DNVGL-CG-0170 Offshore classification projects - testing and … · 2015. 11. 2. · Class...
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CLASS GUIDELINE
DNVGL-CG-0170 Edition July 2015
Offshore classification projects - testing and commissioning
DNV GL AS
The electronic pdf version of this document found through http://www.dnvgl.com is the officially binding version. The documents are available free of charge in PDF format.
FOREWORD
DNV GL class guidelines contain methods, technical requirements, principles and acceptance criteria relatedto classed objects as referred to from the rules.© DNV GL AS July 2015
Any comments may be sent by e-mail to [email protected]
This service document has been prepared based on available knowledge, technology and/or information at the time of issuance of this document. The use of thisdocument by others than DNV GL is at the user's sole risk. DNV GL does not accept any liability or responsibility for loss or damages resulting from any use ofthis document.
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CHANGES – CURRENTGeneralThis document supersedes DNV-RP-A205, October 2013.
Text affected by the main changes in this edition is highlighted in red colour. However, if the changes
On 12 September 2013, DNV and GL merged to form DNV GL Group. On 25 November 2013 Det NorskeVeritas AS became the 100% shareholder of Germanischer Lloyd SE, the parent company of the GL Group,and on 27 November 2013 Det Norske Veritas AS, company registration number 945 748 931, changed itsname to DNV GL AS. For further information, see www.dnvgl.com. Any reference in this document to “DetNorske Veritas AS”, “Det Norske Veritas”, “DNV”, “GL”, “Germanischer Lloyd SE”, “GL Group” or any otherlegal entity name or trading name presently owned by the DNV GL Group shall therefore also be considereda reference to “DNV GL AS”.
On 12 September 2013, DNV and GL merged to form DNV GL Group. On 25 November 2013 Det NorskeVeritas AS became the 100% shareholder of Germanischer Lloyd SE, the parent company of the GL Group,and on 27 November 2013 Det Norske Veritas AS, company registration number 945 748 931, changed itsname to DNV GL AS. For further information, see www.dnvgl.com. Any reference in this document to “DetNorske Veritas AS”, “Det Norske Veritas”, “DNV”, “GL”, “Germanischer Lloyd SE”, “GL Group” or any otherlegal entity name or trading name presently owned by the DNV GL Group shall therefore also be considereda reference to “DNV GL AS”.
involve a whole chapter, section or sub-section, normally only the title will be in red colour.
Main changes July 2015• GeneralThe revision of this document is part of the DNV GL merger, updating the previous DNV recommended practice into a DNV GL format including updated nomenclature and document reference numbering, e.g.:
— DNV replaced by DNV GL.— DNV-RP-A205 to DNVGL-CG-0170 etc.
A complete listing with updated reference numbers can be found on DNV GL's homepage on internet.
To complete your understanding, observe that the entire DNV GL update process will be implemented sequentially. Hence, for some of the references, still the legacy DNV documents apply and are explicitly indicated as such, e.g.: Rules for Ships has become DNV Rules for Ships.
In addition to the above stated main changes, editorial corrections may have been made.
Editorial corrections
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CONTENTSCHANGES – CURRENT .................................................................................................. 3
Sec.1 Introduction.................................................................................................. 61.1 Preamble................................................................................................61.2 General...................................................................................................61.3 Objective................................................................................................61.4 Scope and application ............................................................................61.5 Structure of this document.....................................................................61.6 How to use this document ......................................................................61.7 References .............................................................................................71.8 Abbreviations .........................................................................................7
Sec.2 Commissioning process and definition of various stages............................... 92.1 Introduction ...........................................................................................92.2 Detailed design ......................................................................................92.3 Mechanical completion .........................................................................10
Sec.3 Pre-commissioning...................................................................................... 113.1 Introduction .........................................................................................113.2 Commissioning.....................................................................................113.3 Integration testing ...............................................................................113.4 Marine sea trial ....................................................................................123.5 Delivery................................................................................................123.6 Hook up................................................................................................123.7 Operation .............................................................................................12
Sec.4 Commissioning procedures ......................................................................... 13Sec.5 DNV GL involvement in commissioning ....................................................... 15Sec.6 Safety, health and environment .................................................................. 16
App. A Typical survey categorization for drillships during mechanical completion and commissioning of marine and drilling systems ..................................... 17A.1 Category I systems for commissioning (for integration) ..................... 17A.2 Category II systems for commissioning (for integration).................... 17A.3 Category I systems for commissioning (as independent systems) ...... 18A.4 Category II systems for commissioning (as independent systems)..... 18A.5 Category III systems for commissioning (as independent system)..... 20
App. B Typical survey categorization for semi-submersible units during mechanical completion and commissioning of marine and drilling systems 21B.1 Category I systems for commissioning (for integration) ..................... 21B.2 Category II systems for commissioning (for integration).................... 21B.3 Category I systems for commissioning (as independent systems) ...... 22B.4 Category II systems for commissioning (as independent systems)..... 22B.5 Category III systems for commissioning (as independent system)..... 24
App. C Typical survey categorization for “jack-up” units during mechanical completion and commissioning of marine and drilling systems .................. 25C.1 Category I systems for commissioning (for integration) ..................... 25C.2 Category II systems for commissioning (for integration).................... 25
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C.3 Category I systems for commissioning (as independent systems) ...... 26C.4 Category II systems for commissioning (as independent systems)..... 26C.5 Category III systems for commissioning (as independent system)..... 28
App. D Typical survey categorization for FPSO units during mechanical completion and commissioning of marine and production systems .............................. 29D.1 Category I systems for commissioning (for integration) ..................... 29D.2 Category II systems for commissioning (for integration).................... 30D.3 Category I systems for commissioning (as independent systems) ...... 31D.4 Category II systems for commissioning (as independent systems)..... 32D.5 Category III systems for commissioning (as independent system)..... 33
App. E Typical survey categorization for FSO units during mechanical completion and commissioning of marine and production systems ............................... 34E.1 Category 1 systems for commissioning (for integration)..................... 34E.2 Category II systems for commissioning (for integration).................... 34E.3 Category I systems for commissioning (as independent systems) ...... 35E.4 Category II systems for commissioning (as independent systems)..... 36E.5 Category III systems for commissioning (as independent system)..... 37E.6 Category I systems for commissioning (class notation CRANE)........... 37
App. F DNV GL requirements related to marine, utility and safety systems ........... 38F.1 Stability and watertight integrity ........................................................ 38F.2 Fabrication and testing of offshore structures..................................... 39F.3 Marine and machinery systems and equipment ................................... 40F.4 Electrical installations ......................................................................... 47F.5 Instrumentation and telecommunication systems............................... 58F.6 Fire protection systems....................................................................... 62F.7 Vessel operations ................................................................................ 65
App. G Survey scope for specific class notations .................................................... 68G.1 DNV GL survey scope for DRILL .......................................................... 68G.2 DNV GL survey scope for PROD .......................................................... 77
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1.1 PreambleThis class guideline (CG) outlines the general best practices that lead to effective testing and commissioning of marine and industrial systems onboard mobile offshore units in newbuilding projects. For convenience, an extract of all DNV GL rules related to testing and commissioning of marine and industrial systems have been included in this document. It should be noted that for more accurate applicable statutory and class requirements related to testing and commissioning, applicable versions of the statutory and class rules as specified in the contract shall be referred to. System categorizations included in the appendix are general in nature and may not include all applicable systems that are specific to particular newbuilding projects and so, this document should be used only as a guide. This document currently includes requirements related to drilling units with the intention to include requirements related to other object types at a later stage.
1.2 GeneralDNV GL has recognized that the technical complexity of modern Offshore Installations is increasing due to systems becoming more complex, more automated and more tightly integrated. This evolution provides designers, shipyards, owners and other involved parties challenges in the management of testing and commissioning equipment and systems onboard offshore units successfully.
1.3 ObjectiveThis CG outlines recommended work processes for the testing and commissioning activities on offshore newbuild units. This document shall be read as a guide to testing and commissioning equipment and systems onboard offshore Units. The document will help users in preparing or carrying out witnessing of testing and commissioning activities to satisfy the requirements of classification and applicable statutory regulations where DNV GL has delegation from such authorities.
It should be noted that final acceptance of commissioning is the owner's responsibility. This CG only covers class and statutory related activities.
1.4 Scope and applicationThis guide is applicable to testing and commissioning activities onboard classed mobile offshore units e.g., drilling, accommodation and FPSOs.
1.5 Structure of this documentThis document contains:
— A general overview of testing and commissioning activities together with samples of typical contents of testing and commissioning procedures including the ones for integration testing and commissioning.
— Extract of applicable DNV GL rules for classification of offshore units (rules for offshore units) and DNV GL offshore standards related to preparation, testing and commissioning of various marine, utility and industrial systems.
— Categorization of marine, utility and industrial systems that can be used to decide on the extent of involvement from various stakeholders.
This CG can be used as a check list for reviewing commissioning procedures to assist preparation of requirements related to class and applicable statutory regulations.
1.6 How to use this documentThe main function of this CG is to ensure that the commissioning procedures contain all the relevant information required by the applicable DNV GL rules for offshore units and DNV GL offshore standards.
If the commissioning procedures are reviewed against this document, they should contain all the required information to ensure compliance with the various offshore standards thus ensuring that testing and commissioning activities are fully in compliance with the required classification requirements.
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Information and requirements provided in this CG are extracted from the following DNV GL rules for offshore units, offshore standards and rules for classification of ships (Rules for ships):
1.8 Abbreviations
Table 1-1 DNV GL rules for offshore units, offshore standards and rules for classification of ships (rules for ships)
References TitleDNVGL-RU-OU-0101 Offshore drilling and support units DNVGL-RU-OU-0102 Floating production, storage and loading unitsDNVGL-OS-A101 Safety principles and arrangements DNVGL-OS-C301 Stability and watertight integrityDNVGL-OS-C401 Fabrication and testing of offshore structures DNVGL-OS-D101 Marine and machinery systems and equipment DNVGL-OS-D201 Electrical installations DNVGL-OS-D202 Automation, safety, and telecommunication systems DNVGL-OS-D301 Fire protection DNVGL-OS-E101 Drilling plantDNVGL-OS-E201 Oil and gas processing systemsDNV Rules for Ships Pt.4 Ch.2, Ch.3, Ch.7, Ch.8, and Ch.14 / Pt.5 Ch.3 / Pt.6 Ch.3.
Table 1-2 Abbreviations
Abbreviation DescriptionAC alternating currentBOP blow out preventerCSG casingDAT digital audio tapeDB distribution boardDC direct currentDDM derrick drilling machineDFMA design for manufacture and assemblyDP dynamic positioningDPS dynamic positioning systemE0 unmanned machinery space alarmESD emergency shut downF&G fire & gas (systems)FPSO floating production, storage and offloading (unit)FSO floating storage and offloading (unit)FW fresh waterGMDSS global maritime distress safety systemHP high pressureHPU hydraulic power unitHVAC heating, ventilation and air conditioningICCP impressed current cathodic protectionICMS integrated control and management systemICSS integrated control and safety systemLER local electrical roomLIR local instrument room LMRP lower marine riser packageLP low pressureLQ living quarter
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LV low voltageMC mechanical completionMCC main control centerMGPS marine growth protection systemP&ID piping & instrument diagramPA/GA public address / general alarmPABX private automatic branch exchange (telephone system)PCR process control roomPMS power management systemPSD process shut downQA quality assuranceQC quality controlQSP quality survey planSIT system integration testSWBD switchboardTA/ATA thruster assisted/ automatic thruster assistedUPS uninterruptable power supplyVDU visual display unitVFD variable frequency driveWHC wellhead control system
Table 1-2 Abbreviations (Continued)
Abbreviation Description
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VARIOUS STAGES
2.1 Introduction
Commissioning of an offshore unit is a time consuming and complex process. A structured approach is a necessity for a successful commissioning phase of the newbuilding projects. While the requirements for the testing and commissioning are clearly specified in various applicable DNV GL standards, how exactly the commissioning activities should be carried out is largely left to the Builder/Owners of the mobile offshore units. For instance, there will be dependencies between the different packages. It is, however, a DNV GL requirement to see that the testing requirements mentioned in our rules are carried out during commissioning. It is often required by DNV GL offshore standards that the equipment is to be tested in “as installed” condition. So, though similar tests have already been carried out during a factory acceptance test (FAT), a new test in installed condition would be required. A typical example could be the offshore cranes. They will probably be overload tested during FAT, but they will still be necessary to overload test in installed condition.
Before commissioning starts the responsible DNV GL surveyor and all stakeholders involved in preparing and carrying out the testing and commissioning should also have an idea as to what activities are considered most important to DNV GL and also what activities are not within the DNV scope. During commissioning it is also important to be aware that the owner’s and the yard’s viewpoint as to what is DNV GL’s scope of work may not be in harmony with the scope required by the DNV GL Offshore standards. It is also important to recognize that owner/yard may have additional requirements e.g., related to performance or additional functionality, that may be over and above the classification requirements of DNV GL.
2.2 Detailed designWhen entering into the final stages of any project, the detailed design is expected to be fully completed, reviewed and approved. Failure to complete the design in a satisfactory manner may undermine already completed testing and commissioning, especially comments that may result in redesigning component or systems. Any duplication in redoing testing and commissioning is not very efficient and will result in loss of valuable time and additional cost. The preferred solution would be to have the design engineers available during the commissioning stages. The design engineer can then confirm completion of the design activities and advise what needs to be rectified, redesigned and followed up.
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For most offshore projects mechanical completion (MC) is considered a natural and a logical step on the way towards proper project completion. It is normal for the builder or system vendor to create mechanical completion check lists for the actual equipment or system. Only some parts of mechanical completion is covered in the DNV Offshore standards and is thus formally DNV GL scope of work. DNV GL generally maintain oversight of most of the mechanical completion activities of the project through unscheduled surveys. Where it is mandated by the quality survey plan (QSP), a DNV GL surveyor may attend certain mechanical completion activities. Some of the examples of such activities are:
— pressure testing of piping— installation of main engines/alignment— cable installation / segregation of cables.
In this instruction, MC is completed when construction and installation of equipment, piping, instrumentation, cabling, electrical equipment, etc. have been demonstrated as physically complete. Dynamic tests are limited to non-energised tests like cold alignment of shafting for motors, engines and generators. Further megger tests, flushing and drying of piping systems, cleaning, etc. is included in this milestone. Typically, the MC will result in a number of outstanding activities that must be rectified before any actual pre-commissioning, testing and commissioning can commence. Normal findings typically include missing electrical equipment grounding, lack of proper shielding of fuel pipes or hot surfaces, insufficient nozzle coverage for deluge systems, etc. The evidence of the required certification of equipment should be verified during mechanical completion stage so that there are no surprises before commencing pre-commissioning, testing and commissioning stages. Failure to do so may jeopardize the safety of such activities.
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3.1 IntroductionPre-commissioning is the stage before commissioning which involves the verification of functional operability of the equipment part or full systems. This stage of testing requires energising of equipment and introduction of fluids in fluid piping systems. This is the stage where the vendor and/or the yard are carrying out independent testing of the equipment/system. This is a “trial and error” phase where class normally do not attend. During review and approval of commissioning procedures, it is important for the DNV GL surveyor to make sure that tests required by the rules are carried out during the commissioning phase. It may be a challenge when the tests required by the rules are carried out during pre-commissioning but not attended by a DNV GL surveyor. This should be highlighted during the review of the commissioning procedures. Pre-commissioning would typically include:
— Loop testing. — Motor no load runs. — Equipment final alignments.
3.2 CommissioningThe phase after mechanical completion, pre commissioning and testing is often referred to as the commissioning phase. The “commissioning of an offshore unit” is a very wide term and for the purpose of classification, it refers to final checks, inspection and tests that every operational component or system goes through to confirm operational readiness. Typically equipment/system commissioning will consist of:
— Functional testing of systems by start-up priority.— Testing of ESD/PSD and F&G.— Load tests and other equipment performance testing.
In the commissioning phase it will be verified that the installed equipment and system are working as intended and that the rule requirements for the various equipment/system functionality are met. The rules will have requirements for “performance”, e.g. number of starts for starting air receivers and “functionality”, e.g. safety functions of boilers and incinerators.
For effective commissioning, it is important that the testing and commissioning of the different skids/packages are given the right priority so that they happen in the right sequence/order. Very little commissioning can be performed without the hydraulic ring line, power system, cooling water, pneumatic systems and other utilities being functional and working properly. Typically, temporary arrangements should not be accepted for commissioning. It should also be a general principle that commissioned equipment is not dismantled or modified after testing and commissioning of the equipment/system is completed. Once the equipment/system is tested and commissioning is completed it is good practice to have a close out meeting where the commissioning procedures are signed, by owner and outstanding punch items are agreed.
3.3 Integration testingIntegration testing is a collective term for testing and commissioning of more than one system (a collection of systems, sub-systems and equipment packages) to ensure compliance with project requirements. Many systems onboard are integrated with other systems in one way or another. However, in this context, integration testing is meant to cover the following but not limited to:
— Complete functional testing of systems across equipment boundaries. — Final adjustments of alarm-limits, measuring instruments.— End to end testing of ESD/PSD and F&G.— Integrated testing of PROD/DRILL plants.
Many of the system integration tests are often carried out during the marine sea trial as all the relevant systems and consumers may be required to be ready for such tests to be carried out. The trials can also be organised e.g. with one drilling trial and one marine sea trial.
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The marine sea trials typically focuses on propulsion, steering and utility systems functioning under normal operating conditions. A prerequisite for sea trials is that the major safety systems like fire fighting, life-saving appliances, PA/GA, HVAC, etc. are satisfactorily commissioned ahead of sea trials. In addition, the inclining test should be completed prior to taking the unit out on sea trial.
Sea trials are conducted to test a vessels performance and general seaworthiness. Testing of a vessels speed, manoeuvrability, equipment and safety features are usually conducted during sea trial. However, this demonstration of speed and manoeuvrability, etc. is normally more important for a merchant vessel than an offshore unit. A merchant vessel will typically have a contract speed as part of the contract between the builder and the owner. That is seldom the case for an offshore unit. The marine sea trial will typically consist of but not limited to:
— testing of Dynamic Positioning System
— final commissioning of Ballast systems, Cooling water, Lube oil, Fuel Oil, HVAC, Thrusters, etc.
— speed test
— crash stop
— turning test
— E0 test (Unmanned machinery space alarms)
— endurance test.
The marine sea trial is normally not relevant for fixed units or units without propulsion.
3.5 DeliveryDepending on type of unit, the successful completion of all testing and commissioning activities will trigger the delivery of the unit. The level of completion will however vary from project to project. Typically a project with a contract in place and a long transit to the operation area, the owner may prefer an early delivery with the intention to close some of the outstanding items in transit. If a unit does not have a project in place, the owner will typically aim for a higher level of completion before they will accept the unit. Equipment subject to class approval that is not readily commissioned in accordance with approved testing and commissioning procedures should be identified in the delivery documentation by issuance of relevant conditions of class. It should be evaluated prior to delivery whether the outstanding class and statutory systems are minor in nature and does not affect the safety and integrity of the unit that will allow the Class Society to issue appropriate Class and Statutory Certificates. If critical systems e.g., fire fighting/detection, propulsion and steering, life-saving appliances, navigational aids, etc. are not commissioned, Class and Statutory Certificates are not typically issued.
3.6 Hook upHook up is mostly relevant for fixed units like FPSOs and other units that will stay on the same location for a number of years, however some drilling units may require some testing of systems on first location. Typically it means the hook up of risers to the unit and preparations required prior to first oil. Many of the vital commissioning activities for such units will have to take place at location and cannot be completed during the construction of the unit. Hook up is not typically included in the class scope but if safety and integrity of the vessel is in question, Class Society typically evaluates the status of such operation.
3.7 OperationOnce the unit is in operation, there should not be any major outstanding class and statutory items carried over from the newbuilding phase and procedures related to “units in operation” requirements should be followed.
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Two types of procedures are normally submitted for review / approval:
— system or equipment commissioning— integration testing.
Typical examples of the contents list of these procedures are shown in the Figure 4-1 and Figure 4-2 below.
Figure 4-1 Typical content for a system commissioning procedure
SYSTEM COMMISSIONING PROCEDURE
1 SYSTEM DESCRIPTION 1.1 Commissioning Package 1.2 System Integration Description 1.3 Pre-requisites
2 OBJECTIVE
3 GENERAL 3.1 Safety requirements and precautions 3.2 Regulatory and project specific requirements 3.3 Participants (e.g. Owner / Vendor / Class Representative / Builder) 3.4 Kick-off meeting 3.5 Special / Temporary Tools / Equipment, Spare & Consumables 3.6 Traceability of documents & records 3.7 Punch list system
4 PRE-COMMISSIONING 4.1 Each package listed 5 OPERATIONAL MULTI-DISCIPLINE COMMISSIONING 5.1 Detailed test procedure with acceptance criteria APPENDIXES
I. Equipment Data Sheet / Information II. Commissioning Test Results / Running Logs III. Single Line Diagram / Block Diagram IV. P & ID
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Figure 4-2 Typical content for a system integration test procedure
INTEGRATION TEST PROCEDURE
1 SYSTEM DESCRIPTION 1.1 Commissioning Package 1.2 System Integration Description 1.3 Pre-requisites 2 OBJECTIVE 3 GENERAL 3.1 Safety Requirements and precautions 3.2 Sequence of Events 3.3 Participants (e.g. Owner / Vendor / Class Representative / Builder) 3.4 Kick-off meeting 3.5 Special / Temporary Tools / Equipment, Spare & Consumables 3.6 Traceability of documents & Records 3.7 Punch list system 4 PERFORMANCE OF INTEGRATION TEST 4.1 Detailed test procedure with acceptance criteria 5 OPERATIONAL MULTI-DISCIPLINE COMMISSIONING 5.1 Detailed test procedure with acceptance criteria APPENDIXES
I. Equipment Data Sheet / Information II. Commissioning Test Results / Running Logs III. Single Line Diagram / Block Diagram IV. P & ID
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DNV GL’s involvement in testing and commissioning is limited to the requirements of statutory and class rules. DNV GL surveyor will attend testing and commissioning to the extent specified in applicable quality survey program (QSP).
Survey scope shall be categorized as follows:
— Survey Category 1 - Statutory and Essential Systems for Safety (normally increased attendance by DNV GL).
— Survey Category 2 - Main Systems / Functionally Important (For Main and Additional Class Notations, extent is based on the yard’s experience and the effectiveness of Yard’s QA/QC system).
— Survey Category 3 – Normally limited or no attendance required by surveyor.
The tables attached in the following appendices detail the “survey categorization during Mechanical Completion and Commissioning of Marine and Drilling Systems” (based on Project System / Sub System List).
Drillships App.ASemi-submersible units App.BJack ups App.CFPSO App.DFSO App.E
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It is important to note that commissioning activities may introduce additional hazards to the process that may not have been considered in the design phase i.e. the use of alternative media for testing in the absence of hydrocarbons. When evaluating extent of checks and tests the philosophy of Primum non nocere or first do no harm should be considered.
It should also be noted that the commissioning activities themselves may also introduce additional risks and hazards into the workplace. Prior to start of any commissioning the relevant safe job analysis should be performed where relevant dangers are highlighted and sufficient efforts are taken to minimize the risks.
It is important to ensure responsibilities are clearly defined and recognised; that there are suitable and sufficient instructions e.g. procedures, method statements, workpacks; whether control and supervision of staff and contractors is adequate; whether arrangements for calibration of any test equipment associated with commissioning is adequate; there is adequate control of temporary commissioning aids e.g. E&I hardwired links, isolations, spades in process lines.
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DRILLSHIPS DURING MECHANICAL COMPLETION AND COMMISSIONING OF MARINE AND DRILLING SYSTEMS
A.1 Category I systems for commissioning (for integration)
A.2 Category II systems for commissioning (for integration)
No. Name of the system Integrated with1 Fire Main System F&G/Deluge/control2 Inergen System F&G/HVAC/PA3 Fire Water Deluge System F&G4 Main Diesel Generator PMS&S/T&DP5 Seawater Cooling System Consumer Capacity Test6 Thruster Seawater Cooling System SIT7 Thruster S/T8 11Kv Switchboard (or equivalent) PMS9 690V HPU MCC (or equivalent) SIT10 690V Drilling VFD Switchboard (or equivalent) SIT11 690V Thruster VFD Switchboard (or equivalent) DP/PMS12 230V AC UPS (or equivalent) ESD13 230V AC UPS Battery (or equivalent) ESD14 230V AC UPS Main Distribution Board (or equivalent) ESD15 230V AC UPS DB (or equivalent) ESD16 ICMS, Fire and Gas, ESD and DP with Sensor and Reference System ESD/HVAC17 Telecom System ESD18 Electrical and Auxiliary Machinery Rooms Ventilation Systems ESD19 Engine Rooms Ventilation Systems ESD20 Port/Stbd/Aft Machinery Rooms Ventilation Systems ESD21 LQ HVAC ESD22 Power Management System DRILL/DP23 Dynamic Positioning System Test (DPS) CONTROL24 Machinery Unmanned Test E0
No. Name of the system Integrated with1 Ballast System Semi Recovery Test2 Aux. Cooling F.W. System S/T and SIT3 460V LV Switchboard S/T4 230V LV Switchboard S/T5 PA Coverage Measurement Normal Operation
(machinery Running)
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systems)
A.4 Category II systems for commissioning (as independent systems)
No. Name of the system1 Lifeboat and Launch System2 Fast Rescue Craft Launch Device System3 Deck Crane4 Emergency bilge system5 Emergency Shut Off System (Quick closing valves)6 Drill Floor Elevator7 Escape Chute8 Watertight Doors9 Helideck Fire-Fighting System10 Emergency Generator11 Emergency Switchboard12 Cement unit13 230V AC UPS 14 230V AC UPS Battery15 230V AC UPS Main Distribution Board16 230V AC UPS DB17 Dynamic Positioning System Test (DPS)
No. Name of the system 1 Misc.Lifesaving Equipment2 Helicopter Refueling System3 Ballast System4 Dirty Drain System5 Fire Main System6 Inergen System7 Fire Water Deluge System8 Main Diesel Generator9 Steam Generating System10 Seawater Cooling System11 Starting Air System For Main Engine12 Thruster Seawater Cooling System13 Sewage and Gray Water Discharge System14 Anchor Winches15 Thruster 16 Bilge System17 Diesel Gen. F.W Cooling System18 11Kv Switchboard (or equivalent)19 690V HPU MCC (or equivalent)20 690V Drilling VFD Switchboard (or equivalent)21 690V Thruster VFD Switchboard (or equivalent)22 230V AC UPS (or equivalent)23 230V AC UPS battery (or equivalent)24 230V AC UPS Main Distribution Board (or equivalent)25 230V AC UPS DB (or equivalent)26 Nav. and Signal Light
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27 U-Light and Foghorn28 Obstruction Light29 Remote Sounding System30 ICMS, Fire and Gas, ESD and DP with Sensor and Reference System31 Telecom System 32 HPU For Vent Valve Operation33 Ram Rig Travelling Yokes Main/Aux. (or equivalent)34 Tong Lift System35 LIR / HVAC Room, HVAC 36 Derrick Drilling Machine (DDM)/Top Drive37 Rotary Table Main/Aux.(Including Power Slips) 38 DAT System39 Guideline Winch and Tensioner System40 LP/HP Nitrogen System41 Mud Bucket42 Bulk Powder Handling System43 Mud Storage and Transfer System44 Mud Mixing and Additive System45 Mud Supply System46 Mud Return and Treatment System47 Mud, Brine, Oil Storage and Transfer System System48 BOP Package49 Diverter Package50 Tubular and Riser Feeding Machine/Shuttle, Main Rig51 Lower Guiding Arm including Heads and Rail, Main/Aux52 Trolley for Riser Guiding53 Riser Chute54 DP/DC, Casing and Riser Fingerboard, bellyboard55 Bridge Crane in Derrick56 Hydraulic Roughneck57 Multi Scope Arm58 Hydraulic Cathead, Brake Out, including Wire59 Tail in Arm60 Manipulator Arm (MPMA/DFMA)61 Pipehandler Crane62 Riser Handling Crane (w/ Rail)63 BOP Skid/X-Mas/ LMRP Transportation/Handling64 Miscellaneous Guides65 Access Basket66 BOP Overhead Crane/X-mas Tree Overhead Crane 67 Overhull/underhull Guiding68 Utility Winch and Manrider Winch69 Burner Boom70 Ringline HPU and Distribution System71 Ramrig HPU and Distribution System72 Dual Derrick Simultaneous Operation73 Integrated BOP and Riser Handling System74 Sludge system75 Loop Check76 Mud, Cement, Choke and Kill Manifolds
No. Name of the system (Continued)
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A.5 Category III systems for commissioning (as independent system)
77 LQ HVAC78 Power Management System79 Navigation Equipment80 Machinery Unmanned Test81 Anchor Test82 PA Coverage Measurement
No. Name of the system1 Monorail System2 Winches and Towing Equipment3 Drill Water System4 Deck Bilge System5 Service Air System6 Steam and Drain System7 Seawater Service System8 Aux. Cooling F.W. System9 Diesel Oil Transfer and Drain System10 Lub. Oil Storage, Transfer and Drain System11 Distilled and Make-Up Water System12 Potable and Sanitary Supply System13 Cold Starter Generator14 Marine Growth Protection System15 Heat Trace System16 460V LV Switchboard17 230V LV Switchboard18 Small Power DB19 Lighting and Small Power20 Shore Connection Box21 Column and Pontoon Machinery Rooms Ventilation Systems22 Electrical and Auxiliary Machinery Rooms Ventilation Systems23 Engine Rooms Ventilation Systems24 Port/Stbd/Aft Machinery Rooms Ventilation Systems25 HVAC Duck Air Leak Test Procedure for Hull and Topside26 ICCP27 Pneumatically Operated Door28 Provision Cold Store and Freezer System29 Noise Level Measurement30 Vibration Level Measurement31 Helideck Drains
No. Name of the system (Continued)
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SUBMERSIBLE UNITS DURING MECHANICAL COMPLETION AND COMMISSIONING OF MARINE AND DRILLING SYSTEMS
B.1 Category I systems for commissioning (for integration)
B.2 Category II systems for commissioning (for integration)
No. Name of the system Integrated with1 Fire Main System F&G/Deluge/control2 Inergen System F&G/HVAC/PA3 Fire Water Deluge System F&G4 Main Diesel Generator PMS&S/T&DP5 Seawater Cooling System Consumer Capacity Test6 Thruster Seawater Cooling System S/T7 Thruster S/T8 11Kv Switchboard (or equivalent) PMS9 690V HPU MCC (or equivalent) SIT10 690V Drilling VFD Switchboard (or equivalent) SIT11 690V Thruster VFD Switchboard (or equivalent) DP/PMS12 230V AC UPS (or equivalent) ESD13 230V AC UPS Battery (or equivalent) ESD14 230V AC UPS Main Distribution Board (or equivalent) ESD15 230V AC UPS DB (or equivalent) ESD16 ICMS, Fire and Gas, ESD & DP
With Sensor and Reference SystemESD/HVAC
17 Telecom System ESD18 Column and Pontoon Machinery Rooms Ventilation Systems ESD19 Electrical and Auxiliary Machinery Rooms Ventilation Systems ESD20 Engine Rooms Ventilation Systems ESD21 Port/Stbd/Aft Machinery Rooms Ventilation Systems ESD22 LQ HVAC ESD23 Power Management System DRILL/DP24 Dynamic Positioning System Test (DPS) CONTROL25 Machinery Unmanned Test E0
No. Name of the system Integrated with1 Anchor Winches If Posmoor, TA/ATA2 PA Coverage Measurement Normal operation3 Ballast System Semi recovery test4 Auxiliary Cooling Fresh Water System (#2) S/T & SIT5 460V LV Switchboard S/T6 230V LV Switchboard S/T
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systems)
B.4 Category II systems for commissioning (as independent systems)
No. Name of the system1 Lifeboat and Launch System2 Fast Rescue Craft Launch Device System3 Deck Crane4 Emergency Bilge System5 Emergency Shut Off System (Quick closing valves)6 Drill Floor Elevator7 Escape Chute8 Column Room Elevators9 Water Tight Doors10 Helideck Fire-Fighting System11 Inclining Experiment and Light Weight Measurement Procedure12 Emergency Generator13 Emergency SWBD14 Cement Unit
No. Name of the system 1 Misc. Lifesaving Equipment2 Helicopter Refueling System3 Dirty Drain System4 Ballast System5 Fire Main system6 Inergen system7 Fire Water Deluge system8 Main Diesel Generator9 Steam Generating System10 Seawater Cooling System11 Starting Air System for Main Engine12 Thruster Seawater Cooling System13 Sewage and Gray Water Discharge System14 Anchor Winches15 Thrusters16 Bilge System17 Diesel Generator Fresh Water Cooling System18 11Kv Switchboard (or equivalent)19 Navigation and Signal Light20 690V HPU MCC (or equivalent)21 690V Drilling VFD Switchboard (or equivalent)22 690V Thruster VFD Switchboard (or equivalent)23 230V AC UPS (or equivalent)24 230V AC UPS Battery (or equivalent)25 230V AC UPS Main Distribution Board (or equivalent)26 230V AC UPS DB (or equivalent)27 U-Light and Foghorn28 Obstruction Light29 Remote Sounding System
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30 HPU for Vent Valve Operation31 Ram Rig Travelling Yokes Main and Auxiliary (or equivalent)32 Tong Lift System33 LIR/HVAC Room, HVAC34 Draw-Work35 Derrick Drilling Machine (DDM)/Top Drive36 Rotary Table Main / Auxiliary (Including Power Slips)37 DAT System38 Guideline Winch and Tensioner System39 LP/HP Nitrogen System40 Mud Bucket41 Bulk Powder Handling System42 Mud Storage and Transfer System43 Mud Mixing and Additive System44 Mud Supply System45 Mud Return and Treatment System46 Pontoon Mud, Brine, Oil Storage and Transfer System47 BOP Package48 Diverter Package49 Tubular and Riser Feeding Machine/Shuttle, Main Rig50 Lower Guiding Arm Includes Heads and Rail, Main and Auxiliary51 Trolley For Riser Guiding52 Riser Chute53 DP/DC, Casing and Riser Fingerboard54 Direct Lift Bridge Crane DP/DC/CSG, Main Rig / Auxiliary Rig55 Hydraulic Roughneck56 Multi Scope Arm (Casing Modem)57 Hydraulic Cathead, Brake Out, Including Wire58 Tail in Arm59 Multi Manipulator Arm (DFMA)60 Pipehandler Crane61 Riser Handling Crane (with Rail)62 Skids for BOP/X-mas tree/LMRP63 Miscellaneous Guides64 Access/cherrypicker Basket65 BOP / X-Mas Tree Overhead Crane 66 Underhull Guiding Main / Auxiliary67 Overhull/underhull Guiding68 Utility Winch and Manrider Winch69 Burner Boom70 Ringline HPU and Distribution System71 Ramrig HPU and Distribution System (or equivalent)72 Dual Derrick Simultaneous Operation (if Fitted)73 Integrated BOP and Riser Handling System74 Sludge System75 Loop Check76 Drilling Control
No. Name of the system (Continued)
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B.5 Category III systems for commissioning (as independent system)
77 Mud and Cement Manifolds78 Navigation Equipment79 Anchor Test80 Leakage detection system
No. Name of the system1 Monorail System2 Air Winches and Towing Equipment3 Drill Water System4 Deck Bilge System5 Service Air System6 Steam and Drain System7 Seawater Service System8 Aux. Cooling FW system9 Diesel Oil Transfer and Drain System10 Lub Oil Storage, Transfer and Drain System11 Distilled and Make-Up Water System12 Potable and Sanitary Supply System13 Cold Starter Generator14 MGPS (Marine Growth)15 Heat Trace System16 460V LV Switchboard (or equivalent)17 230V LV Switchboard (or equivalent)18 Small Power Distribution Boards19 Lighting and Small Power20 Shore Connection Box21 Column and Pontoon Machinery rooms ventilation systems22 Electrical and Auxiliary Machinery rooms ventilation systems23 Engine room ventilation systems24 Port/ Stbd/Aft machinery rooms ventilation systems25 HVAC Duct Air Leak Test Procedure for Hull and Topside26 ICCP27 Pneumatically Operated Door28 Provision Cold Store and Freezer System29 Noise Level Measurement30 Vibration Level Measurement31 Helideck Drains
No. Name of the system (Continued)
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UNITS DURING MECHANICAL COMPLETION AND COMMISSIONING OF MARINE AND DRILLING SYSTEMS
C.1 Category I systems for commissioning (for integration)
C.2 Category II systems for commissioning (for integration)
No. Name of the system Integrated with1 Fire Main System F&G/Deluge/control2 Inergen System F&G/HVAC/PA3 Fire Water Deluge System F&G4 Main Diesel Generator PMS&S/T&DP5 Seawater Cooling System Consumer Capacity Test6 11Kv Switchboard PMS7 690V HPU MCC SIT8 690V Drilling VFD Switchboard SIT9 230V AC UPS ESD10 230V AC UPS Battery ESD11 230V AC UPS Main Distribution Board ESD12 230V AC UPS DB ESD13 ICMS, Fire and Gas and ESD
With Sensor and Reference SystemESD/HVAC
14 Telecom System ESD15 Electrical and Auxiliary Machinery Rooms Ventilation Systems ESD16 Engine Rooms Ventilation Systems ESD17 Port/Stbd/Aft Machinery Rooms Ventilation Systems ESD18 LQ HVAC ESD19 Power Management System DRILL/DP20 Machinery Unmanned Test E021 Jacking motors Jacking trial22 Jacking control system Jacking trial
No. Name of the system Integrated with1 Fire water lift with submerged pumps F&G/Deluge/control2 PA Coverage Measurement Normal operation3 Auxiliary Cooling Fresh Water System (#2) S/T and SIT4 460V LV Switchboard S/T5 230V LV Switchboard S/T
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systems)
C.4 Category II systems for commissioning (as independent systems)
No. Name of the system 1 Lifeboat and Launch System2 Fast Rescue Craft Launch Device System3 Deck Crane4 Emergency Bilge System5 Emergency Shut Off System (Quick closing valves)6 Drill Floor Elevator7 Escape Chute8 Water Tight Door9 Helideck Fire-Fighting System10 Inclining Experiment and Light Weight Measurement Procedure11 Emergency Generator12 Emergency SWBD13 Cement Unit14 Cantilever15 Rack Chocking Device16 Accommodation Unit Gangway Test17 230V AC UPS 18 230V AC UPS Battery19 230V AC UPS Main Distribution Board20 230V AC UPS DB
No. Name of the system 1 Misc. Lifesaving Equipment2 Helicopter Refueling System3 Dirty Drain System4 Fire Main System5 Inergen System6 Fire Water Deluge System7 Main Diesel Generator8 Steam Generating System9 Seawater Cooling system (including Buffer Tank alarms if Fitted)10 Starting Air System for Main Engine11 Sewage and Gray Water Discharge System12 Bilge System13 Diesel Generator Fresh Water Cooling System14 11Kv Switchboard or equivalent15 690V HPU MCC (or equivalent)16 690V Drilling VFD Switchboard (or equivalent)17 Navigation and Signal Light18 U-Light and Foghorn19 Obstruction Light20 Remote Sounding System21 ICMS, Fire and Gas and ESD22 Telecommunication System23 HPU for Vent Valve Operation
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24 Ram Rig Travelling Yokes Main and Auxiliary (or equivalent)25 Tong Lift System26 LIR/HVAC Room, HVAC27 Draw-Work28 Derrick Drilling Machine (DDM)/Top Drive29 Rotary Table Main / Auxiliary (Including Power Slips)30 Mud Bucket31 Bulk Powder Handling System32 Mud Storage and Transfer System33 Mud Mixing and Additive System34 Mud Supply System35 Mud Return and Treatment System36 Mud, Brine, Oil Storage and Transfer System37 BOP Package38 Diverter Package39 Lower Guiding Arm Includes Heads and Rail, Main and Auxiliary40 Direct Lift Bridge Crane DP/DC/CSG, Main Rig / Auxiliary Rig41 Hydraulic Roughneck42 Multi Scope Arm (Casing Modem)43 Hydraulic Cathead, Brake Out, Including Wire44 Tail in Arm45 Multi Manipulator Arm (DFMA)46 Pipehandler Crane47 Skids for BOP/X-mas tree/LMRP48 Miscellaneous Guides49 Access Basket50 BOP / X-Mas Tree Overhead Crane 51 Utility Winch and Manrider Winch52 Burner Boom53 Ringline HPU and Distribution System54 Ramrig HPU and Distribution System55 Dual Derrick Simultaneous Operation56 Sludge System57 Loop Check58 Drilling Control59 Mud and Cement Manifolds60 Navigation Equipment61 Anchor Test (if fitted for temp and emergency mooring)62 Ballast System/ Pre Load System63 Spud can HP water injection
No. Name of the system (Continued)
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system)No. Name of the system
1 Monorail System2 Air Winches and Towing Equipment3 Drill Water System4 Deck Bilge System5 Service Air System6 Steam and Drain System7 Seawater Service System8 Diesel Oil Transfer and Drain System9 Lube Oil Storage, Transfer and Drain System10 Distilled and Make-Up Water System11 Potable and Sanitary Supply System12 Cold Starter Generator13 MGPS (Marine Growth) (if fitted for spud cans)14 Heat Trace System15 Small Power DB16 Lighting and Small Power17 Shore Connection Box18 HVAC Duct Air Leak Test Procedure for Hull and Topside19 Pneumatically Operated Door20 Provision Cold Store and Freezer System21 Noise Level Measurement22 Vibration Level Measurement23 Helideck Drains
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UNITS DURING MECHANICAL COMPLETION AND COMMISSIONING OF MARINE AND PRODUCTION SYSTEMS
D.1 Category I systems for commissioning (for integration)No. Name of the system Integrated with*
1 Watertight Doors and Hatches VMS2 Communication – PA/GA ESD/PSD/F&G3 ESD/PSD System ICSS4 F&G Detection Systems ICSS5 UPS for Critical Control (PCS/DP/PMS) ESD6 HVAC Systems ESD/F&G7 Main Power Generation and Distribution ESD/PMS8 Main Fire Pump and Fire Water System ESD/F&G9 Helifuel Fire Fighting System ESD/F&G10 Specific Area Fire Fighting Systems i.e. Foam, CO2, Inergen, Water Spray
SystemsESD/F&G
11 Topsides Fire Water Deluge Systems ESD/F&G12 Dynamic Positioning System (DPS), Steering and Propulsion and associated
equipmentICSS/ESD
13 Wellhead Control System (WHC) ESD/PSD14 Riser Quick Connect/Disconnect System ESD/PSD15 Offloading Quick Connect/Disconnect System including telemetry ESD/PSD/VMS16 Position Monitoring System ICSS/ESD* Where an integrated control and safety system is employed the control system architecture will define which systems the integrated
testing should interface with and may include ICSS/ESD/PSD/F&G/PCS/DP/PMS/VMS.
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No. Name of the system Integrated with*1 Ballast System ICSS2 Fuel oil Transfer System VMS3 Lube oil Transfer System VMS4 Seawater Cooling System (Marine) VMS5 Starting Air System For Main Engine (Marine) VMS6 Bilge System VMS7 Inert Gas System VMS8 Cargo Pumping, Control and Monitoring Systems PSD9 Production Riser System PSD/ESD10 Topside Nitrogen System PSD/ESD11 Inlet Manifold PSD/ESD12 Test Manifold PSD/ESD13 Separation System PSD/ESD14 Test Separation System PSD/ESD15 Process Heating System PSD/ESD16 Process Cooling System PSD/ESD17 Closed Drain System PSD/ESD18 Produced Water Treatment and Disposal System PSD/ESD19 Seawater Treatment and Injection System PSD/ESD20 Gas Treatment System PSD/ESD21 Glycol Regeneration Systems PSD/ESD22 Fuel Gas Treatment System PSD/ESD23 Process Relief and Depressurisation Systems PSD/ESD 24 Gas Disposal System PSD/ESD25 Gas Compression System PSD/ESD/PCS26 Oil Export System PSD/ESD27 Gas Export System PSD/ESD28 Pipeline Pigging Systems PSD/ESD29 Methanol Storage and Injection Systems PSD/ESD30 Chemical Storage and Injection Systems PSD/ESD31 Export Riser System PSD/ESD32 Gas Injection Systems PSD/ESD33 Machinery Unmanned/Watch Call Alarm System (E0) VMS34 Offshore Crane ESD35 Helideck Status Lights (Wave off) F&G36 Topside Power Generation System ESD37 Steam System ESD* Where an integrated control and safety system is employed the control system architecture will define which systems the integrated
testing should interface with and may include ICSS/ESD/PSD/F&G/PCS/DP/PMS/VMS.
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systems)No. Name of the system 1 Lifeboat and Launch System2 Emergency Lighting3 Navigation Lights4 Structural Marking (U-Light and Foghorn)5 Steering Gear and Control System6 Watertight Doors and hatches7 Diving System 8 Communication – GMDSS, PA/GA, PABX9 ESD/PSD System10 F&G Detection Systems11 Emergency Generator and Emergency Switchboard System12 Emergency Generator Starting System (Air or Battery)13 Emergency Motor Control Centre (to control fire pump and other emergency services)14 Transitional Source of Power15 UPS for PA/GA/PABX16 UPS for GMDSS17 UPS for emergency lighting18 UPS ICSS system *define or UPS for ESD/PSD/F&G/PCS/DP/PMS19 Fuel Oil System for Main Power Generation20 Lube oil System for Main Power Generation21 Fresh Water Cooling System for Main Power Generation22 HVAC for propulsion system23 HVAC for Main Power Generation24 Main Power Generation and Distribution25 Emergency Shut Off System (Quick closing valves)26 Fast Rescue Craft Launch Device System27 Emergency bilge system28 Escape routes29 Liferafts and Escape to Sea30 Helideck Fire-Fighting System31 Main Fire Pump and Fire Water System32 Helifuel Fire Fighting System33 Specific Area Fire Fighting Systems i.e. Foam, CO2, Inergen, Water Spray Systems34 Topsides Fire Water Deluge Systems35 Deck Foam System36 Dynamic Positioning System (DPS), Steering and Propulsion and associated equipment37 Wellhead Control System (WHC)38 Riser Quick Connect/Disconnect System39 Offloading Quick Connect/Disconnect System40 Position Monitoring System
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systems)No. Name of the system 1 Misc. Lifesaving Equipment2 Helicopter Refuelling System3 Ballast System4 Hazardous Open Drain System5 Non Hazardous Open Drain System6 Mooring Line Tension Measuring System7 Fuel oil Transfer System8 Lube oil Transfer System9 Steam Generating System (Marine)10 Seawater Cooling System (Marine)11 Starting Air System For Main Engine (Marine)12 Control Air System13 Sewage and Gray Water Discharge System14 Anchoring System and Winches15 Thrusters not part of steering or propulsion16 Bilge System17 Main Lighting Systems18 Topside Umbilical Termination Unit19 Turret Swivel Systems20 Inert Gas System21 Cargo Pumping, Control and Monitoring Systems22 Production Riser System23 Topside Nitrogen System24 Inlet Manifold25 Test Manifold26 Separation System27 Test Separation System28 Process Heating System29 Process Cooling System30 Closed Drain System31 Produced Water Treatment and Disposal System32 Seawater Treatment and Injection System33 Gas Treatment System34 Glycol Regeneration Systems35 Gas Compression System36 Fuel Gas Treatment System37 Process Relief and Depressurisation Systems38 Gas Disposal System39 Oil Export System40 Gas Export System41 Pipeline Pigging Systems42 Methanol Storage and Injection Systems43 Chemical Storage and Injection Systems44 Export Riser System45 Gas Injection Systems46 HVAC for Hazardous Areas47 LQ HVAC48 Individual HVAC Systems (LER, PCR, Topside Power Generation Enclosure)
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D.5 Category III systems for commissioning (as independent system)
49 HVAC for Engine Rooms and other Machinery spaces50 Navigation Equipment51 Machinery Unmanned/Watch Call Alarm System (E0)52 Offshore Crane53 Helideck Status Lights (Wave off)54 Topside Power Generation System
No. Name of the system1 Deck Bilge System2 Service Air System3 Steam and Drain System4 Seawater Service System5 Aux. Cooling F.W. System6 Diesel Oil Transfer and Drain System7 Potable and Sanitary Supply System8 Cold Starter Generator9 MGPS (Marine Growth)10 Heat Trace System11 Small Power DB12 Small Power13 Shore Connection Box14 Electrical and Auxiliary Machinery Rooms Ventilation Systems15 Impressed Current Protection System (ICCP)16 Pneumatically Operated Door17 Provision Cold Store and Freezer System18 Helideck Drains
No. Name of the system (Continued)
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DURING MECHANICAL COMPLETION AND COMMISSIONING OF MARINE AND PRODUCTION SYSTEMS
E.1 Category 1 systems for commissioning (for integration)
E.2 Category II systems for commissioning (for integration)
No. Name of the system Integrated with*
1 Watertight Doors and Hatches VMS2 Communication – PA/GA ESD/PSD/F&G3 ESD/PSD System ICSS4 F&G Detection Systems ICSS5 UPS for Critical Control (PCS/DP/PMS) ESD6 HVAC Systems ESD/F&G7 Main Power Generation and Distribution ESD/PMS8 Main Fire Pump and Fire Water System ESD/F&G9 Helifuel Fire Fighting System ESD/F&G10 Specific Area Fire Fighting Systems i.e. Foam, CO2, Inergen, Water Spray Systems ESD/F&G11 Inlet Flowline or Riser Quick Connect/Disconnect System ESD/PSD12 Offloading Quick Connect/Disconnect System including telemetry ESD/PSD/VMS13 Position Monitoring System* Where an integrated control and safety system is employed the control system architecture will define which systems the integrated
testing should interface with and may include ICSS/ESD/PSD/F&G/PCS/DP/PMS/VMS.
No. Name of the system Integrated with*1 Ballast System ICSS2 Fuel oil Transfer System VMS3 Lube oil Transfer System VMS4 Seawater Cooling System (Marine) VMS5 Starting Air System For Main Engine (Marine) VMS6 Bilge System VMS7 Inert Gas System VMS8 Cargo Pumping, Control and Monitoring Systems PSD9 Inlet flowline or riser System PSD/ESD10 Oil Export System PSD/ESD11 Pipeline Pigging Systems PSD/ESD12 Methanol Storage and Injection Systems PSD/ESD13 Chemical Storage and Injection Systems PSD/ESD14 Export Riser System PSD/ESD15 Machinery Unmanned/Watch Call Alarm System (E0) VMS16 Offshore Crane ESD17 Helideck Status Lights (Wave off) F&G* Where an integrated control and safety system is employed the control system architecture will define which systems the integrated
testing should interface with and may include ICSS/ESD/PSD/F&G/PCS/DP/PMS/VMS.
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systems)No. Name of the system 1 Lifeboat and Launch System2 Emergency Lighting3 Navigation Lights4 Structural Marking (U-Light and Foghorn)5 Watertight Doors and hatches6 Diving System 7 Communication – GMDSS, PA/GA, PABX8 ESD/PSD System9 F&G Detection Systems10 Emergency Generator and Emergency Switchboard System11 Emergency Generator Starting System (Air or Battery)12 Emergency Motor Control Centre (to control fire pump and other emergency services)13 UPS for PA/GA/PABX14 UPS for GMDSS15 UPS for emergency lighting16 UPS ICSS system* define or UPS for ESD/PSD/F&G/PCS/DP/PMS17 Fuel Oil System for Main Power Generation19 Lube oil System for Main Power Generation20 Fresh Water Cooling System for Main Power Generation21 HVAC for propulsion system22 HVAC for Main Power Generation23 Main Power Generation and Distribution24 Emergency Shut Off System (Quick closing valves)26 Fast Rescue Craft Launch Device System27 Emergency bilge system28 Escape routes29 Liferafts and Escape to Sea30 Helideck Fire-Fighting System31 Main Fire Pump and Fire Water System32 Helifuel Fire Fighting System33 Specific Area Fire Fighting Systems i.e. Foam, CO2, Inergen, Water Spray Systems34 Fire Water Deluge Systems35 Deck Foam System36 Inlet Flowline or Riser Quick Connect/Disconnect System37 Offloading Quick Connect/Disconnect System38 Position Monitoring System* Where an integrated control and safety system is employed the control system architecture will define which systems the integrated
testing should interface with and may include ICSS/ESD/PSD/F&G/PCS/DP/PMS/VMS.
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systems)No. Name of the system 1 Misc. Lifesaving Equipment2 Helicopter Refueling System3 Ballast System4 Hazardous Open Drain System5 Non Hazardous Open Drain System6 Mooring Line Tension Measuring System7 Fuel oil Transfer System8 Lube oil Transfer System9 Steam Generating System (Marine)10 Seawater Cooling System (Marine)11 Starting Air System for Main Engine (Marine)12 Control Air System13 Sewage and Gray Water Discharge System14 Anchoring System and Winches15 Thrusters not part of steering or propulsion16 Bilge System17 Main Lighting Systems18 Inert Gas System19 Cargo Pumping, Control and Monitoring Systems20 Gas Disposal System21 Oil Export System22 Pipeline Pigging Systems23 Methanol Storage and Injection Systems24 Chemical Storage and Injection Systems25 Export Riser System26 HVAC for Hazardous Areas27 LQ HVAC28 Individual HVAC Systems (LER, PCR, Topside Power Generation Enclosure)29 HVAC for Engine Rooms and other Machinery spaces30 Navigation Equipment31 Machinery Unmanned/Watch Call Alarm System (E0)32 Offshore Crane33 Helideck Status Lights (Wave off)
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system)
E.6 Category I systems for commissioning (class notation CRANE)
No. Name of the system 1 Deck Bilge System2 Service Air System3 Steam and Drain System4 Seawater Service System5 Aux. Cooling F.W. System6 Diesel Oil Transfer and Drain System7 Potable and Sanitary Supply System8 Cold Starter Generator9 MGPS (Marine Growth)10 Heat Trace System11 Small Power DB12 Small Power13 Shore Connection Box14 Electrical and Auxiliary Machinery Rooms Ventilation Systems15 Impressed Current Protection System (ICCP)16 Pneumatically Operated Door17 Provision Cold Store and Freezer System19 Helideck Drains
No. Name of the system1 Deck Crane
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APPENDIX F DNV GL REQUIREMENTS RELATED TO MARINE, UTILITY AND SAFETY SYSTEMS
f a design when it is near to completion as possible, enter of gravity).
t watertight doors or hatch covers are hydraulically
/mm2 (5 m water), and the acceptance criteria shall
r leakage 1 litre per minute for doors or hatch covers
rs:
ors or hatch covers are hose tested. The water held at a distance of maximum 1.5 m from the door
der special circumstances, upon acceptance by all
for all watertight doors and hatch covers shall be
onds or more than 60 seconds. simultaneously within 60 seconds from the control
ree times by means of a local device and stored
atchway and at the same time hold both handles in
oth sides, after being closed centrally, and the door
osition.atch cover is closed centrally.tion properly.
ng system, low pressure (below lowest permissible).
F.1 Stability and watertight integrity
Table F-1 Stability and watertight integrity
System / equipment description
DNV GL OS / rule reference
DNV GL surveillance focus
Inclining test DNVGL-OS-C301Ch.2 Sec.1 [3.1]
— Confirm the results of an inclining test are gathered for the first unit oto determine accurately the light ship data (weight and position of c
Watertight / weathertight doors and hatches
DNVGL-OS-C301 Ch.2 Sec.2 [9.1]
— Pressure testing of watertight doors and hatches:
- Before installation (i.e. normally at the manufacturer), confirm thatested with exposure to the side most prone to leakage.
- The test pressure shall correspond to the pressure height + 0.05 Nbe:
- No leakage for doors or hatch covers with gaskets, maximum watewith metallic sealing.
DNVGL-OS-C301 Ch.2 Sec.2 [9.2]
— Hose testing of all watertight and weathertight doors and hatch cove
- After installation onboard, confirm watertight and weathertight dopressure shall be at least 0.2 mm2 (2 bar), and the nozzle shall beor hatch cover. No leakage shall be accepted.
- As an alternative to hose testing, chalk testing may be applied unparties involved.
DNVGL-OS-C301 Ch.2 Sec.2 [9.3]
— Function testing of watertight doors and hatch covers — After installation onboard the operation, control and alarm functions
tested. The following shall be verified:
- For each door, the total closing time shall not be less than 30 sec- It shall be possible to close all doors or hatch covers in one group
room.- It shall be possible to open and close the doors or hatch covers th
energy.- It shall be possible for a person to pass through the doorway or h
the “open position”.- It shall be possible to open the door or hatch cover locally from b
or hatch cover shall close automatically after such opening.- The door or hatch cover shall be mechanically locked in a closed p- The light and sound signals shall give warning when the door or h- The remote position indicator for doors or hatch covers shall func- The alarms for the following conditions shall function properly: - Start of standby pump, loss of power to control, alarm and indicati
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F.2 Fabrication and testing of offshore structures
rmed as a hydraulic test using water. Alternatively, t indicating liquid. Void spaces not part of the
e omitted from this tightness test. A void space rgo, ballast or fuel. Gas tightness of e.g. boundaries
ay be subject to appropriate methods accepted by
all be carried out before protective coating has been mposition may be applied prior to testing. Tightness ndividual welds, injection of air into root gap of fillet ultipass semiautomatic weld processes in butt welds
essure shall not exceed 0.2 bar and shall be reduced method shall give clear indications of small leaks. ed 0.2 bar above atmospheric pressure because of re or otherwise. The pressure shall be measured by ould be provided to release pressure in emergency
he top of the tank. The outside of the tank shall be
pplied at a maximum distance of 1.5 m. The nozzle
ral test. By agreement, the test shall be carried out est may be omitted for a series of sister vessels. out. hydraulically tested from at least one side.t for load case a) as defined in the relevant offshore nutes. The filling rate shall be restricted to avoid
ns or other damages have developed during the test.ads (etc.) which shall be watertight, are separately nks may be required. is required.
ed out. The test method and results shall be reported.er installation.
Table F-2 Fabrication and testing of offshore structures
System / equipment description
DNV GL OS / rule reference
DNV GL surveillance focus
Tanks DNVGL-OS-C401 Ch.2 Sec.4 [2.1]
— Testing of Tightness— Confirm that all tanks are tested for tightness. The test may be perfo
tightness may be confirmed by use of compressed air and an efficienstructural integrity in the accidental limit state (ALS) can normally bdefined as a confined space is typically not intended to carry liquid cabetween cofferdams/pump room and adjacent non-hazardous area, mthe purchaser.
— Tightness test by compressed air and an effective indicating liquid shapplied. A thin layer (< 50 m) of primer with documented chemical comay also be confirmed by the following methods: vacuum testing of iwelds (fillet air test). Tightness testing of continuous automatic and mof plated boundaries may be omitted.
— If compressed air and an efficient indicating liquid are used, the air prto a smaller value, but not less than 0.15 bar before inspection. TheCare should be taken so that the pressure in the tank does not exceunexpected raise in ambient temperature, falling atmospheric pressuan accurate method, such as a U-shaped tube with water. Means shcase.
— If water is applied, the pressure shall not be less than 25 kN/m2 at tdry and clean.
— For hose testing, the hose pressure shall be at least 200 kN/m2 and ainside diameter shall be at least 12.0 mm.
DNVGL-OS-C401 Ch.2 Sec.4 [3.1]
— Structural Tests— Confirm that at least one of several identical tanks undergo a structu
by applying water. In agreement with the purchaser, the structural tProtective coating may be applied before a structural test is carried
— Bulkheads between tanks arranged to carry different liquids shall be— The test pressure height shall be taken as the design pressure heigh
object standard. The pressure shall be maintained for at least 20 miexcessive dynamic design pressure.
— The structural test is considered successful if no significant deformatio— Confirm that closing appliances for access openings in decks, bulkhe
tested before installation. Structural testing of other parts outside ta— If structural tests reveal weaknesses in the structure, further testing
Corrosion protection systems
DNVGL-OS-C401Ch.2 Sec.5 [1.5]
— Installation of impressed current cathodic protection system:
- Confirm that testing of the proper functioning of the systems is carri- Final testing and acceptance of the system shall be performed aft
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F.3 Marine and machinery systems and equipment
s reviewed and approved by DNV in advance of the r and is considered complete when all systems,
ll be checked for compliance with approved
as practicable, in accordance with approved
f watertight boundaries from control room / station, s. atertight integrity, these valves shall be capable of l be provided at the remote control station.ply (electrical, hydraulic, and pneumatic) does not anks and in cooling water system for propulsion and
manufacturer, at a pressure equal to 1.5 times the working pressure at room temperature. The test
essure. For valves fitted on unit or installation’s side
ottom are hydrostatically tested at a pressure equal
llowing:
, steam pipes, compressed air pipes and feed pipes
eed not exceed working pressure by more than 70
duration one (1) hour.eakage and functionally tested under working
Table F-3 Marine and machinery systems and equipment
System / equipment description
DNV GL OS /rule reference
DNV GL surveillance focus
All systems / equipment
DNVGL-OS-D101Ch.3 Sec.1[5.1 to 5.3]
— General
- Commissioning shall be in accordance with submitted procedurecommissioning. Commissioning shall be witnessed by a surveyoequipment and instrumentation are operating satisfactorily.
— System and Equipment Checks
- During commissioning, all items of pipework and equipment shadocumentation and commissioning procedures.
— Functional Testing
- During commissioning, the systems shall be functionally tested,procedures.
All piping systems DNVGL-OS-C301Ch.2 Sec.2 [3.2]
— Confirm positive functional testing results of closure devices in way oas well as positive remote confirmation of the same closure device
— Where valves are provided at watertight boundaries to maintain wbeing operated from a control room. Valve position indicators shal
DNVGL-OS-D101Ch.2 Sec.1 [1.7]
— For remotely controlled valves, confirm that a failure in power supcause opening of closed valves or closing of open valves on fuel oil tpower generating machinery.
DNVGL-OS-D101Ch.2 Sec.2 [5.2]
— Confirm that all valve bodies are subject to a hydrostatic test by thenominal pressure. The nominal pressure is the maximum allowablepressure need not be more than 70 bar in excess of the nominal prand bottom, the test pressure shall not be less than 5 bar.
— Confirm that butterfly valves fitted on unit or installation’s side and bto 5 bar applied independently on each side of the closed disc.
DNVGL-OS-D101Ch.2 Sec.6 [6.1/6.2]
— Hydrostatic testing required after assembly on board — The piping shall be hydrostatically tested in accordance with the fo
- Fuel oil piping, heating coils in tanks, bilge, ballast and fire pipesof class III:
- 1.5 maximum working pressure, minimum 4 bar.- Hydraulic piping: - 1.5 maximum working pressure for 15 minutes. Test pressure n
bar.- Piping systems made from non-metallic material: - 1.5 maximum working pressure, minimum six (6) bar, minimum
DNVGL-OS-D101Ch.2 Sec.6 [7.1]
— Confirm that all piping systems are properly flushed, checked for lconditions.
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transfer stored crude oil, are hydrostatically tested ed not exceed the maximum working pressure by
aximum working pressure, and to a minimum of 14
the maximum pressure head on the head-capacity
not be less than the relief valve opening pressure. tested to 1.5 times the steam pressure.
ally not required.at design condition (rated speed and pressure head,
tisfactory tests have been previously performed and
y be de-ballasted by either pump.
tion testing.ystem.d remote status indication.
tchboards.generation (UPS function).
any tank / compartment may be removed by either
d voids fitted with such.fitted within pump / essential machinery rooms. pump / essential machinery rooms.
therwise specified herein.
r installation, while in an intact condition, from the within three (3) hours.
Table F-3 Marine and machinery systems and equipment (Continued)
Pump hydrostatic testing
DNVGL-OS-D101Ch.2 Sec.2 [4.2]
— Confirm that all pump housings, excluding those for pumps which to 1.5 times the maximum working pressure. The test pressure nemore than 70 bar.
- Pumps for transfer of crude oil shall be tested at 1.3 times the mbar.
- For centrifugal pumps, the maximum working pressure shall becurve.
- For displacement pumps, the maximum working pressure shall - The steam side of the steam driven pumps shall be hydraulically
— Hydrostatic testing of pump housings on submerged pumps is normPump capacity testing
DNVGL-OS-D101Ch.2 Sec.2 [4.3]
— Confirm that pump capacities are checked with the pumps running viscosity, etc).
- The capacity test need not be applied for pump designs where sadocumented.
Ballast, bilge and drainage systems - general
DNVGL-OS-D101Ch.2 Sec.3 [2.1]
— Ballast and Bilge System
- Confirm functional redundancy of system such that any tank ma- Confirm installed pump capacity meets design requirements.- Confirm functionality of the central Ballast and Bilge Control Sta- Witness final comprehensive testing of the Ballast and Control S- Confirm self-closure of ballast valves in emergency situations an- Confirm power supply function from normal and emergency swi- Confirm status indications remain following shutdown of power
— Bilge System
- Confirm functional redundancy of system such that the bilge of pump.
- Confirm free draining arrangements for tanks, compartments an- Confirm location and function of both branch bilge suction lines - Confirm location and function of emergency bilge suction within- Confirm installed pump capacity meets design requirements.
Ballast, bilge and drainage systems – column stabilized units and installations
DNVGL-OS-D101Ch.2 Sec.3 [3.1]
— Confirm that the general requirements are complied with, unless o
- The ballast system is to provide the capability to bring the unit omaximum normal operating draught to a severe storm draught,
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fitted to lube oil tanks above double bottom and
an 0.5 m3, and tanks which upon unintended closing
m of remote shut-off valves as fitted to fuel oil (FO) confirm the proper location of remote control station.
es fitted on or nearby engine room bulkheadsm positions above the floor plates.
ded opening of a filter under pressure.
the following pumps and fans from a central place
related manual interlock for over temperature.
Table F-3 Marine and machinery systems and equipment (Continued)
Lubricating oil systems
DNVGL-OS-D101Ch.2 Sec.4 [3.4]
Confirm proper function of remote shut-off of normally open valves as located below top of the tank or overflow outlet.
— This requirement may be waived for small tanks with volume less thof the valves, may result in loss of main functions.
Fuel oil systems DNVGL-OS-D101Ch.2 Sec.4 [3.4 to 3.6 and 3.9]
— Fuel Oil Tank Valves
- Confirm proper function from central position outside engine rootanks and located below top of the tank or overflow outlet. Also,
— Arrangement of Valves
- Confirm location and proper function of fuel oil line shut-off valv- Confirm all valves in the fuel oil system shall be controllable fro
— Oil Filters
- Confirm duplex filter arrangement such that it prevents unintenDNVGL-OS-D201Ch.2 Sec.2 [8.5]
— Remote Stop of Fuel Oil Pumps and Fans— Confirm function of remote emergency stop of the power supply to
outside the engine and boiler room:
- Fuel oil transfer pumps- Fuel oil booster pumps- Nozzles cooling pumps when fuel oil is used as coolant- Fuel oil purifiers- Pumps for oil-burning installations- Fans for forced draught to boilers- Fans for ventilation of engine and boiler rooms- Thermal oil circulation pumps- Hydraulic oil pumps.
DNV Rules for ShipsPt.4 Ch.8 Sec.8A400
— Fuel Oil Pre-Heaters— Confirm proper function of oil temperature control (Max 50ºC) and
System / equipment description
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g and an approved fixed fire-extinguishing system,
oil-burner and oil-booster pumps outside the room.
the heater in case consumers are shut-off. ble location outside the heater room, of stop-valves al-oil.ccessible location outside the heater room, of
ure control and bypass arrangements and fire
10 minutes after stop of burners. to be able to keep the oil temperature within the
:
Low
ly)
nd capacity tested according to an approved test ach coil, covering the whole range of heater loads. aximum heater rating to be tested.
bove 80ºC when boilers are operated at maximum
Table F-3 Marine and machinery systems and equipment (Continued)
Thermal oil systems DNV Rules for ShipsPt.4 Ch.7 Sec.3B100 / B200 / B300 / B600 / B700
— Confirm function of mechanical ventilation, automatic fire detectinoperated from an easily accessible place outside the room.
— Confirm location and proper function of remote stop of ventilation, Ventilating ducts shall be possible to close by means of flaps.
— Confirm proper automatic function of minimum circulation through— Confirm local and remote manual operation, from an easily accessi
fitted to oil fired heater main inlet and main outlet pipes for therm— Confirm local start, stop and remote manual stop, from an easily a
circulation pumps and heater burners.— For exhaust fired thermal oil heaters, confirm function of temperat
extinguishing arrangements as fitted.— Confirm that the circulating pumps remain in operation at least for
DNV Rules for ShipsPt.4 Ch.7 Sec.7E100 / E200
— Confirm proper automatic control of thermal-oil outlet temperaturelimits for safe operation under all load conditions.
— Confirm alarm and automatic shutdown of burner for the following
- Thermal Oil: Temperature Outlet High, Flow Low and Pressure - Flue Gas: Temperature High- Expansion Tank: Level Low, Temperature High (alarm only)- Forced Draft: Fan Stopped- Heavy Fuel Oil: Temperature or Viscosity High / Low (alarm on- Flame: Flame Ignition and / or Flame Failure.
DNV Rules for ShipsPt.4 Ch.7 Sec.8D600
— After onboard installation, confirm that the system is functionally aprogram. The test procedure shall include flow measurements for eThe heater system charge shall be a thermal-oil, which will allow m
Feed water and condensation system
DNVGL-OS-D101Ch.2 Sec.4 [6.2]
— Confirm the preheating arrangement maintains the temperature aload during normal service.
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turbines shall have capacity for a number of starts
rposes – three (3) starts each, total capacity need
matic attempts shall be limited to three (3) starts
ified purposes, the capacity of the system shall be
ng air receivers shall be sufficient for three (3) starts ve (12) starts and need not exceed eighteen (18)
charging air receivers of capacities specified in 201 hour.ict consumption of starting energy.
lant is such as to provide comfortable working ir to the diesel engines, boilers, and to prevent heat-
that pockets of stagnant hot air are avoided. Special and to all normal working areas, where reasonably
ble inlet devices. from air intake to air passing from the engine room perature of maximum +35ºC.
e in the engine room, which does not exceed 50 Pa.anges per hour and non-hazardous enclosed spaces
matic shutdown of gas and crude oil supply:
) in the ventilated duct. For crude oil fired units, accepted as an alternative
oom. This requirement may be dispensed with if the
Table F-3 Marine and machinery systems and equipment (Continued)
Pneumatic starting arrangements
DNVGL-OS-D101Ch.2 Sec.4 [10.2]
— Confirm starting systems for internal combustion engines and gas specified below without reloading of air receivers:
- Engines for driving electric generators and engines for other punot exceed six (6) starts
- Engines for driving emergency generators – six (6) starts, auto
— Confirm if a starting system serves two or more of the above specthe sum of the capacity requirements.
— Confirm for multi-engine propulsion plants, the capacity of the startiper engine. However, the total capacity shall not be less than twelstarts.
— Confirm compressors are installed with total capacity sufficient for and 202 from atmospheric to full pressure in the course of one (1)
DNVGL-OS-D201Ch.2 Sec.2 [8.2]
— Confirm that failed automatic starting attempts are limited to restr
HVAC system DNVGL-OS-D101Ch.2 Sec.4 [11.3]
— Confirm for machinery spaces that the capacity of the ventilation pcondition in the engine room, to supply the necessary combustion asensitive apparatus from overheating.
- Confirm that air is distributed to all parts of the engine room, so considerations should be given to areas with large heat emissionfresh and clean outdoor air should be provided through adjusta
- Confirm for units with unrestricted location, the temperature riseup to the casing should be maximum 10ºC for an outside air tem
— Confirm that the air exhaust fans maintain a slight positive pressur— Confirm that hazardous enclosed spaces receives twelve (12) air ch
receives six (6) air changes per hour.Use of gas and crude oil for auxiliary boilers and turbines
DNVGL-OS-D101Ch.2 Sec.4 [12.3.11]
— Confirm the following fault conditions shall release alarm and auto
- Detected gas of maximum 20% of the lower explosive limit (LELdetection of liquid at all low points in the ventilated duct may be
- Detected gas of maximum 20% of the LEL in engine and boiler rducting has no opening (e.g. hood) into the machinery space
- Loss of ventilation in the duct- Abnormal pressure variation in the fuel supply line- Detected fire in the engine and boiler room.
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is provided the following minimum requirements:
ent of ingestion of flammable gas.e present:
er applied to the motors. The brake alarm shall be
reval is provided. For a lattice leg unit, the load per ignal is given when the maximum load is exceeded.
ording to accepted methods.
ifting and descending load. The duration shall reflect
Table F-3 Marine and machinery systems and equipment (Continued)
General marine equipment
DNVGL-OS-D101Ch.2 Sec.5 [2.2]
— Confirm that a space is pressurized to make it non-hazardous, and
- Pressurization air is taken from a safe area- An alarm system is fitted to indicate loss of air pressure- An air-lock system with self-closing doors are fitted- An exhaust outlet is located in a non-hazardous area- A combustion air inlet is located in a non-hazardous area.
— Automatic shutdown is arranged to prevent overspeeding in the evJacking gear machinery
DNVGL-OS-D101Ch.2 Sec.5 [3.11]
— Confirm that the following control and monitoring arrangements ar
- Remote indication and alarm if a brake is not released when powgiven by an independent mechanical sensor
- Remote indication and alarm for overheating of an electric moto- A permanent remote indication of loads during jacking and retri
chord is as a minimum to be presented. Confirm that an alarm sDNVGL-OS-D101Ch.2 Sec.5 [3.12]
— Confirm that a spin test and contact pattern test is carried out acc
DNVGL-OS-D101Ch.2 Sec.5 [3.14]
— Confirm that jacking machinery is tested with the highest specified lone operating cycle.
— Confirm that the interlock is tested.
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ering gear shall be subjected to the required se of:
shop shall be tested at 1.5 times design pressurerking pressure
applicable)
mechanical means, confirm that mutual adjustment
opulsion thruster azimuth gear power units:
possible to release the anchor lines while risers are ting this is provided.wire rope / chain in case of an emergency. protected area close to the winch itself, and from a hall be possible to apply the brakes once in order to
eration of the windlasses or winches shall take place.top system and an audible alarm system in case of
Table F-3 Marine and machinery systems and equipment (Continued)
Thrusters DNVGL-OS-D101Ch.2 Sec.5 [5.1]DNV Rules for ShipsPt.4 Ch.14 I100
— Shipboard testing— After installation on board the vessel, and prior to seatrial, the ste
hydrostatic and running tests. The test shall as a minimum compri
- Hydrostatic testing;- Parts of steering gear that has not been pressure tested at work- Assembly shall be tested at a minimum 1.5 times maximum wo- Function testing of the steering gear- Testing alarms and indicators- Autostart test of power units- Testing all start and stop functions- Test control transfer between bridge and local control- Test safety valve setting (if not performed during in Workshop)- Testing function and setting of overcurrent protection- Test and check functions and settings in frequency converter (if- Check mechanical rudder indicator.
— On double rudder installations where two units are synchronized byis tested.
DNVGL-OS-D101Ch.2 Sec.5 [5.9]
— Confirm that alarms are provided for the following faults:
- Stop of prime mover- Power failure of remote control system- Power failure of alarm system- Low level in lubrication oil tank (if provided)- Low level in hydraulic supply tank- Low pressure in hydraulic system- High level in bilge well.
— The following additional alarms shall be provided and tested for pr
- Power failure- Phase failure- Motor overload- High lubrication oil inlet temperature.
Windlasses, winches and chain stoppers for temporary or limited use
DNVGL-OS-D101Ch.2 Sec.5 [6.3]
— Confirm that a riser disconnect system is fitted, such that it is not connected to the unit. Confirm that a special safety system preven
— Confirm that it is possible to carry out a controlled lowering of the — Confirm that it is possible to release the brakes or stoppers from a
manned control room or bridge. During the emergency release, it shalt the lowering and therefore releasing them again.
— Confirm that an audible alarm system exists to warn that remote op— Confirm that winches are fitted with a load indicator, emergency s
overload.
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F.4 Electrical installations
r to all services necessary for maintaining the ship in
ng, propulsion and steering, and to ensure safety of loss of any one of the generators in service, including:
f the standby generator occurs preferably within 30
controlled by an automation system. The following
W and kVAr) taken by the generators, with the
ot possible.rs in service.g blackout. power.for duration sufficient for conducting all related
ng surface temperature.olgear assemblies (may be submitted by the
ocumentation. Control and protection shall be tested
lete function tests after installation onboard. is subject to a voltage test between the circuits and
equal to twice the rated voltage plus 1000 V with a ny frequency between 25 and 100 Hz. he test voltage shall be a minimum of 500 V. ompletion of the voltage test. Confirm that the testing ulation level shall be at least 1 MOhm.
Table F-4 Electrical installations
System / equipment description
DNV GL OS /rule reference
DNV GL surveillance focus
Main electric power supply system
DNVGL-OS-D201Ch.2 Sec.2 [2.1]
— Confirm the main power supply system has the capacity to supply powenormal operation without recourse to the emergency source of power.
DNVGL-OS-D201Ch.2 Sec.2 [2.2]
— Confirm that electrical supply to equipment necessary for station keepithe offshore unit, will be maintained or immediately restored in case of
- Confirmation that starting and connection to the main switchboard oseconds, but not more than 45 seconds after loss of power.
DNVGL-OS-D201Ch.2 Sec.2 [8.2]
— Confirm system for start, stop and load sharing between generators, ifalarms shall be confirmed:
- Power failure to the control system- Starting failure of prime mover- High and low frequency- High and low voltage- Excessive percentage difference in loads (kVA or alternatively both k
necessary time delay, when in symmetrical load sharing mode.— Confirm simultaneous connection of generators on to the same bus is n— Confirm restoration of power in case of loss of any one of the generato— Confirm all generator sets are arranged with systems for starting durin
DNV Rules for ShipsPt.4 Ch.3 Sec.1I300
— Confirm that propulsion engines are tested for four (4) hours at 100% — Confirm that engines for auxiliary purposes are tested at 100% power
inspections or measurements, however, not less than one (1) hour.
- Confirm insulation of hot surfaces during maximum load by measuriSwitchgear and control assemblies
DNVGL-OS-D201Ch.2 Sec.4 [4.1]
— Confirm that the following tests are performed on switchgear and contrmanufacturer):
- Function test: all basic functions including auxiliary functions- Insulation resistance test- High voltage test.
— Confirm that all circuits are verified installed as shown in the as-built dfor correct functioning.
— Confirm that switchgear or control gear assemblies are subject to comp— Confirm that switchgear and assemblies with rated voltage above 60 V
between live parts and the enclosure. The test voltage shall be minimumminimum of 1500 V. The test voltage shall be applied for 1 minute at a
— For switchgear assemblies with rated voltage below 60V, confirm that t— Confirm that the insulation resistance test is completed prior to and on c
does not cause any reduction in the switchgear insulation level. The ins
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o the emergency switchboard in case of failure of the rm that it is automatically started within 45 seconds
ices essential for safety in an emergency. Hence, the e considered as part of the main distribution system,
ed from the main switchboard by an interconnecting e main switchboard, and shall be disconnected
from the main source of electrical power.ystem and the testing of automatic starting
evice with a stored energy capability of at least three d for an additional three (3) starts within 30 minutes,
time. One starting motor is sufficient.
total consumer load is applied suddenly, or;
on main switchboard
aximum step loading is not exceeded are demonstrated at ship’s trails.on sufficient for conducting all related inspections or
easuring surface temperature. at least 80% capacity within 10 hours while system
ing of a battery fails.
epted for the two (2) alarms listed here;nsured that an active alarm will not prevent initiation
Table F-4 Electrical installations (Continued)
Emergency power supply system
DNVGL-OS-D201Ch.2 Sec.2 [3.1]
— Confirm the emergency source of power to be automatically connected tmain source of electric power. If the power source is a generator, confiand supplies at least the services required by transitional power.
— Confirm the electrical power available to be sufficient to supply all servemergency switchboard and emergency distribution boards are not to beven though supplied from such during normal operation.
— Confirm that in normal operation, the emergency switchboard is supplifeeder, which shall be protected against overload and short circuit at thautomatically at the emergency switchboard upon failure of the supply
— Confirm provision for the periodic testing of the complete emergency sarrangements.
DNVGL-OS-D201Ch.2 Sec.2 [3.3]
— Confirm that emergency generating sets are equipped with a starting d(3) consecutive starts. Confirm that a second source of energy is provideunless manual starting can be demonstrated to be effective within this
— The duration of each start shall be minimum 10 seconds.DNV Rules for ShipsPt.4 Ch.2 Sec.4A100
— Confirm governor conditions for emergency generator sets when their — The total consumer load is applied in steps, subject to:
- The total load is to be supplied within 45 seconds since power failure- The maximum step load is declared and demonstrated- The power distribution system is designed such that the declared m- The compliance of time delays and loading sequence with the above
DNV Rules for ShipsPt.4 Ch.3 Sec.1I400
— Engines for auxiliary purposes to be tested at 100% power for a duratimeasurements, however not less than one (1) hour.
— Confirm sufficient insulation of hot surfaces during maximum load by mBattery systems DNVGL-OS-D201
Ch.2 Sec.2 [4.1]— Confirm that each charging device has sufficient rating for recharging to
has normal load.— Confirm that an alarm is given at a manned control station if the charg— Confirm that an alarm shall be given if the battery is discharged.
- A single common alarm signal to a central alarm system may be acc- If other alarms are included in the common alarm signal, it must be e
of any new alarm with its audible and visual indication.
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ing start attempts of the engines being normally
le propeller or other devices enabling the engine to
the starting batteries is sufficient for three (3) starts exceed 18 starts.as sufficient capacity for at least three (3) start of each starting shall be taken as a minimum of ten
ship» condition within 30 minutes using only the
with the tests carried out on a prototype of a machine d out on each machine.
tors include:
n name plate; verification of degree of enclosure f the bearing or lubrication system during running
inutes); withstand voltage test (1 minute); windings rement of insulation resistance; overload or transient loading and unloading (AC generator); suring of short circuit characteristics (AC generator);
factor (AC synchronous motor or generator); tor); a steep fronted impulse test (for high voltage
nclude:
n name plate; verification of degree of enclosure f the bearing or lubrication system during running
); withstand voltage test (1 minute); windings rement of insulation resistance; no load current at
t acceptable starting and running performance is
Table F-4 Electrical installations (Continued)
Engines with electric starter
DNVGL-OS-D201Ch.2 Sec.2 [5.1.1]
— Confirm that each battery has sufficient capacity for at least the followsupplied:
- Twelve (12) starts for each reversible engine;- Six (6) starts for each non-reversible engine connected to a reversib
be started with no opposing torque.- The duration of each starting shall be a minimum of 10 seconds.
— For multi-engine propulsion plants, it shall be confirmed the capacity ofper engine, total capacity shall not be less than 12 starts and need not
— For auxiliary engines, it shall be confirmed that each starting battery hattempts of each of the engines being normally supplied. The duration (10) seconds.
Rotating machinery - general
DNVGL-OS-D101Ch.2 Sec.1 [2.3.13]
— Confirm that machinery can be brought into operation from the «dead facilities installed onboard.
DNVGL-OS-D201Ch.2 Sec.5 [3.1]
— Confirm that electrical machines are tested at the manufacturer’s works or the first of a batch of machines. Confirm that routine tests are carrie
— The type tests (TT) and routine tests (RT) that are required for genera
- Air gap measured or verified; visual inspection, verification of data oprotection; vibration or balance of the machine including operation otests; overspeed tests (20% in excess of rated r.p.m. for two (2) mresistance to be measured; temperature-rise test at full load; measuovercurrent test; measuring of voltage regulation during steady andmeasuring of open circuit voltage characteristics (AC generator); meameasuring of excitation current at rated voltage, current and powermeasuring of steady short circuit condition (AC synchronous generamachines).
— The type test (TT) and routine tests (RT) that are required for motors i
- Air gap measured or verified; visual inspection, verification of data oprotection; vibration or balance of the machine including operation otests; overspeed tests (20% in excess of rated r.p.m. for 2 minutesresistance to be measured; temperature-rise test at full load; measurated voltage and frequency; overload or overcurrent test.
— Confirm that all machines are tested onboard, after installation, so thaverified with full capacity of driven equipment.
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e starting and running performance are verified with
ther with their switchboard equipment (switchgear or
erating sets. generating sets. short circuit, other protection like earth fault,
sets.
ss than 10% of the rated frequency with a recovery e maximum electrical step load is switched on or off. and shall be such that prime movers - running at no r followed by the next 1/3 after an interval sufficient
the prime mover shall be able to take a sudden ad below 2/3 of full power. Steady state conditions
ge of 20% to 100% of total load. The load on any the total load by more than 15% of the rated power hine in question, whichever is the less.
range 20 to 100% of the rated reactive load of each all not differ from its proportionate share of the total t generator in parallel, or not more than 25% of the
Table F-4 Electrical installations (Continued)
Rotating machinery - general(continued)
DNVGL-OS-D201Ch.2 Sec.10 [4.4]
— All machines shall be tested at site, after installation, so that acceptablfull capacity of driven equipment, alternatively full generator load.
— Confirm electrical characteristics and control of all generating sets togeprotection and cabling) during full load test.
— Confirm engine room ventilation / airflow during full load test of all gen— Confirm voltage regulation, speed governing and load sharing for of all— Confirm overload protection, reverse power protection, overcurrent and
differential, undervoltage, overvoltage (if applicable) for all generating— Confirm synchronizing systems for all generating sets.
Rotating machinery - load steps
DNV Rules for ShipsPt.4 Ch.2 Sec.4A100
— Confirm transient frequency variations in the electrical network to be letime to steady state conditions not exceeding five (5) seconds, when th
— Confirm application of electrical load to be possible with three load stepsload - can suddenly be loaded to 1/3 of the rated power of the generatoto restore the speed to a steady state condition.
— Finally, the sudden load step from 2/3 to full load applies. Additionally,application of not less than 1/3 of full load when running at any part loshall be achieved in not more than five (5) seconds.
— Confirm parallel running of generating sets (active load, kW) in the rangenerating set shall not normally differ from its proportionate share of of the largest machine or 25% of the rated power of the individual mac
DNVGL-OS-D201Ch.2 Sec.5 [2.4]
— Confirm parallel running of generating sets (reactive load, kVAr) in thegenerator. The actual reactive load (mean value, if oscillations occur) shreactive load by more than 10% of the rated reactive load of the largessmallest generator's rated reactive load, if this is less than the former.
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routine tests (RT) being carried out on each batch of identical transformers.
; measuring of insulation resistance; measuring of g of winding resistance; short circuit impedance and AC withstand voltage test; inducted AC withstand s above Um ≥ 3.6 kV, maximum level of partial
e and enclosure all connected together. The full test
ed in accordance with requirements for the
ubjected to a high voltage test with a test voltage of
ing the insulation resistance of a new, clean, dry een carried out. The test shall be carried out between:
nds of each polarity or phase are individually
Table F-4 Electrical installations (Continued)
Power transformers
DNVGL-OS-D201Ch.2 Sec.6 [2.1]
— Confirm that transformers are tested at the manufacturer’s works withtransformer, and type tests (TT) carried out on a prototype or the first
— The following routine tests (RT) are to be carried out:
- Inspection of enclosure, terminations, instrumentation or protectionvoltage ratio at no load and check of phase displacement; measurinload losses; measuring of no-load loss and current; separate-sourcevoltage test; partial discharge measurement on transformer windingdischarge shall be 10 pC.
— The following type test (TT) is to be carried out:
- Temperature rise test,— Confirm that the separate-source AC withstand voltage test involves:
- A high voltage test is applied to a new and completed transformer- The test is carried out immediately after the temperature rise test- The test is applied between each winding and the other windings, fram
voltage shall be maintained for one (1) minute- Single phase transformers for use in a polyphase group shall be test
transformers as connected together in the system- After rewinding or other extensive repair, the transformer shall be s
at least 75% of that minimum test voltage.— Confirm that insulation resistance test is carried out and involves measur
transformer, after the temperature rise test and high voltage test have b
- All current carrying parts, connected together, and earth- All current carrying parts of different polarity or phase, where both e
accessible.
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ad, and specified overload capacity given by a current
ithstand two consecutive start attempts immediately ted.an 60 Volt in less than five (5) seconds (or a residual is not achievable, warning signboards shall be fitted.
ng alarms shall be provided: when the discharging automatic bypass is in operation for on-line units;
voltage, frequency and current.t is possible. Manual resetting / restarting of the unit
s and are carried out on each converter. These tests
igh voltage tests); insulation resistance test; control t piping/hoses.ks and are carried out on a prototype of a converter
frequency tolerance test; stored energy and restored ce test; rated current test/full load test; temperature ailure tests; capacitor discharge; pressure test of
ivers are performed with all relevant ship systems
functions, an alarm is initiated. In case of duplicated
power supply for systems that are required to operate specify the need.
Table F-4 Electrical installations (Continued)
Semi-conductor converters
DNVGL-OS-D201Ch.2 Sec.7 [1.2.1]
— Confirm that the converter has a capacity of at least 100% continuous loof maximum duration of time.
— Confirm for motor drives (including soft starters), shall as a minimum wfollowed after stopping, or starting up from cold without being overhea
DNVGL-OS-D201Ch.2 Sec.7 [1.2]
— Confirm that capacitors within a converter shall be discharged to less thcharge of less than 50 mC) after removal of power. If this requirement
— Confirm that alarm is given for power supply failure and trip of unit.— Confirm that for power supply units with batteries included, the followi
battery fails, alternatively if the battery is being discharged; when the operation of battery protective device.
— Confirm that converters have the possibility for monitoring the output — Confirm that restarting the converter in a normal manner after a blackou
shall not be necessary.DNVGL-OS-D201Ch.2 Sec.7 [2.1]
— Confirm that converters are routine tested (RT) at the manufacturer’s workshould include:
- Visual inspection; function test (UPS switch test); insulation tests (hand monitoring system; cooling failure tests; pressure test of coolan
— Confirm that converters are type tested (TT) at the manufacturer’s woror the first batch of identical converters. These tests should include:
- Visual inspection; function test (UPS switch test); input voltage and energy tests; insulation tests (high voltage tests); insulation resistanrise test; control and monitoring system; short circuit test; cooling fcoolant piping/hoses.
DNVGL-OS-D201Ch.2 Sec.10 [4.4]
— Confirm that functional tests of semi-conductor converters for motor drsimultaneously in operation, and in all characteristic load conditions.
Control power DNVGL-OS-D201Ch.2 Sec.2 [8.1]
— Confirm that upon failure of the power supply to essential and importantsupplies, both shall be monitored.
— Confirm battery or uninterruptible power supply is provided as stand-by during black-out, restore normal conditions or if specific requirements
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ndary distribution system has a device or devices to e an audible or visual indication in case of abnormally
ged for operation at 1/3 or less of the minimum earth ction is arranged for less than 20% of the minimum
pment or give an alarm on a manned control position.er to prevent simultaneously closing of both feeders s’ short circuit strength. A short time parallel feeding
automatic disconnection of one of the parallel feeders
t the generator breaker trips at 110% to 125% of ort circuit protection is installed such that the breaker
ltage protection, such that it will trip when generator
oad, with a supply voltage containing the following
ingle harmonic being greater than 5% of voltage RMS
consumers) connected during installation shall ds earth and between phases where applicable (i.e.
eans of a suitable instrument applying a DC voltage
minimum resistance 1 M-ohmm resistance 1 M-ohmum resistance (rated voltage / 1000) + 1 M-ohm
imum resistance (rated voltage / 1000) + 1 M-ohm.ent are carried out.
g installation.rmal conditions, and in any abnormal condition in
operating modes and are controlled by automatic
Table F-4 Electrical installations (Continued)
Electrical distribution systems
DNVGL-OS-D201Ch.2 Sec.2 [7.1]
— Confirm that each insulated, or high resistance earthed primary or secocontinuously monitor the values of electrical insulation to earth and to givlow insulation values.
— Confirm that on high voltage systems, automatic disconnection is arranfault current. On low-resistance earthed neutral systems, the disconneearth fault current.
DNVGL-OS-D201Ch.2 Sec.2 [7.2]
— Confirm loss of protective functions to either trip the corresponding equi— Confirm interlocks when a switchboard has two incoming feeders in ord
when the parallel-connected short circuit power exceeds the switchboardas a “make before break” arrangement is accepted when arranged with within 30 seconds.
DNVGL-OS-D201Ch.2 Sec.2 [7.3]
— Confirm that generators are fitted with overcurrent protection such thanominal current, with a time delay of 20 to 120 seconds. Confirm that shtrips at a maximum of 1 second delay.
— Confirm that generator circuit breakers are also equipped with undervovoltage drops within the range of 70% to 35% of its rated voltage.
DNVGL-OS-D201Ch.2 Sec.3 [3.1]
— Confirm equipment is designed to operate at any load up to the rated lharmonic distortion:
- Total harmonic content not exceeding 8% of voltage RMS value; no svalue.
DNVGL-OS-D201Ch.2 Sec.10 [4.3]
— Confirm that all outgoing power circuits from switchboards (cables andundergo insulation resistance testing to verify its insulation level towarswitchboards assembled onboard).
— The insulation resistance tests (megger tests) shall be carried out by maccording to:
- Rated voltage ≤ 250 V, minimum test voltage 2 x rated voltage (V), - 250 < rated voltage ≤ 1000 V, minimum test voltage 500 V, minimu- 1000 < rated voltage ≤ 7200 V, minimum test voltage 1000 V, minim- 7200 < rated voltage ≤ 15000 V, minimum test voltage 5000 V, min
DNVGL-OS-D201Ch.2 Sec.10 [4.4]
— Confirm that function and load tests of essential and important equipm— Confirm settings of protective functions of consumers.— Confirm function of protective functions of consumers, if wired up durin— Confirm satisfactory operation (by use of tests) of the distribution in no
which the system is intended to operate.— Confirm start-up and stop sequences are tested together with different
control systems when relevant. — Confirm interlocks, alarms and indicators.— Confirm all control modes from all control locations.
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ble to be stopped in an emergency from an easily
lure, trip of unit and earth fault (except dedicated
rms are provided for when the battery is being n of battery protective device is active. Confirm that
atteries are put into service:
ower is being switched off (black out simulation) for ional, emergency or clean power) systems serving
nning on expected load (in battery feeding mode) for a levant rules (30 minutes unless specified by other Rule
upply with intended loading onboard. with all relevant ship systems simultaneously in
Table F-4 Electrical installations (Continued)
Emergency stops DNVGL-OS-D201Ch.2 Sec.2 [8.5]
— Confirm that at least the following pumps and fans are arranged and aaccessible position outside the space being served:
- Fuel oil transfer pumps- Fuel oil feed and booster pumps- Nozzles cooling pumps when fuel oil is used as coolant- Fuel and lubrication oil purifiers- Pumps for oil-burning installations- Fans for forced draught to boilers- All ventilation fans- All electrical driven lubrication oil pumps- Thermal oil circulating pumps- Hydraulic oil pumps in machinery space.
Battery / UPS system
DNVGL-OS-D201Ch.2 Sec.7 [1.2]
— Confirm monitoring with alarm for UPS is provided for power supply faisystem for single consumers).
— Confirm for power supply units with batteries included, that additional aladischarged, when the bypass is in operation for on-line units and operatioalarms are given to main alarm system.
DNVGL-OS-D201Ch.2 Sec.10 [2.3]
— Confirm that the following tests and inspections are performed before b
- Ventilation shall be verified, including natural ventilation;- Capacity tests, voltage measurements;- Alarms and monitoring functions.
DNVGL-OS-D201Ch.2 Sec.10 [4.4]
— Confirm positive function test result for dip free voltage when feeding pUPS systems and regular D.C. battery backed up power supply (transitessential or important functions.
— Confirm correct capacity of battery backed up power supply system by ruperiod determined by the requirements for the actual system and by the rerequirement).
— Confirm that alarms are verified for their correct function.— Confirm functional test result of semi-conductor converters for power s— Confirm functional tests of semi-conductor converters for motor drives
operation, and in all characteristic load conditions.
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t those parts of the ship normally accessible to, and ce of electrical power. These areas include:
appliances, and area of water which they are launched;nnel lift cars and lift trunksntrol positionstion of safety equipment may be necessary to bring emergency switchboardere controls of machinery essential for the -off of the power plant are located
hting to is automatically supplied from the emergency
two alternative circuits, one from the main source of itch shall be arranged for the two supply circuits.
capacity.
l be subject to one of the following alternative high screen:
l be not less than:
em, applied for 24 hours.tem applied between the conductor and the metallic
g shall be confirmed:
unninged equipment for essential servicess in the cooled equipment for important services.ents for all equipment equipped with air / water heat d rotating equipment (which are not located in heated
Table F-4 Electrical installations (Continued)
Lighting DNVGL-OS-D201Ch.2 Sec.2 [6.2]
— Confirm main electric lighting system to provide illumination throughouused by, passengers or crew, and shall be supplied from the main sour
- Every muster and embarkation station, survival craft and their launching- All service and accommodation alleyways, stairways and exits, perso- All machinery spaces and main generating stations including their co- All control stations, machinery control rooms, locations where opera
the installation to a safe stage, steering gear and at each main and - All spaces from which control of drilling process is performed and wh
performance of this process, or devices for the emergency switching- All stowage positions for firemen’s outfits- At the fire pump and its starting position- At the sprinkler pump and its starting position- At the emergency bilge pump and its starting position- Floodlight and perimeter lights on helicopter landing decks- In all cargo pump rooms.
— Confirm that upon loss of main source of power, all required emergency ligsource of power.
— Confirm the navigation light switchboard (controller) to be supplied by power and one from the emergency source of power. A changeover swConfirm that upon failure of either power supply, an alarm is given.
Parallel connected cables
DNVGL-OS-D201Ch.2 Sec.2 [10.6]
— Confirm that single cables, after installation, do not carry more than its— Confirm that this is demonstrated at full load of the consumer.
High voltage cable after installation
DNVGL-OS-D201Ch.2 Sec.10 [4.3]
— After installation, with termination kit applied, high voltage cables shalvoltage tests, with the voltage applied between the conductors and the
a) When a D.C. voltage withstand test is carried out, the voltage shal1.6 · (2.5 · U0 + 2) kV for cables with U0 not exceeding 3.6 kV
4.2 · U0 kV for cables with U0 in excess of 3.6 kV The test voltage shall be maintained for a minimum of 15 minutes;
b) A power frequency test at the normal operating voltage of the systc) A power frequency test with the phase-to-phase voltage of the sys
screen or earth for five (5) minutes.Cooling and anti-condensation
DNVGL-OS-D201Ch.2 Sec.3 [4.2]
— Where electrical equipment depends on additional cooling, the followin
- Alarm is initiated when auxiliary cooling or ventilation motors stop r- Alarm is initiated based on winding temperature for windings in cool- Alarm is initiated based on high winding temperature in the winding- Confirm automatic operation (on standstill condition) of heating elem
exchangers as well as for all high voltage converters, transformers anand ventilated spaces).
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cessary torque, power, and for A.C. systems reactive ash stop (seatrial) conditions.
frequency variations exceed normal limits, if other
ation systems, an alarm is given on the navigating e system into a safe operational mode are executed.
t cause appreciable change of the thrust level or
m when there is not adequate available power.ed with an automatic control system having at least
s
is overloadedf one running generator is tripped. If necessary by
stem fails, that is no start or stop of generators shall
adequate power is no longer available.yed with separate warnings separated from group
or converters having forced cooling
i-conductor converters having closed cooling method n motor itself. Auxiliary contacts from motor starters
mi-conductor converters
brushless excitation systems and for machines rated
Table F-4 Electrical installations (Continued)
Electric propulsion DNVGL-OS-D201Ch.2 Sec.12 [1.3 and 1.4]
— Confirm the system to have sufficient overload capacity to provide the nepower needed during starting (seatrial), manoeuvring (sea trial) and cr
- During crash-stop manoeuvres, it will be accepted that voltage and equipment operating on the same net is not unduly affected.
DNVGL-OS-D201Ch.2 Sec.12 [1.5]
— Confirm upon detection of abnormal conditions in the generators’ excitbridge and in the engine control room and automatic actions to bring th
DNVGL-OS-D201Ch.2 Sec.12 [1.6]
— Confirm that a failure of the remote propulsion control system does nodirection and not prohibit local control.
— Confirm thrust limitation of the normal propulsion remote control syste— Confirm electric power generation and distribution system to be equipp
the following functions:
- Ensure adequate power for safe manoeuvring is available at all time- Ensure even load sharing between on-line generators- Execute load tripping and / or load reduction when the power plant - Ensure that adequate power for safe manoeuvring is available also i
tripping of non-essential consumers- No changes in available power shall occur if the automatic control sy
occur as an effect of a failure- Control the maximum propulsion motor output.
— Confirm that the control system initiates an alarm to the operator when— Confirm that critical alarms are relayed to navigation bridge and displa
alarms.
— Confirm that monitoring alarms are arranged for:
- High temperature of cooling medium of machines and semi-conduct- High winding temperature of all propulsion generators and motors- Loss of flow of primary and secondary coolants of machines and sem
with a heat exchanger, when this flow is not caused by the propulsiomay be used for this purpose
- Lubricating oil pressure for machines with forced oil lubrication- Leakage of water-air heat exchanger for cooling of machines and se- Earth fault for main propulsion circuits- Earth fault for excitation circuits (This may be omitted in circuits of
less than 500 kW)
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t evident.e of the stator windings of generators and propulsion
n the applicable converter:
generator: A power factor meter or kVAr meter. and power available for propulsion on the bridge and
ck signals, are provided for pitch or direction of
ine control room, even if no control means are
tric propulsion system shall be confirmed during sea l conditions.anagement system, when relevant.
Table F-4 Electrical installations (Continued)
Electric propulsion(continued)
DNVGL-OS-D201Ch.2 Sec.12[1.6](Continued)
— Fuses for filter units or for other components where fuse failures are no— Confirm that a temperature indicator for directly reading the temperatur
motors is located in the control room.— Confirm that the following values are displayed in the control room or o
- Stator current in each motor- Field current in each motor (if applicable).
— Confirm the following values are displayed in the control room for each— Confirm that instruments are provided for indication of consumed power
in the control room.— Confirm at each propulsion control stand, indications, based on feedba
rotation, speed, and azimuth, if applicable.— Confirm indications as listed for control stands, are arranged in the eng
provided.DNVGL-OS-D201Ch.2 Sec.12 [2.1]
— Upon completion as well as satisfactory tests of all subsystems, the electrial where the propulsion plant shall be tested in normal and abnorma
— Confirm that start-up and stop sequences as controlled by the power m— Confirm safety functions, alarms and indicators.— Confirm all control modes from all control locations.— Confirm required level of redundancy by verification through tests.
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F.5 Instrumentation and telecommunication systems
ontrol station.re types:
vers the following:
lt in the least critical of any possible new conditions. etectors are used for each detection area, as fail safe or gas.ts and integration of software modules into the same re and hardware on board include:
ide normal operating parameters
Table F-5 Instrumentation and telecommunication systems
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Failure response DNVGL-OS-D202 Ch.2 Sec.1 [3.2]
— Confirm that detected failures initiate alarms in the assigned manned c— Confirm that failure detection facilities at least cover the following failu
- Power failure- Sensor and actuator failures.
— For computer based systems, confirm that failure detection facilities co
- Communication errors- Computer hardware failures- Software execution failures- Software logical failures.
— Confirm fail-safe functionality to ensure the most probable failures resuSpecial attention shall be paid to arrangement where single fire or gas daction should be taken on instrument failure resulting in confirmed fire
Integration testing DNVGL-OS-D202Ch.2 Sec.1 [5.3]
— Confirm that integration tests include integration of hardware componenhardware. The integration tests to be performed with the actual softwa
- Hardware tests for failures- System software tests for failures- Application software tests- Function tests of normal system operation, as well as operation outs- User interface tests.
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lity of all automation and safety systems and shall
ages, together with establishment of correct tc.)d integration of systems, including the ability of the tolerances and carry out all safety/protective actions
al unit / installation systems. The tests should he available back-up means of operation (as required ormal system is disabled as far as practical.
n, completed with final set points. ests by the Approval centre.all be tested with maximum return flow to verify that revent correct system performance. ed to ensure fail-safe operation, tests shall include
mand locations. Only one location shall be able to be ated when this location is in control.er (also applicable for mode change) does not result
Table F-5 Instrumentation and telecommunication systems (Continued)
On-board testing DNVGL-OS-D202 Ch.2 Sec.1 [5.5]
— On-board testing shall demonstrate, verify and document full functionainclude:
- During installation, the correct function of individual equipment packparameters for automation and safety (time constants, set points, e
- During installation and sea trials, the correct function of systems anautomation and safety systems to keep any EUC within the specified
- The correct distribution, protection and capacity of power supplies- Back-up and emergency automation and safety functions for essenti
demonstrate that the essential installation functions are operable on tin the relevant application standard), and in a situation where the n
— A copy of the approved test programme shall be kept on the installatio— The test program for harbour and sea trials shall be approved prior to t— Hydraulic automation and shutdown systems with on or off regulation sh
return headers are adequately sized and free of blockages that could p— For pneumatic and hydraulic automation systems with accumulators us
verification of accumulator charge level and capacity.DNVGL-OS-D202 Ch.2 Sec.2 [1.3]
— Confirm main propulsion remote controls are independent of other comin control at a time. Confirm on each alternative location that it is indic
— Confirm transfer of propulsion remote control from one location to anothin significant alteration of process equipment parameters.
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ally after being stopped by safety system.
e audible signal may not be heard due to background
al conditions. of colour and special representation.dged by the receiving location. Confirm transfer of ation when this location is in charge.ddition to the external rotating lights. However, the y flashing.rm. However, visual indication will remain in alarm e alarm signal will not prevent initiation of any new
ate or other appropriate means. version identifier. d the identification information is maintained.nits main functions independent of network status.
res and initiates an alarm on dedication workstations.
larms should be generated if malfunctions or reduced
communication
R) measurements for each fibre can be used to
accumulators are hydrostatically tested to 1.5 times
Table F-5 Instrumentation and telecommunication systems (Continued)
On-board testing (continued)
DNVGL-OS-D202Ch.2 Sec.2 [1.4]
— Confirm equipment under control (EUC) does not start again automatic
DNVGL-OS-D202 Ch.2 Sec.2 [1.5]
— Confirm that alarms indicate abnormal conditions only. In areas where thnoise, additional visual and audible display units shall be installed.
— Confirm audible alarms are distinguishable from signals indicating norm— Confirm visual alarms are distinguishable from other indications by use— Confirm responsibility for alarms not to be transferred before acknowle
responsibility gives audible warning and indicates at each individual loc— Confirm that silencing the audible signal causes the signal to cease in a
visual alarm indication on the workstation remains unchanged, normall— Confirm that acknowledgement of the alarm causes silencing of the ala
state on the workstation until the alarm condition ceases. Also, an activalarm with its audible and visual indication.
DNVGL-OS-D202 Ch.2 Sec.3 [2.1]
— Confirm running software versions are uniquely identified by number, d— Confirm software modifications are not made without also changing the— Confirm the record of changes to the system since the original issue an
DNVGL-OS-D202 Ch.2 Sec.3 [3.1]
— Confirm it is possible to maintain emergency operation of the vessel / u
DNVGL-OS-D202Ch.2 Sec.3 [3.2]
— Confirm that the data communication link is self-checking, detects failu
DNVGL-OS-D202 Ch.2 Sec.3 [3.2]
— Confirm that network (traffic) performance is continuously monitored. A/ degraded capacity occurs.
DNVGL-OS-D202 Ch.2 Sec.3 [3.4]
— Confirm the following items in a test related to network functionality:
- The main observations / items from the analysis- Self- diagnostics, alarming upon different network failures- Worst-case scenarios - network storm- Segment segregation - autonomous operation of segments- Individual controller node integrity - nodes working without network- Consequence of single cabinet loss.
DNVGL-OS-D202 Ch.2 Sec.4 [3.7]
— After installation, confirm that Optical Time Domain Reflectometry (OTDcorrect and re-evaluate the power budget calculations.
DNVGL-OS-D202 Ch.2 Sec.4 [4.1]
— Confirm piping and tubing to actuators and between actuators and localthe system design pressure for minimum 15 minutes.
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tion functions and alarm indications related to n of active fire protection devices;am system status, if applicable; gas detection status if applicable; activation of BOP release sequence
ripped by the emergency shutdown (ESD) system.
Table F-5 Instrumentation and telecommunication systems (Continued)
On-board testing (continued)
DNVGL-OS-D202 Ch.2 Sec.6 [4.1]
— Drilling Unit / Production and Storage Unit
- Confirm back-up means of operation contains the most important acemergency relocation (if required), gas detection, including activatio
- This will typically include release of foam systems and indication of foindication (flammable and toxic); facilities for emergency relocation,(normally located in BOP control panel).
DNVGL-OS-D202 Ch.2 Sec.7 [2.1]
— Production and Storage Unit
- Confirm power to the relevant parts of the safety system is not be t
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F.6 Fire protection systems
of gas, smoke and flames up to the end of the two-
its classified as “H” class.
e one-hour standard fire test. its classified as “H” class.
our of the standard fire test. its classified as “H” class.es, control stations, machinery spaces and hazardous outside the space being served. The means provided
zardous areas to be entirely separate from the means
tested without interruption of normal operation.
ne jet simultaneously from each of any two (2) fire pressure of 0.35 N/mm2.
deck, confirm the pump is capable of maintaining a
d remotely at the control station where the operating
automatically activates start-up of fire water pumps.
ntally and vertically in order to permit the monitor to
operated monitor is installed.g in a selected position as well as capable of both jet
Table F-6 Fire protection systems
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Fire divisions DNVGL-OS-D301Ch.2 Sec.1 [3.1]
— “H” class divisions are tested to the following standards:
- They are constructed to be capable of preventing the passage hour standard fire test.
- Confirm that a test of a prototype division is carried out before
— “A” class divisions are tested to the following standards:
- They prevent the passage of smoke and flame to the end of th- Confirm that a test of a prototype division is carried out before
— “B” class divisions are tested to the following standards:
- They prevent the passage of flame to the end of the first half h- Confirm that a test of a prototype division is carried out before
Fire protection DNVGL-OS-D301Ch.2 Sec.1 [2.3]
— Confirm power ventilation of accommodation spaces, service spacareas is possible of being stopped from an easily accessible positionfor stopping the power ventilation serving machinery spaces or haprovided for stopping ventilation of other spaces.
Fire fighting systems DNVGL-OS-D301Ch.2 Sec.3 [2.1]
— Confirm that active fire protection systems and equipment can be
DNVGL-OS-D301Ch.2 Sec.3 [2.2]
— Confirm that each pump has the capability of delivering at least ohydrants, hoses and 19 mm nozzles while maintaining a minimum
— Where a foam system is provided for protection of the helicopter pressure of 0.7 N/mm2 at the foam installation.
DNVGL-OS-D301Ch.2 Sec.3 [3.4]
— Confirm release of the deluge systems to be possible both locally anstatus of the systems is monitored.
DNVGL-OS-D301Ch.2 Sec.3 [2.5]
— Confirm that pressure drop in the sprinkler system is alarmed and
DNVGL-OS-D301Ch.2 Sec.3 [2.7]
— Confirm that the fire water monitor has sufficient movement horizocover the complete area of protection.
— Confirm the local manual override control is possible, if remotely — Confirm the monitor is provided with a locking device for operatin
and spray discharge.
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oint will initiate a visual and audible fire signal at the attention within two (2) minutes, confirm that an modation and service spaces, control stations and
d to the satisfaction of the Administration by means of ke or aerosol particles having the appropriate range of
nt fires to which the detector is designed to respond. sted for correct operation and restored to normal
onitoring principals includes facilities for periodical .e operation and ventilation (activity normally
ntinuously monitors all enclosed areas of the unit in ur.visual alarm in the control center, the presence of an losion limit. central control station. The firewater pumps should as well as upon low pressure in the fire water ring main.pped at the driver. Automatic trip is only accepted for
emergency situation. Over-speed protection shall be d for.r area do not stop the pump or inhibit the start of the
d fire water distribution pipework, provide effective
fire and gas detection system and has a local energy
han the greatest of the following:
il tank deck area means the maximum breadth of the k spacesle tank having the largest such area, or, such area being entirely forward of the monitor, but
e at least 20 minutes of foam generation in tankers tion in tankers not fitted with an inert gas installation
Table F-6 Fire protection systems (Continued)
Fire and gas detection DNVGL-OS-D301Ch.2 Sec.4 [3.5/3.7]
— Confirm that activation of any detector or manually operated call pcontrol panel and indicating units. If the signals have not receivedaudible alarm is automatically sounded throughout the crew accommachinery spaces of category A.
— Confirm that the function of the detection system is periodically testeequipment producing hot air at the appropriate temperature, or smodensity or particle size, or other phenomena associated with incipie
— Confirm that all detectors are of the type such that they can be tesurveillance without the renewal of any component.
DNVGL-OS-D301Ch.2 Sec.4 [3.6]
— Periodically Unattended Machinery Space:
- Confirm that an approved fire detection system based on self-mtesting is installed in periodically unattended machinery spaces
- Confirm fire detection system under varying conditions of enginperformed during sea trial – smoke tests).
DNVGL-OS-D301Ch.2 Sec.4 [4.1]
— Confirm that a fixed automatic gas detection and alarm system cowhich the accumulation of flammable gas may be expected to occ
— Confirm that gas detection system indicates both, by audible and accumulation of gas corresponding to 25% and 60% of lower exp
Fire protection – oil and gas production and storage units
DNVGL-OS-D301Ch.2 Sec.7 [3.1]
— Confirm that the fire pump systems are available at all times at thestart automatically upon fire detection in any area they are serving,
— Confirm that fire pumps are only be capable of being manually stoover-speed protection.
— Confirm that fire pump systems can operate until destruction in anautomatic reset to cater for situations where new start up is calle
— Confirm that fire detection at the fire water pump and / or its drivefire pump driver.
DNVGL-OS-D301Ch.2 Sec.7 [4.1]
— Confirm that fixed fire fighting systems, including deluge valve anfire water protection within 20 seconds of the demand.
— Confirm the deluge valve system is activated by a signal from thesource for the valve actuator.
DNVGL-OS-D301Ch.2 Sec.7 [5.2]
— Confirm that the rate of supply of foam solution shall not be less t
- 0.6 litre / minute / m2 of storage tank deck area, where crude oship multiplied by the total longitudinal extent of the cargo tan
- 6 litre / minute / m2 of the horizontal sectional area of the sing- 3 litre/ minute / m2 of the area protected by the largest monitor
not less than 1250 litre / minute.
— Confirm that sufficient foam concentrate can be supplied to ensurfitted with an inert gas installation, and 30 minutes of foam generawhen using solution rates given above, whichever is greatest.
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central control station. Confirm that firewater pumps g, as well as upon low pressure in the fire water ring
d fire water distribution pipework, provide effective
fire and gas detection system and has a local energy
ssing facilities results in an automatic shut-down of
enclosed spaces or smoke detection in ventilation air
r crude oil tank areas initiates an automatic shutdown
ydrocarbon flow.) in the air results in an automatic shutdown of all air
oduction facilities and storage tanks result in the
mp rooms and double hull spaces on floating automatically initiated in the pump-room, engine ntial hazard.easuring O2-content, two instruments for measuring
y volume and two instruments for measuring low alarms (visual and audible) on the bridge and in the
or measuring low hydrocarbon gas content 0 to 100% e and in the cargo control room are triggered if safe
Table F-6 Fire protection systems (Continued)
Fire protection – LNG import and export terminals and production units
DNVGL-OS-D301Ch.2 Sec.8 [3.1]
— Confirm that the fire pump systems are available at all times at thestart automatically upon fire detection in any area they are servinmain.
DNVGL-OS-D301Ch.2 Sec.8 [4.1]
— Confirm that fixed fire fighting systems, including deluge valve anfire water protection within 20 seconds of the demand.
— Confirm the deluge valve system is activated by a signal from thesource for the valve actuator.
DNVGL-OS-D301Ch.2 Sec.8 [7.1]
— Confirm that fire detection in areas containing gas and LNG procehydrocarbon flow and ventilation for the area.
— Confirm automatic shutdown of ventilation upon detection of fire ininlets.
— Confirm that fire detection in the wellhead, turret, oil production oof wellhead valves and oil production facilities.
DNVGL-OS-D301Ch.2 Sec.8 [8.1]
— Confirm that gas detection results in an automatic shutdown all h— Confirm that a gas concentration of 25% lower explosion limit (LEL
inlets to non-hazardous areas.— Confirm 60% LEL gas detection in the area of wellhead, turret, pr
wellhead valves and production facilities shutdown.DNV Rules for ShipsPt.5 Ch.3 Sec.9F and G
— Confirm that gas detection not higher than 10% LEL in product puinstallations results in an audible and visual alarm signal which is control room and navigation bridge, to alert personnel to the pote
— For ships with inert gas systems, confirm that two instruments for mhydrocarbon content in the range of 0 to 20% hydrocarbon gas bhydrocarbon gas content 0 to 100% LEL are present. Confirm thatcargo control room are triggered if safe levels are exceeded.
— For ships without inert gas system, confirm that two instruments fLEL are provided and that alarms (visual and audible) on the bridglevels are exceeded.
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F.7 Vessel operations
e physical sensor and the whole signal loop, correct
ry six (6) months, unless more frequent testing is instruments shall not exceed 12 months. m is continuously powered and in case of a loss of available power supply will have capacity for 30
udible and optical (flashing light) warning at both g shall remain in operation until acknowledged.e process parameter which is being monitored (ie. s clearly indicated on the operator panel.rom the bridge for over-speed protection, crankcase s.endent from the main alarm system.
ymachinery
chinery, including controllable pitch propeller if arranged
achinery safety system), as well as restart (from h acceptable. to produce a start, is limited to safeguard sufficient w starting air pressure set at a level that still permits
ded machinery spaces shall be confirmed.
ulsion machinery shall be confirmed. Prior to testing,
stem shall be carried out without manual assistance mal for unattended machinery space. approved test programme for fixed or controllable
Table F-7 Vessel operations
System / equipment description
DNV GL OS /rule reference
DNV GL surveillance focus
Periodical test DNV Rules for ShipsPt.6 Ch.3 Sec.1D200
— Confirm that testing of field instruments shall in general include thfunctionality, indication and alarming.
— Confirm that all field instruments for critical alarms are tested evespecified by the manufacturer. The test intervals for all other field
General operations DNV Rules for ShipsPt.6 Ch.3 Sec.2C100
— Confirm that the alarm system including the extension alarm systenormal power supply, an automatic change over to a continuouslyminutes.
DNV Rules for ShipsPt.6 Ch.3 Sec.2 C400
— Confirm that the watch responsibility transfer system initiates an acontrol positions when watch transfer is requested, and the warnin
DNV Rules for ShipsPt.6 Ch.3 Sec.2D200
— Confirm that automatic start of the standby pump is initiated by thLow-pressure signal). When a pump is standby, confirm that this i
Class notation E0 – monitoring systems
DNV Rules for ShipsPt.6 Ch.3 Sec.3A200
— Confirm that a manual activated safety shutdown is not possible fexplosive conditions and short circuit in electrical propulsion plant
— Confirm that the alarm for manual activation of shutdown is indepDNV Rules for ShipsPt.6 Ch.3 Sec.3B100
— E0: Confirm and test individual alarms on the bridge for:
- Automatic shutdown of main boiler- Automatic shutdown and / or slowdown of propulsion machiner- Request for manual shutdown and / or slowdown of propulsion - Power failure bridge alarm system- Failure in the remote control systems with respect to propulsion ma- Failure in the remote control systems with respect to steering- Low starting air pressure for reversible propulsion engines.
— Confirm that the propulsion plant is possible to reset (propulsion mbridge) after blackout. Automatic or manual arrangements are bot
DNV Rules for ShipsPt.6 Ch.3 Sec.3D100
— Confirm the number of consecutive automatic attempts, which failstarting air pressure. Confirm that an alarm is provided indicating lostarting operations of the propulsion machinery.
DNV Rules for ShipsPt.6 Ch.3 Sec.5 A100
— During sea trials, four (4) hours continuous operation with unatten
DNV Rules for ShipsPt.6 Ch.3 Sec.5B100
— During sea trials, testing of the remote control system for the propthe propulsion machinery shall run for at least one (1) hour.
— All tests included in the test programme for the remote control syfrom the engine room and all systems shall be in operation as nor
DNV Rules for ShipsPt.6 Ch.3 Sec.5B200 / B300
— Confirm manoeuvres, start, stop and emergency stop according topitch propeller arrangement during sea trial.
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approved test programme for steam turbine
ed machinery spaces shall be confirmed for both gas est).d test programme should be confirmed for both gas
as dual fuel engines of the high pressure gas injection euvres, start, stop and emergency stop test) may be
g units) is possible without manual surveillance,
-off gas is possible without manual surveillance.stem for auxiliary boilers tests, which include:
etc. generators, vary the boiler load as follows:
imum 15 minutesum 15 minutes
ting one of the greater consumersto a minimum. in parallel, vary the boilers’ load as follows:
ting one of the greater consumers.pproximately 5% of full load and keep that load until
stem for main boilers tests, which include:
ring tests specified in B300. The boiler plant testing ystem for the main turbines.
Table F-7 Vessel operations (Continued)
Class notation E0 – monitoring systems (continued)
DNV Rules for ShipsPt.6 Ch.3 Sec.5B400
— Confirm manoeuvres, start, stop and emergency stop according toarrangement during sea trial.
Ships with gas fuelled machinery
DNV Rules for ShipsPt.6 Ch.3 Sec.5B500
— During sea trials, four (4) hours continuous operation with unattendoperation mode as well as fuel oil mode (resulting in 2 x 4 hours t
— Manoeuvres, start, stop and emergency stop according to approveoperation mode as well as fuel oil mode.
— For LNG carriers with steam propulsion and dual fuel boilers as well type: testing required (four (4) hours continuous operation - manocarried out with boilers fired with fuel oil only.
Other installations for boil-off gas handling
DNV Rules for ShipsPt.6 Ch.3 Sec.5B600
— Confirm that automatic operation of gas combustion units (oxidizinexcept that start and stop may be manually initiated.
— Confirm that automatic operation for re-liquefaction plants for boilDNV Rules for ShipsPt.6 Ch.3 Sec.5C100
— Confirm that parameters are recorded for the automatic control sy
- Steam pressure (primary and secondary system)- Water level in boiler- Automatic actions such as start and/or stop of burners, alarms,
— For an automatic control system for auxiliary boilers serving turbo
- Increase load from minimum to full load during a period of min- Reduce load from full load to minimum during a period of minim- Increase load suddenly to minimum 50% of full load by connec- When stationary conditions are reached, reduce load suddenly
— For an automatic control system for two auxiliary boilers operating
- Increase load suddenly to minimum 30% of full load, by connec— When stationary conditions are reached, reduce load suddenly to a
stationary conditions are reached.DNV Rules for ShipsPt.6 Ch.3 Sec.5C200
— Confirm that parameters are recorded for the automatic control sy
- Steam flow (alternatively position of control valve);- Steam pressure;- Temperature of superheated steam;- Water level in boiler;- Water level in condenser and deaerator;- Fuel oil temperature or viscosity;- Excess of combustion air in exhaust gas.
— Confirm that the boiler load is varied in accordance with manoeuvmay be carried out simultaneously with testing of remote control s
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burner while in operation. fuel oil by shielding the flame detector. air fan. elow safety limit.failures as realistically as practicable.d as per main class test requirement and no major ning (DP) test activity.
test programme.plete automatic system in operation.oved test programme.
Table F-7 Vessel operations (Continued)
Other installations for boil-off gas handling(continued)
DNV Rules for ShipsPt.6 Ch.3 Sec.5C300
— Confirm the flame fault detection system by closing fuel supply to— With burners in operation, confirm the automatic shutoff valve for— With boiler in operation, confirm automatic stop of the combustion— Confirm that fuel oil supply is shut off after reducing water level b— Confirm remaining boiler alarms and safety actions by simulating
Dynamic positioning DNV Rules for ShipsPt.6 Ch.7 Sec.1E100
— Confirm power systems and thruster systems have been completepending issues remaining before commencing any dynamic positio
- Main class test requirements will at least include:- Load test according to main class- Transfer of thruster control- Manual override of thruster control- Emergency stop- Communication systems- Main alarm system as for main class and E0 (if applicable)- Integrated automation systems (if applicable).
DNV Rules for ShipsPt.6 Ch.7 Sec.1E600
— Confirm dynamic positioning (DP) functional test as per approved — Confirm DP duration test for at least eight (8) hours with the com— Confirm DP failure modes and effects analysis (FMEA) as per appr
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APPENDIX G SURVEY SCOPE FOR SPECIFIC CLASS NOTATIONS
tallation of DRILL equipment and systems. It is mainly
ts of offshore drilling facilities which have potential to
approval of complete drilling plant, which includes at
rdance with the Rules. This should be confirmed prior
in accordance with written test procedures accepted
t; however, the Surveyor should “Note” the program
manufacturer, it is important to ensure that bled, installed and integrated in the correct manner. onsiderable.
working conditions.
be paid to fixation and support.ry I equipment. The list should include DVR and PC
Escape way, F and G/ESD needs to be addressed as
n and support of heavy equipment.
G.1 DNV GL survey scope for DRILL
Table G-1 DNV GL survey scope for DRILL
System / equipment description
DNV GL OS /rule reference
DNV GL surveillance focus
Drilling plant – general
DNVGL-OU-0101DNVGL-OS-E101
— This section includes instructions for surveys and tests in connection with insto be used by the PMF and his / hers project task members at the yard.
— DRILL notation covers design fabrication, installation and operational aspeceffect personnel or pollution of the environment.
— DRILL notation requires certification of drilling equipment and systems, andleast the following:
- Drilling arrangement- Piping and instrumentation- Power supply- Equipment interface.
— It is important to ensure that equipment installed onboard is certified in accoto testing of complete systems.
— Testing of systems and equipment specified in the Rules is to be carried outby the Surveyor.
— Such test programs may contain testing that exceeds the Rule requiremenand ensure that the rule requirements are complied with, as a minimum.
— Although most equipment will normally have undergone shop testing at theequipment has not been damaged under transportation and has been assemAlso, time between equipment fabrication and installation onboard can be c
— Functional testing of systems is to be carried out, as far as possible, under— SIT test to be carried out.— In connection with installation of heavy equipment, special attention should— Units with DRILL / DRILL(N) class should have equipment lists for all catego
numbers with name of maker and equipment.— A copy of all the PC’s shall be filed at the local station.— DNV-OS-E101 makes reference to other standards. In particular, A101 and
it’s always a problem on site.— Communication / PA is not addressed.
Drilling structures – derrick
DNVGL-OS-E101Ch.2 Sec.5 [2.1]
— Confirm satisfactory fastening of derrick fixtures, special attention to fixatio
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lve gates and C/K connections. Testing should be
d be used, suitably anchored to the test stump).
d fail-safe valves (using the accumulator system, not
lectrical or computer based BOP control systems.ed or reset.
compare with required volume.pressure, low manifold pilot pressure, low fluid level,
lator nitrogen charging side.
ir.d by completely draining the units and witnessing a
ote panels are powered by 24V DC batteries, which m but allow uninterrupted operation by the batteries.
ure of annular and mud system valves).
Table G-1 DNV GL survey scope for DRILL (Continued)
Drill floor and sub-structures
DNVGL-OS-E101Ch.2 Sec.5[2.3/2.4]
— Check satisfactory sea-fastening arrangement.— Lifting lugs / pad eyes, if covered by Class.
Well control systems –
Blowout preventer stack
DNVGL-OS-E101 Ch.2 Sec.5 [3.2]
DNVGL-OS-E101 Ch.2 Sec.6 [3.2]
— Leak / pressure test to demonstrate function of rams, annular elements, vacarried out at low pressure (2-300 psi) and rated working pressure.(Note: For testing of the pipe rams and annulars, a suitable test tool shoul
— Complete function testing of the BOP including all preventers, connectors anonly the stack-mounted accumulators).
Well control systems –Blowout control system
DNVGL-OS-E101 Ch.2 Sec.5 [3.2]
DNVGL-OS-E101 Ch.2 Sec.6 [3.2]
— Leak / pressure testing of installed hoses and piping.— Operate all BOP functions from main control station and remote locations.— Confirm satisfactory operation from either pod.— Verify independence of the two mutually independent control systems for e— Verify that the system resumes normal operation automatically when start— Check flow rates and response times.— Check actual volumetric capacity of accumulator unit (usable volume) and — Check alarms (visual and audible) for low accumulator pressure, low rig air
autostart / autostop of pumps, and loss of power supply.— Check function in emergency shutdown situations.— Test acoustic panel (if installed).— Check calibration of manometers and thermometers.— Confirm safety valves (or temperature sensitive fuse plugs) on the accumu— Check calibration of pressure gauge flow meters.— Check operation of the regulator for closing pressure in case of loss of rig a— Confirm pre-charge pressure of the accumulators. This can be accomplishe
sudden pressure drop when they are emptied. — Confirm emergency power supply for remote panel operation. Normally, rem
are continuously trickle charged. Confirm that loss of charging will give alarWell control systems –diverter
DNVGL-OS-E101 Ch.2 Sec.5 [3.3]
— Function test dogs on fixed support housing.— Leak test to confirm tightness of seals.— Operate all functions from main and remote panels.— Confirm valve sequence interlock (opening of overboard valve prior to clos
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rking pressure.
n cementing unit), including starting the pump and hip condition. (HP) piping and flexible hoses.
of pipes;
of pipes;
of pipes;
ses.
iliary machinery.e).
Table G-1 DNV GL survey scope for DRILL (Continued)
Well control systems – choke and kill system
DNVGL-OS-E101Ch.2 Sec.5 [3.4]
— Valve seat sealing test at low pressure (approx. 200-300 psi) and rated wo— Confirm operation of manual and remote chokes.— Confirm that manifold gauges and driller’s gauges correctly calibrated. — Function test of the Emergency Circulation Pump (normally the diesel drive
the alignment / operation of necessary valves under a (simulated) Black-S— Pressure testing to maximum working pressure, including all high pressure— Confirm calibration of manometers and thermometers.
Marine riser system –workover riser system
DNVGL-OS-E101Ch.2 Sec.5 [3.5]
DNVGL-OS-E101Ch.2 Sec.6 [3]
— Riser joints:
- Visual inspection to confirm no damage to sealing surfaces or distortion - Pressure test to max working pressure (of choke, kill and booster lines).
— Telescopic joint:
- Visual inspection to confirm no damage to sealing surfaces or distortion - Pressure test to confirm sealing at gooseneck connections.
— Flex joint:
- Visual inspection to confirm no damage to sealing surfaces or distortion - Pressure test to confirm sealing.
— Riser wellhead connector:
- Function testing of mechanisms for lock, unlock and disconnect; - Leak / pressure testing of control hoses.
Heave compensating system
DNVGL-OS-E101Ch.2 Sec.5 [4.2]
— Pressure testing to max working pressure of installed piping and flexible ho— Confirm full extension of hydraulic cylinders.— Confirm safety valve setting.— Confirm operation and safety features of any dedicated compressors or aux— Confirm operation of main valve control and indicators (weight and pressur— Confirm operation of isolation valve control and indicators.— Confirm alignment and spacing of crown block guide wheels.— Confirm operation of crown position indicator.
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iliary machinery.
ies).
ors or hydraulic PSVs).
Table G-1 DNV GL survey scope for DRILL (Continued)
Riser tensioning system
DNVGL-OS-E101Ch.2 Sec.5 [4.3]
— Pressure testing of installed piping and flexible hoses.— Stroking of tensioners to confirm free movement.— At full stroke, apply full system air pressure and check for leaks.— Confirm safety valve setting.— Alignment and free movement of sheaves to be confirmed.— Retractable sheaves to be load tested at full extension. — Operation of hydraulic and pneumatic systems to be confirmed.— Check clamping of wires to be carried out satisfactorily.— Confirm operation and safety features of any dedicated compressors or aux— Verify proper functioning of slingshot valves.— Perform a function test on the tripsaver trolley over the full track length.— Perform a load test on the tripsaver trolley.— Confirm operation of limit switches, bumper stops, and parking bolts.
Hoisting equipment
DNVGL-OS-E101Ch.2 Sec.5[5.1/5.2]
— Confirm satisfactory fastening of derrick fixtures.— Confirm satisfactory functioning of guide dollies (especially retractable doll— Check calibration of deadline, load cell, etc.— Confirm correct torque of deadline clamp bolts.— Confirm operation of draw works main and auxiliary brakes.— Confirm operation of crown saver device.— Load test air winches to confirm correct installation and anchoring.— Confirm calibration and sealing of load limiting valves (air pressure regulat
Rotating equipment
DNVGL-OS-E101Ch.2 Sec.5[5.1/5.3]
— Confirm operation of rotary table safety features (e.g. purge).— Confirm calibration of driller’s console torque and RPM.
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se.
luffed at slow speed through the entire operating
ating radius, shall generally be performed with the .
se.lection.ll be traversed and travelled over the full length of
s or hydraulic PSVs).
Table G-1 DNV GL survey scope for DRILL (Continued)
BOP and pipe handling equipment
DNVGL-OS-E101Ch.2 Sec.5 [6.1]
— All lifting appliances shall be tested in “as installed” condition prior to first u— Load test as applicable.— Load test of pipe handling crane. The test load shall be hoisted, slewed and
range. — Function testing of all safety features.— Check operation of parking bolts, limit switches, and bumper stops.— Confirm hoisting and traversing over full track length.— Tests for lifting appliances where safe working load (SWL) varies with oper
appropriate test load at maximum, minimum and at an intermediate radius— Function test upper racking arm in all positions.— Test operation of spears.— Function test intermediate racking arm.— Confirm operation of standby cylinder under load.— Confirm operation of drill floor manipulator arm.— Confirm operation and safety features of hydraulic power unit.— Perform functional test of fingerboard.
BOP overhead crane
DNVGL-OS-E101Ch.2 Sec.5 [6.1]
— All lifting appliances shall be tested in “as installed” condition prior to first u— Load test of main and auxiliary hoists. Check main girder for excessive def— Gantry and travelling cranes together with their trolleys, as applicable, sha
their track.— Check hose reel operation.— Pressure test installed high pressure (HP) piping.— Check operation of parking bolts, limit switches, and bumper stops.— Check calibration and sealing of load limiting valves (air pressure regulator
BOP bulkhead guide
DNVGL-OS-E101Ch.2 Sec.5 [6.1]
— Check traversing operation.— Check hose reel operation.— Check gripper function.— Check parking bolt function.— Check operation of hydraulic cylinders.— Check parking bolt arrangement.— Check unobstructed travel of frames.
BOP baseplate trolley
DNVGL-OS-E101Ch.2 Sec.5 [6.1]
— Perform load test, especially in cantilevered position.— Confirm travel from storage position to cantilevered position.— Confirm operation of hose reels.— Confirm operation of parking bolt arrangement.
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).
e of the tanks safety valves / rupture discs.ble hoses.
seal to be confirmed at low pressure (2-300 psi) and
x WP, of Kelly Cocks, IBOP, and valves in drill string.m. hoses.firmed at low pressure (2-300 psi) and rated working
perature, high cooling water temperature, and low
e diesel engine is to be reviewed to ensure that the be paid to non-return valves, if fitted between start the safety functions on the engine are to be tested. nd the overspeed trips.
Table G-1 DNV GL survey scope for DRILL (Continued)
BOP carrier and skid
DNVGL-OS-E101Ch.2 Sec.5 [6.1]
— Function test BOP carrier or skid with BOP installed over full track length.— Confirm function of sea fastening equipment.— Confirm operation of hose reels.— Confirm operation of limit switches, bumper stops, parking bolts.
Bulk storage, mud and cementing system –
Bulk storage
DNVGL-OS-E101Ch.2 Sec.5[7.1/7.2]
— Pressure test to max working pressure (WP) of installed piping.— Pressure test pressure vessels to max WP.— Confirm operation and safety features of any dedicated compressors.— Confirm bulk transfer routes operate satisfactorily (may use air as medium— Confirm operation of remote control valves and control panels.— Confirm safety valve setting.— Confirm operation of instrumentation (level alarms).— Confirm possibility to purge vent lines to prevent clogging on discharge sid
Bulk storage, mud and cementing system –
Mud system
DNVGL-OS-E101Ch.2 Sec.5[7.1/7.3]
— Pressure testing to max working pressure (WP) of installed piping and flexi— Pressure test pressure vessels to max WP.— Pressure testing of standpipe manifold and mud system valves. Valve seat
rated working pressure.— Calibration of mud standpipe gauges and driller’s gauges to be confirmed.— Perform pressure test of rotary hose and swivel.— Confirm mud pump safety valve setting.— Confirm system for monitoring mud return flow rate.— Function test and pressure test, both low pressure (LP, 200-300psi) and ma
Bulk storage, mud and cementing system –
Cementing system
DNVGL-OS-E101Ch.2 Sec.5[7.1/7.4]
— If the cement unit is the emergency pump, confirm crossover to mud syste— Pressure test to max working pressure (WP) of installed piping and flexible— Pressure test cement manifold and system valves. Valve seat seal to be con
pressure.— Confirm pressure safety valve settings.— Confirm calibration of manifold gauges and driller’s gauges.— Safety functions of diesel engine to be tested (overspeed, high exhaust tem
lube oil pressure).— If the cement pump is the emergency kill pump, the starting system for th
engines can start without use of the rig’s air system. Special attention is toair bottles and rig air systems. For diesel engines located in zone 2 areas, Typically, these are lube oil low pressure, cooling water high temperature a
— Confirm insulation of the exhaust gas manifold.
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hoses.
roceeds to (i.e. burner boom or open air).
system. er booms and rig side, and fire monitors.
quired weight of burner and spreader.se.
entire operating range, as applicable, for the lifting
t 2 ´ safe working load (SWL).
L.
or over open sea).
riding winch drum at the lowest possible operating
h safe working load (SWL).ns).
Table G-1 DNV GL survey scope for DRILL (Continued)
Well testing and associated well control system
DNVGL-OS-E101 Ch.2 Sec.5 [8.2]
— Pressure test to max working pressure (WP) of installed piping and flexible— Pressure test pressure vessels to max WP.— Confirm settings of safety valves and where the discharge from the valve p— Confirm safety features (e.g. level controls, fire and gas detection).— Complete a full functional testing of the associated safety systems and ESD— Perform a function test of the fixed deluge system, cooling system on burn— Verify drainage system in well test area.— Confirm calibration of manifold gauges and control room gauges.— Confirm operation and safety features of any dedicated compressors.— The burner boom shall be tested with an overload of 25% related to the re
Man riding equipment
DNVGL-OS-E101Ch.2 Sec.5[9.1 to 9.5]
— All lifting appliances shall be tested in “as installed” condition prior to first u— The test load shall be hoisted, slewed and luffed at slow speed through the
appliance in question.— Perform static brake capacity test for all brakes operating simultaneously a— Perform static brake capacity test for each individual brake at 1.8 ´ SWL.— Perform dynamic brake capacity test for each individual brake at 1.25 ´ SW— Confirm operation of two independent locking devices.— Confirm emergency stop function. — Confirm that system is reset to function after an emergency stop.— Confirm that slack wire detection is functioning.— Confirm that load limiting devices and limit switches are functioning.— Confirm override possibilities between local and remote controls.— Confirm functioning of emergency hoisting system (if operating under deck— Confirm emergency lowering and hoisting functionality.— Confirm that at least three (3) turns of wire rope is remaining on the man
position.Other systems –
Winches
DNVGL-OS-E101Ch.2 Sec.5 [6.1]
— Perform load test.— Function test skid or carrier with overload over full track length.— Confirm operation of limit switches, bumper stops, parking bolts.
DNVGL-OS-E101Ch.2 Sec.5 [10.1]
— Perform load test.— Confirm that winches are shielded for personnel protection and marked wit— Confirm correct function of operating handle or equivalent (e.g. push butto— Confirm functionality of automatic brake.— Confirm emergency lowering function of the lifting device.— Confirm load limit device and pressure safety valve setting.
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integrity, these valves shall be capable of being t the remote control station., and pneumatic) shall not cause:
cooling water system for propulsion and power
y the manufacturer at a pressure equal to 1.5 times king pressure at room temperature). The following
l pressure;re shall not be less than five (5) bar;
also be hydrostatically tested at a pressure equal to
cally tested in accordance with the following:
pipes, compressed air pipes and feed pipes of class
ot exceed working pressure by more than 70 bar.g pressure, minimum six (6) bar, minimum duration
ionally tested under working conditions.l room / station - positive remote confirmation of the
e to each spool and weld joint. This recording should stress relief, hardness testing (for sour service),
ct schedules and rating.ol drawing of latest revision.
be checked.crack in tag weld, bevel configuration and cleanliness.tings and piping with poor weldability and heavy
ween fusion lines at the surface of the welds, should , the weld distance should be sufficient to avoid high
rough steel bulkheads. No welding is to be performed
s are to be given expansion possibilities. For such
Table G-1 DNV GL survey scope for DRILL (Continued)
High pressure piping –
All piping systems
DNVGL-OS-D101Ch.2 Sec.2 [5.2]
DNVGL-OS-D101Ch.2 Sec.6[6.1, 6.2 and 7.1]
— Where valves are provided at watertight boundaries to maintain watertightoperated from a control room. Valve position indicators shall be provided a
— For remotely controlled valves, failure in power supply (electrical, hydraulic
- Opening of closed valves, closing of open valves on fuel oil tanks and ingenerating machinery.
— Hydrostatic testing - all valve bodies shall be subject to a hydrostatic test bthe nominal pressure (the nominal pressure is the maximum allowable worregulations are required:
- The test pressure need not be more than 70 bar in excess of the nomina- For valves fitted on unit or installation’s side and bottom, the test pressu- For butterfly valves fitted on unit or installation’s side and bottom, shall
five (5) bar applied independently on each side of the closed disc.— Hydrostatic testing after assembly onboard - The piping shall be hydrostati
- Fuel oil piping, heating coils in tanks, bilge, ballast and fire pipes, steamIII - 1.5 maximum working pressure, minimum four (4) bar.
- Hydraulic piping - 1.5 maximum working pressure. Test pressure need n- Piping systems made from non-metallic material - 1.5 maximum workin
one (1) hour.— All piping systems shall be properly flushed, checked for leakage and funct— Function testing of closure devices i.w.o. watertight boundaries from contro
same.High pressure piping –
General
DNVGL-OS-E101Ch.2 Sec.3[2.1 to 2.5]
— Monitor the yard’s system to document the fabrication process with referenccontain material verification status, fit-up, edge penetration, WPS number,pressure testing, NDE and final inspection.
— All piping including fittings, flanges, valves, etc., shall be checked for corre— Dimensions of all prefabricated pipework are to be checked against the spo— Confirm that flanges are square to pipework. The flange face flatness shall— The fit-up shall be checked with particular attention to alignment, root gap, — Special attention should be paid to systems which may be assembled of fit
thickness.— The distance between two buttwelds, defined as the minimum distance bet
not be less than ten times the wall thickness, minimum 50 mm. In additionpreheating temperatures (100°C) on completed welds.
— Special attention should also be paid to penetration of high pressure pipes thin high pressure pipes.
— In areas where the temperatures are fluctuating (e.g. on deck), pipe lengthpipes, the flexibility of support is important.
— Pressure testing is to be witnessed.
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ements.f all automation and safety systems and shall include:
s, together with establishment of correct parameters
egration of systems, including the ability of the UC) within the specified tolerances and carry out all
it/installation systems. The tests should demonstrate k-up means of operation (as required in the relevant abled as far as practical. A copy of the approved test ints. by the Approval centre.ll be tested with maximum return flow to verify that vent correct system performance. o ensure fail safe operation, tests shall include
Table G-1 DNV GL survey scope for DRILL (Continued)
Electrical systems and components
DNVGL-OS-E101Ch.2 Sec.4 [2.1]
See section on Electrical Installations for requirements.
Instrumentation, control and monitoring systems
DNVGL-OS-E101Ch.2 Sec.4 [3.1]
— See section on Instrumentation and Telecommunication systems for requir— On-board testing shall demonstrate, verify and document full functionality o
- During installation, the correct function of individual equipment packagefor automation and safety (time constants, set points, etc.);
- During installation and sea trials, the correct function of systems and intautomation and safety systems to keep any equipment under control (Esafety / protective actions;
- The correct distribution, protection and capacity of power supplies;- Back-up and emergency automation and safety functions for essential un
that the essential installation functions are operable on the available bacapplication standard), and in a situation where the normal system is disprogramme shall be kept on the installation, completed with final set po
— The test program for harbour and sea trials shall be approved prior to tests— Hydraulic automation and shut-down systems with on or off regulation sha
return headers are adequately sized and free of blockages which could pre— For pneumatic and hydraulic automation systems with accumulators used t
verification of accumulator charge level and capacity.
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G.2 DNV GL survey scope for PROD
stallation of process topsides (PROD) equipment and mbers at the yard/site.
s of offshore production facilities which have potential environment. and approval of complete production plant, which
and clear to all parties, as applicable, these may be:
r loading buoy
een regasification plant and export line.
Table G-2 DNV GL survey scope for PROD
System / equipment description
DNV GL OS /rule reference
DNV GL surveillance focus
Oil and gas processing plant – general
DNVGL-OU-0102DNVGL-OS-E201
— This section includes instructions for surveys and tests in connection with insystems. It is mainly to be used by the PMF and his / hers project team me
— PROD notation covers design fabrication, installation and operational aspectto effect the safety of personnel, the safety of the vessel or pollution of the
— PROD notation requires certification of production equipment and systems,includes, as applicable, the following:
- production and export riser systems- well control system- riser compensating and tensioning system- hydrocarbon processing system- relief and flare system- production plant safety systems- production plant utility systems- water injection system- gas injection system- storage system- LNG Liquefaction system- crude offloading system- LNG regasification system- LNG transfer system.
— It is essential that the main boundaries of the production plant are known
- riser shutdown valve- control system connection to sea floor system- connection to production buoy- shutdown valve at crude outlet from production plant to crude storage o- shutdown valve between liquefaction plant and LNG storage tanks- shutdown valve between LNG storage and regasification plant, and betw
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rdance with the Rules. This should be confirmed prior
accordance with written test procedures accepted by
t; however, the Surveyor should “Note” the program
manufacturer, it is important to ensure that bled, installed and integrated in the correct manner. onsiderable, preservation and calibration issues may
working conditions.
be paid to fixation and support.ent. The list should include DVR and PC numbers with
European Directive requirements for equipment will 7/23/EC), Potentially Explosive Atmospheres (ATEX)
1 and Escape routes, F and G/ESD requirements to be
ort stools and secondary structures.
gs, marking etc.)
gs, marking etc.)
Table G-2 DNV GL survey scope for PROD (Continued)
Oil and gas processing plant – general (continued)
DNVGL-OU-0102DNVGL-OS-E201(Continued)
— It is important to ensure that equipment installed onboard is certified in accoto testing of complete systems.
— Testing of systems and equipment specified in the Rules is to be carried out inthe Surveyor.
— Such test programs may contain testing that exceeds the Rule requiremenand ensure that the rule requirements are complied with, as a minimum.
— Although most equipment will normally have undergone shop testing at theequipment has not been damaged under transportation and has been assemSince time between equipment fabrication and installation onboard may be cbe present.
— Functional testing of systems is to be carried out, as far as possible, under— SIT test to be carried out.— In connection with installation of heavy equipment, special attention should— Units with PROD class should have equipment lists for all category I equipm
name of maker and equipment.— A copy of all the Product Certificate’s shall be filed at the local station.— For European situated units, and/or where DNV act’s as the Notified Body,
also apply for the topsides only. E.g Pressure Equipment (PED) Directive (9Directive 94/9/EC
— DNV-OS-E201 makes reference to other standards. In particular, DNV-OS-A10addressed.
Main production structures – process modulesControl roomsOther topside packages i.e.Metering packageDeck boilersPower generationEtc.
DNVGL-OS-E201Ch.2 Sec.8 [3.1]
— Confirm satisfactory fastening of module structures and equipment to supp— Lifting lugs / pad eyes, if covered by Class.— Confirm required structural PFP installed as per design requirements— Rotating equipment mounts to be verified for acceptable vibration.— Coatings verified to design— Escape route arrangements to be verified. (Include lighting, surface coatin
Other secondary and tertiary structures
DNVGL-OS-E201Ch.2 Sec.8 [3.1]
— Confirm satisfactory integration and fastening arrangement.— Escape route arrangements to be verified. (Include lighting, surface coatin— Coatings verified to design
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is provided as per design.
g to maximum working pressure.)
e is within code requirements.
otection.ally benign.
ctionality shall be tested.
is provided as per design.
nnection occurs.e.g.
permissible design limits.design.
components and instrumentation have been installed
osure. Verify correct valves close upon initiation from wing valve)
pressure to wellhead panel. pressure, low manifold pilot pressure, low fluid level,
Table G-2 DNV GL survey scope for PROD (Continued)
Wellhead control systems –
Surface controlled subsea safety valves and risers
DNVGL-OS-E201 Ch.2 Sec.1 [3.5]
DNVGL-OS-E201 Ch.2 Sec.4A100
— Ensure all mechanical and accidental impact protection for the riser system— Confirm required PFP installed as per design requirements— Leak / pressure testing of installed risers, hoses and piping. Pressure testin— Leak testing of SCSSV to be verified with code allowable limits (APR RP 14F— Function test SCSSSV to confirm limit switches operate and time for closur— Confirm correct valve position indication is provided— Confirm hydraulic oil cleanliness following installation and flushing.— Confirm hydraulic oil return is provided with hydrocarbon contamination pr— If hydraulic oil is drained to sea on closure, confirm oil type is environment— Confirm acoustic or other initiation system (if installed)
Wellhead control systems –
Riser tensioning and disconnection systems
DNVGL-OS-E201 Ch.2 Sec.1 [3.5]
DNVGL-OS-E201 Ch.2 Sec.4 [1.3]
— Where emergency disconnection of flexible risers is provided, important fun— Confirm ability to test without actual disconnection.— Ensure all mechanical and accidental impact protection for the riser system— Confirm required PFP installed as per design requirements— Disconnection to be tested from main control room and locally.— Disconnection shut off valve sequence to be verified before simulated disco— Critical components and functions of riser tensioning system to be verified
— Confirm alarms (visual and audible) for riser system excursions outsideWellhead control systems –
Surface production tree and wellhead control
DNVGL-OS-E201 Ch.2 Sec.1 [3.5]
DNVGL-OS-E201 Ch.2 Sec.4 [1.1]
— Confirm all mechanical and accidental impact protection is provided as per — Confirm required PFP installed as per design requirements— Leak / pressure test to demonstrate function wing and master valves. — Complete function testing of the Surface Production Tree to ensure all piping
in accordance with P&ID’s and all relevant set points are correct. — Confirm wellhead control panel functionality.— Confirm hydraulic oil type, cleanliness, levels in wellhead control panel.— Confirm sequence and independence of production tree and subsea valve cl
the ESD system depending on ESD level. (i.e. low level ESD may only close— Confirm complete isolation of wells within performance criteria.— Confirm controlled shutdown of wellhead valves on loss or reduced supply — Confirm alarms (visual and audible) for low accumulator pressure, low rig air
autostart / autostop of pumps, and loss of power supply, as applicable.
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issioning tests therefore it is important to consider ning tests to verify.ectly supported; flange management processes ompleted.
ts and instrumentation have been installed in
lemented in accordance with P&ID’s.rded in accordance with procedure.n is installed in accordance with P&ID’s.
Table G-2 DNV GL survey scope for PROD (Continued)
Turret system andswivel stack
— Confirm swivel barrier protection system— Turret bearing lubrication system— Turret bearing maintenance arrangements.— Slip ring commissioning test in accordance manufacturer requirements.— Confirm monitoring and control arrangements.— Configuration of the turret could have significant bearing on extent of comm
the manufacturers test programme carefully to evaluate level of commissioProduction separation system
— Confirm module integration piping is complete, installed as per P&IDs, corrsatisfactorily completed and leak testing of complete integrated system is c
— Confirm dropped object protection (or procedural controls) are in place.— Complete function testing of the PSD system to ensure all piping componen
accordance with P&ID’s and all relevant set points are correct. — Confirm valve ‘locked open’, ‘locked closed’ requirements are correctly imp— Confirm inhibits and non-standard system configurations are correctly reco— Confirm necessary heat tracing, heat conservation and personnel protectio
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ectly supported, flange management processes ompleted.n/cold vent piping (including sizing and approximate
ts and instrumentation have been installed in
emented in accordance with P&ID’s. (Particular focus
rded in accordance with procedure.n is installed in accordance with P&ID’s.
iod, in the correct valve sequence. (Ideally a full live nduct this test following startup with the plant finally by the control system of a blowdown event at some
ting media is lost (including pressure in local energy ally energized.
location as per drawings particularly hazardous area
to flow (other than properly sized orifaces) and that
out
Table G-2 DNV GL survey scope for PROD (Continued)
Relief, blowdown and depressurising systems
DNVGL-OS-E201 Ch.2 Sec.3
— Confirm module integration piping is complete, installed as per P&IDs, corrsatisfactorily completed and leak testing of complete integrated system is c
— Confirm that the blowdown valves, blowdown restriction orifice and blowdowrouting) has been installed in accordance with the design.
— Complete function testing of the PSD system to ensure all piping componenaccordance with P&ID’s and all relevant set points are correct.
— Confirm valve ‘locked open’, ‘locked closed’ requirements are correctly implaround relief and blowdown valves)
— Confirm inhibits and non-standard system configurations are correctly reco— Confirm necessary heat tracing, heat conservation and personnel protectio— Confirm dropped object protection (or procedural controls) are in place.— Confirm by tests that blowdown valves operate within the desired time per
system blowdown test is be conducted however it may be undesirable to coin a steady state so an alternative would be to review real time data loggedtime after startup.
— Confirm that blowdown valves open when pressure in their respective actuastorage devices if provided) or loss of signal from the ESD system, i.e norm
— Confirm relief valve interlocking arrangement or procedures.— Confirm and test knock out drum set points.— If not routed to the flare system, confirm other relief devices route to safe
drawings as applicable.— Confirm cold vents are provided with weather protection.— Confirm cold vents provided with local fire system, and tested.— Confirm relief and blowdown piping is self-draining, there are no restriction
drain points are provided at unavoidable low points.— Confirm flare pilot is supplied from two sources of pilot gas.— Confirm redundant ignition system operates effectively i.e. simulate flame — Confirm purging/snuffing arrangements are available and proceduralised.— Confirm heat radiation is within acceptable levels, post startup.
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ectly supported, flange management processes ompleted.
n is installed in accordance with P&ID’s.
ts and instrumentation have been installed in
emented in accordance with P&ID’s. (Particular focus
rded in accordance with procedure.
ectly supported, flange management processes ompleted.nnel protection is installed in accordance with P&ID’s.
ts and instrumentation have been installed in
emented in accordance with P&ID’s. (Particular focus
rded in accordance with procedure.nnel protection is installed in accordance with P&ID’s.
ead
e dampers closing and fire extinguishing
tested, flushed/cleaned that all exterior surfaces are
ms.
issioning trial.ing testing. Checks to be done at all different load rements.
Table G-2 DNV GL survey scope for PROD (Continued)
Gas treatment and compression systems
DNVGL-OS-E201 Ch.2 Sec.2 [3.1]
— Confirm module integration piping is complete, installed as per P&IDs, corrsatisfactorily completed and leak testing of complete integrated system is c
— Confirm necessary heat tracing, heat conservation and personnel protectio— Confirm dropped object protection (or procedural controls) are in place.— Complete function testing of the PSD system to ensure all piping componen
accordance with P&ID’s and all relevant set points are correct. — Confirm valve ‘locked open’, ‘locked closed’ requirements are correctly impl
around relief and blowdown valves)— Confirm inhibits and non-standard system configurations are correctly reco— Off specification fuel gas trips to be confirmed.
Water and gas injection
DNVGL-OS-E201 Ch.2 Sec.2 [4.1]
— Confirm module integration piping is complete, installed as per P&IDs, corrsatisfactorily completed and leak testing of complete integrated system is c
— Confirm necessary winterisation, heat tracing, heat conservation and perso— Confirm dropped object protection (or procedural controls) are in place.— Complete function testing of the PSD system to ensure all piping componen
accordance with P&ID’s and all relevant set points are correct. — Confirm valve ‘locked open’, ‘locked closed’ requirements are correctly impl
around relief and blowdown valves)— Confirm inhibits and non-standard system configurations are correctly reco— Confirm necessary winterisation, heat tracing, heat conservation and perso— Confirm dropped object protection (or procedural controls) are in place.— Confirm correct installation of non-return valves at injection points to wellh— Test injection point ESD valve.
Packaged rotating equipment i.e. compressors, water injection pumps, turbines
— Confirm location of manual release buttons— Confirm location, numbers and type of fire detectors— Confirm correct functioning of interlocks on doors, if applicable— Confirm the sequencing of fire detection, rotating equipment shutdown, fir— Confirm air tightness, differential pressure of enclosure— Verify site connected piping, i.e. fuel, lube oil to be correctly installed, hydro
below 220°C at steady state. — Verify critical unit control panel trips and intertrips to ICSS/PSD/ESD syste— Ensure manufacturer approved test programme followed.— The vibrations in the entire speed range to be confirmed as insignificant.— Check for leakage of lube oil and fuel oil before, during and after the comm— Check that all ancillaries and piping are visually inspected for vibration dur
conditions to detect resonance problems and identify an new support requi— Refer to appendix F.4 Electrical Installations for generators and turbines
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cification recycle arrangement operational.
al.ectly supported, flange management processes ompleted.ts and instrumentation have been installed in
emented in accordance with P&ID’s. (Particular focus
rectly recorded in accordance with procedure.nnel protection is installed in accordance with P&ID’s.
the process stream.
methanol resistant foam
Table G-2 DNV GL survey scope for PROD (Continued)
Water treament and disposal
DNVGL-OS-E201 Ch.2 Sec.2
— Confirm oil in water analyser is installed, calibrated and functional. Off spe— Confirm overboard dump arrangement, i.e. hazardous area.
Heating and cooling systems
DNVGL-OS-E201 Ch.2 Sec.2 [5.1]
— Confirm hydrocarbon leakage detection systems are installed and operation— Confirm module integration piping is complete, installed as per P&IDs, corr
satisfactorily completed and leak testing of complete integrated system is c— Complete function testing of the PSD system to ensure all piping componen
accordance with P&ID’s and all relevant set points are correct. — Confirm valve ‘locked open’, ‘locked closed’ requirements are correctly impl
around relief and blowdown valves)— Confirm inhibits, overrides and non-standard system configurations are cor— Confirm necessary winterisation, heat tracing, heat conservation and perso— Confirm dropped object protection (or procedural controls) are in place.
Chemical injection systems
DNVGL-OS-E201 Ch.2 Sec.2 [6.1]
— Confirm injection devices (quills) are installed correctly i.e. correct part of — Confirm non-return valves are installed.— For wellhead injection, automatic shutdowns valves to be tested.— Confirm chemical storage area is correctly bunded.— Confirm safety shower and eyewash arrangements.— Confirm any additional fire fighting requirements for specific chemicals i.e.
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ld occur i.e.
uments
to allow for vessel motions. Confirm liquid seal quid level checked.r each module (probably during deluge test).
stems.er protection, flame arrestors, dip pipes.ectly supported, flange management processes ompleted.ts and instrumentation have been installed in
emented in accordance with P&ID’s. (Particular focus
rectly recorded in accordance with procedure.nnel protection is installed in accordance with P&ID’s.
Table G-2 DNV GL survey scope for PROD (Continued)
Drainage systems
DNVGL-OS-E201 Ch.2 Sec.2 [7.1]
— To be installed under process equipment where spillage or minor leaks cou
— atmospheric tanks and pressure vessels with multiple flanges and instr— pumps— heat exchangers— rotating machinery— sample points— offloading system— pig receivers and launchers, etc.
— Confirm drip trays drain point installed on opposite corners of the drip trayarrangement (or other method to prevent gas migration) is installed and li
— Confirm open deck drainage system is correctly installed and operational fo— Confirm segregation between hazardous and non-hazardous open drain sy— Confirm drain tank vent arrangements i.e. safe location, blanketing, weath— Confirm module integration piping is complete, installed as per P&IDs, corr
satisfactorily completed and leak testing of complete integrated system is c— Complete function testing of the PSD system to ensure all piping componen
accordance with P&ID’s and all relevant set points are correct. — Confirm valve ‘locked open’, ‘locked closed’ requirements are correctly impl
around relief and blowdown valves)— Confirm inhibits, overrides and non-standard system configurations are cor— Confirm necessary winterisation, heat tracing, heat conservation and perso— Confirm dropped object protection (or procedural controls) are in place.
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ccommodation and associated access ways and air
llers or other system is not possible.ignal from shuttle tanker arrangements, hawser as applicable.
times are correctly implemented.components and instrumentation have been installed
rectly recorded in accordance with procedure.nnel protection is installed in accordance with P&ID’s.mentation and bleed arrangements to prevent
location.per closure times, fan trips.
ked.
tilation arrangements
ed (EX certification)
Table G-2 DNV GL survey scope for PROD (Continued)
Export system DNVGl-OS-E201 Ch.2 Sec.4 [3.1]
DNVGL-OS-E201 Ch.2 Sec.12
— Confirm offloading arrangement is located the required distance from the aintakes.
— Confirm floating hoses and hawser are arranged such that foaling of prope— Confirm external offloading shutdown arrangements, i.e. telemetry/radio s
tension monitoring, relative positioning monitoring, and receiving terminal,— Confirm hose real locking mechanism.— Confirm hose draining procedures.— Confirm offloading shutdown via ESD from pushbuttons and CCR.— Confirm offloading control station operation.— Confirm offload/export pump protection systems, set points and response — Complete function testing of the offload/export system to ensure all piping
in accordance with P&ID’s and all relevant set points are correct. — Confirm normal, automatic and manual emergency release mechanisms.— Minimum flow recycle and non-return valve arrangements to be verified.— Confirm inhibits, overrides and non-standard system configurations are cor— Confirm necessary winterisation, heat tracing, heat conservation and perso— Confirm arrangement for pig launchers and receivers, i.e. interlocks, instru
inadvertent opening while pressurised.Ventilation arrangements – external rooms
DNVGL-OS-D101 Ch.2 Sec.4 [11.1]
— Confirm overpressure ventilation arrangement including alarms at manned— Confirm air intake fire and gas detection arrangements and related fire dam— Confirm gas tight door self-closing mechanisms. Escape hatches to be chec— Confirm electrical conduits are suitably sealed.— Confirm air intakes are located 3m outside hazardous areas.
Electrical systems and components
DNVGL-OS-D201DNVGL-OS-A101
— See section on Electrical installations for requirements.— Confirm hazardous area drawing accurately reflect release sources and ven— Confirm that equipment and structures are suitable earthed.— Confirm the electrical equipment suitable for hazardous area is suitable rat
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drawings.ses with an oxygen content of
xygen deficient atmosphere in the cargo tanks under volume. Confirm acceptable dilution in cargo tanks.
ck seal. ses with an oxygen content of
ctioning and integrated where appropriate with ICSS/
ration to be provided and used to verify
ements.f all automation and safety systems and shall include:
s, together with establishment of correct parameters
egration of systems, including the ability of the UC) within the specified tolerances and carry out all
it/installation systems. The tests should demonstrate k-up means of operation (as required in the relevant abled as far as practical. A copy of the approved test ints.ll be tested with maximum return flow to verify that vent correct system performance. o ensure fail safe operation, tests shall include
ported.
rectly supported; flange management processes and grated system is completed.
Table G-2 DNV GL survey scope for PROD (Continued)
Inert gas system DNV Rules for Ships Pt.5 Ch.3 Sec.11
— Confirm installation of inert gas piping system in accordance with approved— Confirm the inert gas system is capable of supplying a gas or mixture of ga— not more than 5% at the correct flowrate, temperature and pressure.— Confirm that the cargo tank blanketing system (IG system) maintains an o
all foreseeable operating conditions. Oxygen content not exceeding 8% by — Confirm valve locking and interlocking arrangement or procedures.— Confirm pressure/vacuum breaking devices installed.— Confirm deck seal supply pump is running and maintaining levels in the de— Confirm the inert gas system is capable of supplying a gas or mixture of ga— not more than 5%— Confirm all instrumentation feedback to the Inert gas control system is fun
ESD/PSD system.— Portable instruments for measuring oxygen and flammable vapour concent
instrumentation readings.Instrumentation, control and monitoring systems
DNVGl-OS-E101Ch.2 Sec.4 [3.1]
DNVGL-OS-D202
— See section on Instrumentation and Telecommunication systems for requir— On-board testing shall demonstrate, verify and document full functionality o
- During installation, the correct function of individual equipment packagefor automation and safety (time constants, set points, etc.)
- During installation and sea trials, the correct function of systems and intautomation and safety systems to keep any equipment under control (Esafety / protective actions;
- The correct distribution, protection and capacity of power supplies- Back-up and emergency automation and safety functions for essential un
that the essential installation functions are operable on the available bacapplication standard), and in a situation where the normal system is disprogramme shall be kept on the installation, completed with final set po
— Hydraulic automation and shut-down systems with on or off regulation shareturn headers are adequately sized and free of blockages which could pre
— For pneumatic and hydraulic automation systems with accumulators used tverification of accumulator charge level and capacity.
Instrument air system
DNVGL-OS-E201 Ch.2 Sec.5
— Confirm generator integration piping is complete, installed as per P&IDs — Confirm small bore tubing is complete, installed as per P&IDs, correctly sup— Confirm dew points, liquid traps and regulator set points correct.
Nitrogen generation system
DNV Rule for Ships Pt.5 Ch.3
— Confirm generator integration piping is complete, installed as per P&IDs, corsmall bore tubing satisfactorily completed and leak testing of complete inte
— Confirm 02 detection operational.
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ccordance with approved designs.
le in process areas. Flashing beacons to be confirmed
ery backup.
Table G-2 DNV GL survey scope for PROD (Continued)
Escape and communication
DNVGL-OS-A101Ch.2 Sec.5
— Confirmed two escape from modules and rooms in the topside areas is in a— Surface coatings and marking to be confirmed adequate.— PA/GA tests to be conducted on both ‘A’ and ‘B’ to confirm alarms are audib
in high noise areas.— Confirm signage— Confirm adequate lighting on escape routes on normal and emergency batt
System / equipment description
DNV GL OS /rule reference
DNV GL surveillance focus
SAF
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