Facility Information Summary AER Reporting Year 2016 ... · SW1 Water Suspended Solids composite...
Transcript of Facility Information Summary AER Reporting Year 2016 ... · SW1 Water Suspended Solids composite...
12016
P0830-02
0
Date 21-Mar-17
Facility Information Summary
Licence Register NumberName of site Whitegate Power StationSite Location Fort David Road, Whitegate, Co. Cork
AER Reporting Year
NACE Code 3521Class/Classes of Activity Thermal Power Station
Melissa Morrissey
EHS ManagerGroup/Facility manager
(or nominated, suitably qualified andexperienced deputy)
National Grid Reference (6E, 6 N) 51 49'07" N, 8 15'17"W
A description of the activities/processesat the site for the reporting year. Thisshould include information such asproduction increases or decreases on site,any infrastructural changes,environmental performance which wasmeasured during the reporting year andan overview of compliance with yourlicence listing all exceedances of licencelimits (where applicable) and what theyrelate to e.g. air, water, noise.
Whitegate Power Station is a Combined Cycle Power Plant (CCGT), which utilises natural gas and distillate oil asfuel to generate up to 450 MW of electricity for supply to the NationalGrid. The site is located to the southwest ofWhitegate village, County Cork on the Fort Davis Road. The power station site is approximately ten hectares.Neighbouring lands are used for a variety of activities, including: an adjacent oil refinery, a gas bottling plantdepot, agricultural activities, and the Fort Davis fortifications to the west. Bord Gais Eireann (Owner) is the IELicence holder and has contracted General Electric Operations and Maintenance (GE O&M) to operate andmaintain the power station and its environmental policy, aspects and impacts on their behalf.
Declaration:All the data and information presented in this report has been checked and certified as being accurate. The
quality of the information is assured to meet licence requirements.
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AIR-summary template Lic No: P0830-02 Year 2016Answer all questions and complete all tables where relevant
2No
3Basic airmonitoringchecklist AGN2
Yes
Table A1: Licensed Mass Emissions/Ambient data-periodic monitoring (non-continuous)
Emissionreference no: Parameter/ Substance
Frequency ofMonitoring
ELV in licence orany revisiontherof Licence Compliance criteria
Measured value Unit ofmeasurement
Compliant withlicence limit
Method of analysis Annual massload (kg)
Comments -reason forchange in %mass loadfrom previousyear ifapplicable
A1-1 volumetric flow Biannually 250000 Daily average < ELV
142038 m3 yes OTH
A1-1 volumetric flow Biannually 50000 All 1-hour averages < ELV
45479 m3 yes OTH
A1-1Nitrogen oxides(NOx/NO2) Biannually 200 All 1-hour averages < 2 x ELV
142.1 mg/Nm3 yes EN 14792:2005 548.3 Natural GasLicense Limits.
A1-1Sulphur oxides(SOx/SO2) Biannually 10 All 1-hour averages < ELV
0.63 mg/Nm3 yes EN 14791:2005 2.31 Natural GasLicense Limits.
A1-1Particulate matter(PM10) Biannually 5 All 1-hour averages < ELV
0.83 mg/Nm3 yes 2.98 Natural GasLicense Limits.
A1-1Nitrogen oxides(NOx/NO2) Biannually 400 All 1-hour averages < 2 x ELV
0 mg/Nm3 yes EN 14792:2005 0 Liquid FuelLicense Limits.Aux. Boiler
A1-1Sulphur oxides(SOx/SO2) Biannually 100 All 1-hour averages < ELV
0 mg/Nm3 yes EN 14791:2005 0 Liquid FuelLicense Limits.Aux. Boiler
A1-1Particulate matter(PM10) Biannually 20 All 1-hour averages < ELV
0 mg/Nm3 yes 0 Liquid FuelLicense Limits.Aux. Boiler
A2-1Sulphur oxides(SOx/SO2) Biannually 10 All 1-hour averages < ELV
0.18 mg/Nm3 yes EN 14791:2005 16228.75 Natural GasLicense Limits.
A2-1Particulate matter(PM10) Biannually 2 All 1-hour averages < ELV
0.2 mg/Nm3 yes SELECT 2293.4 Natural GasLicense Limits.
Was all monitoring carried out in accordance with EPA guidancenote AG2 and using the basic air monitoring checklist?
Additional information
1Does your site have licensed air emissions? If yes please complete table A1 and A2 below for the current
reporting year and answer further questions. If you do not have licenced emissions and do not complete asolvent management plan (table A4 and A5) you do not need to complete the tables
Yes
Periodic/Non-Continuous Monitoring
Are there any results in breach of licence requirements? If yes please provide brief details in the comment section ofTableA1 below
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AIR-summary template Lic No: P0830-02 Year 2016
A2-1Sulphur oxides(SOx/SO2) Biannually 60 All 1-hour averages < ELV
0 mg/Nm3 yes EN 14791:2005 0 Liquid FuelLicense Limits.
A2-1Particulate matter(PM10) Biannually 20 All 1-hour averages < ELV
0 mg/Nm3 yes SELECT 0 Liquid FuelLicense Limits.
Note 1: Volumetric flow shall be included as a reportable parameter
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AIR-summary template Lic No: P0830-02 Year 2016
4Yes
5 Yes
6Yes
7No
Table A2: Summary of average emissions -continuous monitoring
Emissionreference no:
Parameter/ Substance
ELV in licence orany revision therof
Averaging Period Compliance Criteria Units ofmeasurement
Annual Emission Annual maximum MonitoringEquipmentdowntime (hours)
Number of ELVexceedences incurrentreporting year
Comments
A2-1 volumetric flow 4000000 Hourly All 1-hour averages < ELV m3 1368273 1943466 0
A2-1Nitrogen oxides(NOx/NO2)
75 Hourly
Daily average < ELV mg/Nm3
35.2 51.5 5 0 Natural GasLicense Limits.
A2-1Nitrogen oxides(NOx/NO2)
90 Hourly
Daily average < ELV mg/Nm3
0 0 0 0 Liquid FuelLicense Limits.
A2-1 Carbon monoxide (CO)
100 Hourly
Daily average < ELV mg/Nm3
3.23 29.25 Natural GasLicense Limits.
A2-1 Carbon monoxide (CO)
100 Hourly
Daily average < ELV mg/Nm3
0 0 Liquid FuelLicense Limits.
SELECT SELECTSELECT SELECTSELECT SELECTSELECT SELECT
note 1: Volumetric flow shall be included as a reportable parameter.
Table A3: Abatement system bypass reporting table Bypass protocol
Date* Duration** (hours) Location Reason for bypass Corrective actionImpact magnitude
* this should include all dates that an abatement system bypass occurred
** an accurate record of time bypass beginning and end should be logged on site and maintained for future Agencyinspections please refer to bypass protocol link
If yes please review your continuous monitoring data and report the required fields below in Table A2 and compareit to its relevant Emission Limit Value (ELV)
Did continuous monitoring equipment experience downtime? If yes please record downtime in table A2 below 5 hours were lost in January due to failure of hardrive
Do you have a proactive service agreement for each piece of continuous monitoring equipment? Signal Ambitech for CEMS
Did your site experience any abatement system bypasses? If yes please detail them in table A3 below
Continuous Monitoring
Does your site carry out continuous air emissions monitoring?
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AIR-summary template Lic No: P0830-02 Year 2016
8 Do you have a total Emission Limit Value of direct and fugitive emissions on site? if yes please fill out tables A4 and A5SELECT
Solventregulations
Reporting year Total solvent input onsite (kg)
Total VOCemissions to Airfrom entire site
(direct and fugitive)
Total VOCemissions as %ofsolvent input Total Emission Limit Value
(ELV) in licence or any revisiontherof
Compliance
SELECT
SELECT
(I) Inputs (kg)
Solvent(I) Inputs (kg)
Organic solventemission in waste
gases(kg)
Solvents lost inwater (kg)
Collected waste solvent (kg) Fugitive OrganicSolvent (kg)
Solvent releasedin other ways e.g.by-passes (kg)
Solvents destroyedonsite throughphysical reaction
Total emission ofSolvent to air (kg)
Total
Solvent use and management on site
Table A5: Solvent Mass Balance summary
Please refer to linked solvent regulations tocomplete table 5 and 6
(O) Outputs (kg)
Table A4: Solvent Management Plan SummaryTotal VOC Emission limit value
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AER Monitoring returns summary template-WATER/WASTEWATER(SEWER) Lic No: P0830-02 Year 2016
2
Yes
Locationreference
Locationrelative to site
activitiesPRTR Parameter Licenced
ParameterMonitoring
date
ELV or triggerlevel in licenceor any revision
thereof*
LicenceCompliance
criteriaMeasured value Unit of
measurementCompliant with
licenceComments
SW2
downstreamTotal organic carbon (TOC) (as total C or COD/3)Total Organic Carbon (as C)
Continuous
40 All results < 1.2 xELV
3.83 ppm yes Pumpsinterlocked toTOC analyser.Result isaverage of all.
SW2
downstream pH
Continuous
5.5-10 No pH value shalldeviate from thespecified range.
8.7 pH units yes Pumpsinterlocked topH meter.Result isaverage
SW2downstream Conductivity Grab Sample 494.9 All results < 1.2 x
ELV158.5 µS/cm @20oC yes Average of
results
SW2downstream COD Grab Sample 50 All results < 1.2 x
ELV8.11 mg/L yes Average of
results
*trigger values may be agreed by the Agency outside of licence conditions
LocationReference
Date ofinspection
Source ofcontamination
SELECTSELECT
3No
4
External /InternalLab Qualitychecklist
Assessment ofresults checklist
Yes
Table W3: Licensed Emissions to water and /or wastewater (sewer)-periodic monitoring (non-continuous)0.18
Emissionreference no:
Emissionreleased to
Parameter/SubstanceNote 1 2
Frequency ofmonitoring
Averaging period ELV or triggervalues in licence orany revisiontherofNote 2
Licence Compliance criteria Measured value Unit ofmeasurement
Compliantwith licence
Method of analysis Procedural reference source
Procedural referencestandard number
Annual mass load(kg) Comments
SW1 Water BOD composite Monthly 24 hour 20All results < 1.2 times ELV, plus
8 from ten results must be <ELV
4.21 mg/L yes
Other (5 DayCarbonaceous Method
based on BS 6068-2.14:1990
ISO 5815:1989
B.S. (British Standard)
ENVCM-031
135.79All results for the periodwere reported as less the
10mg/l
SW1 Water Suspended Solids composite Weekly 24 hour 30All results < 1.2 times ELV, plus
8 from ten results must be <ELV
<10 mg/L Liquid FuelLicense Limits.
Gravimetric analysis
Other (Standard Methods forthe Examination of Water and
Wastewater, 20th edition1997, Method 2540-D)
WPS-QAP 06-QWI 112
71.13
All results for the periodwere reported as less the10mg/l by external Lab,
andinternal lab <7.35 bartwo samples of 9.5.
SW1 Water Ammonia (as N) composite Weekly 24 hour 5All results < 1.2 times ELV, plus
8 from ten results must be <ELV
0.38 mg/L yesOther (LCK 304 (salicylate
method))Other (Method 4500-NH3 and
ASTM D1426 )WPS-QAP 06-QWI 108
9.67
Bar two results allexternal lab results were
<0.2. the highest was1.23mg/l
SW1 Water Total phosphorus composite Weekly 24 hour 5All results < 1.2 times ELV, plus
8 from ten results must be <ELV
0.36 mg/L yesOther (LCK 348 , LCK 349(ascorbic acid method) )
Other (USEPA method 365.2and Standard Method 4500-P-
E for wastewater) WPS-QAP 06-QWI 106
1.7
Bar two results allexternal lab results were
<0.1. the highest was0.15mg/l
SW1 Water Mineral oils composite Monthly 24 hour 20All results < 1.2 times ELV, plus
8 from ten results must be <ELV
<1 mg/L yes Fourier Infra-Red (FTIR) ISOENVCM-053
5.78All results <1. Ten of
Twelve samples reportedas <0.01
SW1 Water Total Dissolved Solids composite Weekly 24 hour N/A All results < 1.2 times ELV, plus8 from ten results must be <
885.57 mg/L yes Gravimetric analysis Other (Standard Methods forthe Examination of Water and WPS-QAP 06-QWI 112 28042
Licensed Emissions to water and /or wastewater(sewer)-periodic monitoring (non-continuous)Was there any result in breach of licence requirements? If yes please provide brief details in
the comment section of Table W3 below
Additional information
Was all monitoring carried out in accordance with EPAguidance and checklists for Quality of Aqueous MonitoringData Reported to the EPA? If no please detail what areas
require improvement in additional information box
Comments
Was it a requirement of your licence to carry out visual inspections on any surface waterdischarges or watercourses on or near your site? If yes please complete table W2 below
summarising only any evidence of contamination noted during visual inspections
Not a licence requirement but based on recommendations by ARUP intheir Hydrogeological Assessment of site in 2015, monthly monitoring of
the Glenagow Stream takes place at entrance and exit of site
Table W1 Storm water monitoring
Table W2 Visual inspections-Please only enter details where contamination was observed.
Description of contamination
Corrective action
Additional information
1
Does your site have licensed emissions direct to surface water or direct to sewer? If yesplease complete table W2 and W3 below for the current reporting year and answer
further questions. If you do not have licenced emissions you only need to complete tableW1 and or W2 for storm water analysis and visual inspections
Yes SW2 licenced Stormwater point
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AER Monitoring returns summary template-WATER/WASTEWATER(SEWER) Lic No: P0830-02 Year 2016Additional information
SW1 Water72 HR IC2 to
PhaedactylumTricornutum
discrete Annual 24 hour 10All results < 1.2 times ELV, plus
8 from ten results must be <ELV
1.29 NTU yes Toxicity Analysis ISO Algaltoxkit calculationprogramme
41.19
SW2 Water Conductivity discrete Monthly Monthly 494.9 All results < 1.2 x ELV 158.5 µS/cm@25oC yes Conductivity Meter(Electrode)
B.S. (British Standard) WPS-QAP 06-QWI 118
SW2 Water COD discrete Monthly Monthly50
All results < 1.2 x ELV8.11
mg/L yesstandard method, asdocumented by ISO
15705 ST-CODISO
WPS-QAP 06-QWI 11156.149
Note 1: Volumetric flow shall be included as a reportable parameterNote 2: Where Emission Limit Values (ELV) do not apply to your licence please compare results against EQS for Surface water or relevant receptor quality standards
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AER Monitoring returns summary template-WATER/WASTEWATER(SEWER) Lic No: P0830-02 Year 2016Additional information
5 Yes
6Yes
7 Yes For TOC EASL biodetector. pH and temperature probes in house
8 NoTable W4: Summary of average emissions -continuous monitoring
Emissionreference no:
Emissionreleased to Parameter/ Substance
ELV or triggervalues in licenceor any revisionthereof
AveragingPeriod
ComplianceCriteria
Units ofmeasurement
Annual Emission for currentreporting year (kg)
% change +/- fromprevious reportingyear
MonitoringEquipmentdowntime (hours)
Number ofELVexceedencesin reportingyear
SW1 Water volumetric flow 600 24 hour All values < ELV m3/day 31931 107.78% 0 0SW1 Water volumetric flow 50 1 hour All values < ELV m3/hour 38.6 0 0
SW1 Water pH 6-9 Instantaneous
No pH valueshall deviate
from the.specified range
pH units 6.5 - 8.58 0 0
SW1 Water Temperature 25 Instantaneous
No temperaturevalue shall
exceed the limit.value
degrees C 24.41 0 0
SW2 Water pH 5.5-10 Instantaneous
No pH valueshall deviate
from the.specified range
pH units 6.49 - 9.8 0 0
SW2 WaterTotal organic carbon(TOC) (as total C or
COD/3)40 Instantaneous All values < ELV mg/L 56.149 458.31% 0 0
note 1: Volumetric flow shall be included as a reportable parameter.
Table W5: Abatement system bypass reporting tableDate Duration
(hours)Location Resultant
emissionsReason forbypass
Correctiveaction*
Was a reportsubmitted to theEPA?
When was this reportsubmitted?
SELECT
*Measures taken or proposed to reduce or limit bypass frequency
Did continuous monitoring equipment experience downtime? If yes please record downtime intable W4 below Composite sampler failure in October 13th to 25thDo you have a proactive service contract for each piece of continuous monitoring equipment onsite?Did abatement system bypass occur during the reporting year? If yes please complete table W5below
CommentsIncrease in volume discharged is due to increased running durations, compunded by greater losses
Continuous monitoring Additional Information
Does your site carry out continuous emissions to water/sewer monitoring? SW2 - pH & TOC and for SW1 - pH, temp, Flow
If yes please summarise your continuous monitoring data below in Table W4 and compare itto its relevant Emission Limit Value (ELV)
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Bund/Pipeline testing template Lic No: P0830-02 Year 2016
Bund testing Additional information
1 Yes
Results of failures were reported in2015 AER, hence table B1 below left
blank2 Please provide integrity testing frequency period 3 years last completed in 2015
3 Yes4 How many bunds are on site? 69 47 + 22 Mobile bunds
5 How many of these bunds have been tested within the required test schedule? 6947 Bund structures includingchemstore units
6 How many mobile bunds are on site? 227 Are the mobile bunds included in the bund test schedule? Yes
8 How many of these mobile bunds have been tested within the required test schedule?22 2 failed & were disposed of in 2015
918 Sumps normally tested when the
bund is been tested.
10
18 There are also four basins on site,three of which have been tested.Equalisation basin cannot be testeddue to plant running regime
Please list any sump integrity failures in table B1
11No Nine have level guages - higher
volumes12 Yes listed as environmentally critical13 Is the Fire Water Retention Pond included in your integrity test programme? Yes
Bund/Containmentstructure ID Type Specify Other type Product containment Actual capacity
Type of integrity test Other test type Test date Integrity reportsmaintained on site?
Results of test Integrity test failureexplanation <50 words
Corrective action taken
Scheduled datefor retest
Results ofretest(if incurrentreporting year)
* Capacity required should comply with 25% or 110% containment rule as detailed in your licence
15 bunding and storage guidelines No16 Are channels/transfer systems to remote containment systems tested? Yes17 Are channels/transfer systems compliant in both integrity and available volume? No
1 Yes2 Please provide integrity testing frequency period 3 years
*please note integrity testing means water tightness testing for process and foul pipelines (as required under your licence)
Structure ID Type system Material of construction:Does this structure haveSecondary containment?
Type of secondarycontainment
Type integrity testingIntegrity reportsmaintained on site? Results of test
Integrity test failure explanation <50words
Corrective actiontaken
Scheduled datefor retest
Results of retest(if in currentreporting year)
D.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
D.01.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
D.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
D.02.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
D.03 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
D.04 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.01.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.01.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.01.03.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
Does the site maintain a register of bunds, underground pipelines (including stormwater and foul), Tanks, sumps and containers? (containers refers to "Chemstore"type units and mobile bunds)
Has integrity testing been carried out in accordance with licence requirements and are all structures tested inline with BS8007/EPA Guidance?
Do all sumps and chambers have high level liquid alarms?If yes to Q11 are these failsafe systems included in a maintenance and testing programme?
dropdown menu click to see options
Are you required by your licence to undertake integrity testing on bunds and containment structures ? if yes please fill out table B1 below listing all new bunds andcontainment structures on site, in addition to all bunds which failed the integrity test-all bunding structures which failed including mobile bunds must be listed inthe table below, please include all bunds outside the licenced testing period (mobile bunds and chemstore included)
Are you required by your licence to undertake integrity testing* on underground structures e.g. pipelines or sumps etc ? if yes please fill out table 2 below listing allunderground structures and pipelines on site which failed the integrity test and all which have not been tested withing the integrity test period as specified
Table B2: Summary details of pipeline/underground structures integrity test
How many sumps on site are included in the integrity test schedule?
How many of these sumps are integrity tested within the test schedule?
Table B1: Summary details of bund /containment structure integrity test
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Bund/Pipeline testing template Lic No: P0830-02 Year 2016
DA.02.05.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.02.05.01.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.02.05.01.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.02.05.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.02.05.03 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.03 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.04 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.05 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.05.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.05.03 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.05.04 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.05.05 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.06 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.07 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.08 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.09 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.10 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.10.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.11 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.11.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.14 Process concrete No Hydraulic Yes Fail Lost pressure steadily over test timeArranging contractorfor repair
DA.15 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.17 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.17.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.17.03 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DB.01 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DB.01.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DB.02 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DB.04 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DB.05 Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
DE.02. Process concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
D.02.02 to D.02.03 Process pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
11
Bund/Pipeline testing template Lic No: P0830-02 Year 2016
DA.06 to Channel Drain Process pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.17 to DA.17.01 Process polypropylene No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
DA.17.02 to DA.17.01 Process polypropylene No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW1 to C.SW.2/C.SW.3 Foul pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.1 to C.SW.3 Foul pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.3 to C.SW.5 Foul pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.4 to C.SW.5 Foul pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.6 to C.SW.7 Foul pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.10 to C.SW.11 Foul pvc No Air Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.01.01.03 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.01.01.02 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.01.01.01.01 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.01.01 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.01. Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.03 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.04 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.05.02 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.05.03 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.05.04 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.05.05 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.06 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.07 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.08 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
SW.09 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.02 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.03 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.05 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.06 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.07 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.07.01 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.07.02 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.07.03 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.10 Foul pvc No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
C.SW.13 Foul concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
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Bund/Pipeline testing template Lic No: P0830-02 Year 2016
ST.C.09 Storm concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
ST.C.09.01 Storm concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
ST.C.10 Storm concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
ST.C.11 Storm concrete No Hydraulic Yes Fail loss of pressure during testing period Repaired Feb 2017 16/02/2017 Pass
ST.C.12 Storm concrete No Hydraulic Yes Fail loss of pressure during testing period Repaired Feb 2017 16/02/2017 Pass
ST.C.12.01 Storm concrete No Hydraulic Yes Fail loss of pressure during testing periodArranging contractorfor repair
Please use commentary for additional details not answered by tables/ questions above
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Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016
Comments
1yes
2 no
3 no
4Groundwater
monitoringtemplate yes
Hydrogeological andGroundwaterContamination Assessmentsubmitted in February 2015 to EPA compiled by ARUPbased on results from 2014and previous years
5
yes
6
7N/A
8yes 12.2.2
9yes ELRA & EIS
10yes
11yes
12
no
Table 1: Upgradient Groundwater monitoring results
Date ofsampling
Samplelocationreference
Parameter/Substance Methodology
Monitoringfrequency
MaximumConcentration++
AverageConcentration+
unit GTV's* IGV Upward trendin pollutantconcentrationover last 5years ofmonitoringdata
10/05/2016 BH01 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH01 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
yes
Please specify the proposed time frame for the remediation strategy
Is there a licence condition to carry out/update ELRA for the site?
Is there evidence that contamination is migrating offsite?
Please provide an interpretation of groundwater monitoring data inthe interpretation box below or if you require additional space
please include a groundwater/contaminated land monitoring resultsinterpretaion as an additional section in this AER
Are you required to carry out groundwater monitoring as part of your licencerequirements?
Is the contamination related to operations at the facility (either current and/orhistoric)
Have actions been taken to address contamination issues?If yes please summariseremediation strategies proposed/undertaken for the site
There were incidences of exceedance of the IGVs for Manganeseand Total Petroleum Hydrocarbons (TPHs) observed in somesamples in upgradient well waters in 2014 (Theses incidences werealso recorded in previous years 2012 and 2013). An investigationwas undertaken by ARUP at the time, and submitted to the EPA.The laboratory results are generally in decline from historic valuesfor the various boreholes with some increases and some decreasesin heavy metals and hydrocarbon parameters, but generally animproving trend over time. Upgradient wells include BH01, BH02,BH03, BH04, BH05, BH06, BH08. BH01 has shown a decline in heavymetal concentration in 2016 from 2015 figures, BH03 has shown aslight rise in Manganese concentration to average of 48.5ug/l. BH04has shown an increase in the concentration of manganese from thehighest value of 4090ug/l in 2015 to value of 6132ug/l in 2016 andTPH rose slightly in the November 2016 sampling from that in May.This bore BH04 has shown historically to have rises and falls in theconcentration of these elements since 2012. BH05 has shown aslight increase in Manganese concentration but a drop in Titanium.Max concentration TPH in 2015 was 17ug/l but in 2016 <10ug/l.Mercury in BH06 had max concentration rise from 0.02ug/l in 2015to 0.06ug/l in 2016. Manganese max concentration in BH 08 hasdropped from 3101ug/l to 999ug/l with Nickel also dropping from22ug/l to <2 ug/l, and Titanium from 89 ug/l to <5ug/l, and TPHdown from 75ug/l to <10ug/l. BH07A has shown a very slight rise inarsenic levels from <2.5 to 3.5ug/l, but has shown a decrease in anumber of elements Max Concentration Values; Chronium downfrom 3.10 to <1.5ug/l, Cobalt dropped from 2.7 to <2ug/l, Copperdown from 9.2 to <7ug/l, Manganese down from 150 to 80ug/l ,Ttitanium down from 9 to <5ug/l, and TPH down from 75 to <10ug/l.BH09 Arsecnic concentration showing a decrease as has copper,cobalt and maganese, titanium, TPH. BH11 chromium levels haveshown slight increase, manganese slight decrease.
Joint Gr. Water Monitoringreport with P66 submittedvia Alder on 30th June 2015
Are you required to carry out soil monitoring as part of your licence requirements?
Has a Conceptual Site Model been developed for the site?
Do you extract groundwater for use on site? If yes please specify use in commentsectionDo monitoring results show that groundwater genericassessment criteria such as GTVs or IGVs are exceeded or isthere an upward trend in results for a substance? If yes,please complete the Groundwater Monitoring GuidelineTemplate Report (link in cell G8) and submit separatelythrough ALDER as a licensee return AND answer questions 5-12 below.
Has any type of risk assesment been carried out for the site?
Have potential receptors been identified on and off site?
14
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016BH01 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH01 Cobalt 2 Biannual <2 <2 ug/l - - noBH01 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH01 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH01 Manganese ICP-OES Biannual <2 <2 ug/l - 50 noBH01 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH01 Tin ICP-OES Biannual <5 <5 ug/l - - noBH01 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH01Mercury
Cold VapourAtomic
Fluorescence. Biannual0.09 0.05 ug/l 0.75
no
BH01Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l - 10 no
BH01 TPH(C5-35) GC-FID Biannual<10 <10 ug/l 0.075 no
BH01 MTBE #GC-FID Biannual
<5 <5 ug/l no
BH01 Benzene #GC-FID Biannual
<5 <5 ug/l 0.75 no
BH01 Toluene #GC-FID Biannual
<5 <5 ug/l no
BH01 Ethylbenzene #GC-FID Biannual
<5 <5 ug/l no
BH01 m/p-Xylene #GC-FID Biannual
<5 <5 ug/l no
BH01 o-Xylene #GC-FID Biannual
<5 <5 ug/l no
BH01 Conductivity Probe Biannual 337 350 uS/cm 800-1875 1000 noBH01 pH Probe Biannual 6.65 6.64 pH units - 6.5 - 9.5 no
10/05/2016 BH02 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH02 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH02 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH02 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH02 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH02 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH02 Manganese ICP-OES Biannual 9 5.5 ug/l - 50 no
BH02Mercury Vapour Atomic
Fluorescence Biannual
0.07 0.04 ug/l0.75 1
no
BH02 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH02 Tin ICP-OES Biannual <5 <5 ug/l - - noBH02 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH02Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l - 10 no
BH02 TPH (C5-35) GC-FID. Biannual <10 <10 ug/l 0.75 no
BH02 MTBE # GC-FID Biannual <5 <5 ug/l noBH02 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH02 Toluene # GC-FID Biannual <5 <5 ug/l noBH02 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH02 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH02 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH02 Conductivity Probe Biannual 389 374 uS/cm 800-1875 1000 noBH02 pH Probe Biannual 6.43 6.41 pH units - 6.5 - 9.5 no
10/05/2016 BH03 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH03 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH03 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH03 Cobalt ICP-OES Biannual 3 2.5 ug/l - - noBH03 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 no
15
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016BH03 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH03 Manganese ICP-OES Biannual 95 48.5 ug/l - 50 no
BH03Mercury Vapour Atomic
Fluorescence Biannual
0.01 <0.01 ug/l0.75 1
no
BH03 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH03 Tin ICP-OES Biannual <5 <5 ug/l - - noBH03 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH03Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l no
BH03 TPH (C5-35) GC-FID. Biannual<10 <10 ug/l - 10 no
BH03 MTBE # GC-FID Biannual <5 <5 ug/l noBH03 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH03 Toluene # GC-FID Biannual <5 <5 ug/l noBH03 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH03 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH03 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH03 Conductivity Probe Biannual 371 367 uS/cm 800-1875 1000 noBH03 pH Probe Biannual 6.82 6.7 pH units - 6.5 - 9.5 no
10/05/2016 BH04 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH04 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH04 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH04 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH04 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH04 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH04 Manganese ICP-OES Biannual 6132 4780 ug/l - 50 no
BH04Mercury Vapour Atomic
Fluorescence Biannual
0.03 0.02 ug/l0.75 1
no
BH04 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH04 Tin ICP-OES Biannual <5 <5 ug/l - - noBH04 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH04Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l no
BH04 TPH (C5-35) GC-FID. Biannual122 66 ug/l - 10 yes
BH04 MTBE # GC-FID Biannual <5 <5 ug/l noBH04 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH04 Toluene # GC-FID Biannual <5 <5 ug/l noBH04 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH04 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH04 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH04 Conductivity Probe Biannual 524 518 uS/cm 800-1875 1000 noBH04 pH Probe Biannual 6.8 6.79 pH units - 6.5 - 9.5 no
10/05/2016 BH05 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH05 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH05 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH05 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH05 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH05 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH05 Manganese ICP-OES Biannual 74 38 ug/l - 50 yes
BH05Mercury Vapour Atomic
Fluorescence Biannual
<0.01 <0.01 ug/l0.75 1
no
BH05 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH05 Tin ICP-OES Biannual <5 <5 ug/l - - no
16
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016BH05 Titanium ICP-OES Biannual <5 <5 ug/l - - yes
BH05Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l no
BH05TPH (>C10-
40) GC-FID. Biannual<10 <10 ug/l - 10 no
BH05 MTBE # GC-FID Biannual <5 <5 ug/l noBH05 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH05 Toluene # GC-FID Biannual <5 <5 ug/l noBH05 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH05 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH05 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH05 Conductivity Probe Biannual 438 430 uS/cm 800-1875 1000 noBH05 pH Probe Biannual 6.95 6.84 pH units - 6.5 - 9.5 no
10/05/2016 BH06 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH06 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH06 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH06 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH06 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH06 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH06 Manganese ICP-OES Biannual <2 <2 ug/l - 50 no
BH06Mercury Vapour Atomic
Fluorescence Biannual
0.06 0.035 ug/l0.75 1
no
BH06 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH06 Tin ICP-OES Biannual <5 <5 ug/l - - noBH06 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH06Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l no
BH06TPH (>C10-
40) GC-FID. Biannual<10 <10 ug/l - 10 no
BH06 MTBE # GC-FID Biannual <5 <5 ug/l noBH06 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH06 Toluene # GC-FID Biannual <5 <5 ug/l noBH06 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH06 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH06 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH06 Conductivity Probe Biannual 490 449.5 uS/cm 800-1875 1000 noBH06 pH Probe Biannual 6.91 6.89 pH units - 6.5 - 9.5 no
10/05/2016 BH08 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH08 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH08 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH08 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH08 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH08 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH08 Manganese ICP-OES Biannual 999 814.5 ug/l - 50 no
BH08Mercury Vapour Atomic
Fluorescence Biannual
<0.01 <0.01 ug/l0.75 1
no
BH08 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH08 Tin ICP-OES Biannual <5 <5 ug/l - - noBH08 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH08Mineral Oil(>C10-40) GC-FID. Biannual
<10 <10 ug/l no
BH08TPH (>C10-
40) GC-FID. Biannual<10 <10 ug/l - 10 no
BH08 MTBE # GC-FID Biannual <5 <5 ug/l noBH08 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 no
17
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016BH08 Toluene # GC-FID Biannual <5 <5 ug/l noBH08 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH08 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH08 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH08 Conductivity Probe Biannual 679 625 uS/cm 800-1875 1000 noBH08 pH Probe Biannual 6.99 6.95 pH units - 6.5 - 9.5 no
.+ where average indicates arithmetic mean
.++ maximum concentration indicates the maximum measured concentration from all monitoring results produced during the reporting yearTable 2: Downgradient Groundwater monitoring results GTV's* IGV
Date ofsampling
Samplelocationreference
Parameter/Substance Methodology
Monitoringfrequency
MaximumConcentration++
AverageConcentration unit
Upward trendin yearlyaveragepollutantconcentrationover last 5years ofmonitoringdata
10/05/2016 BH07A Arsenic ICP-OES Biannual 3.5 3 ug/l 7.5 10 no24/11/2016 BH07A Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH07A Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH07A Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH07A Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH07A Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH07A Manganese ICP-OES Biannual 80 41 ug/l - 50 no
BH07AMercury Vapour Atomic
Fluorescence Biannual 0.02 0.02
ug/l0.75 1
noBH07A Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH07A Tin ICP-OES Biannual <5 <5 ug/l - - noBH07A Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH07AMineral Oil(>C10-40) GC-FID. Biannual <10 <10
ug/lno
BH07ATPH (>C10-
40) GC-FID. Biannual <10 <10ug/l - 10 no
BH07A MTBE # GC-FID Biannual <5 <5 ug/l noBH07A Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH07A Toluene # GC-FID Biannual <5 <5 ug/l noBH07A Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH07A m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH07A o-Xylene # GC-FID Biannual <5 <5 ug/l noBH07A Conductivity Probe Biannual 427 411 uS/cm 800-1875 1000 noBH07A pH Probe Biannual 6.83 6.78 pH units - 6.5 - 9.5 no
10/05/2016 BH09 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH09 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH09 Chromium ICP-OES Biannual <1.5 <1.5 ug/l 37.5 30 noBH09 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH09 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH09 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH09 Manganese ICP-OES Biannual 12 7 ug/l - 50 no
BH09Mercury Vapour Atomic
Fluorescence Biannual <0.01 <0.01
ug/l0.75 1
noBH09 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 no
18
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016BH09 Tin ICP-OES Biannual <5 <5 ug/l - - noBH09 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH09Mineral Oil(>C10-40) GC-FID. Biannual <10 <10
ug/lno
BH09TPH (>C10-
40) GC-FID. Biannual <10 <10ug/l - 10 no
BH09 MTBE # GC-FID Biannual <5 <5 ug/l noBH09 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH09 Toluene # GC-FID Biannual <5 <5 ug/l noBH09 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH09 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH09 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH09 Conductivity Probe Biannual 456 405.5 uS/cm 800-1875 1000 noBH09 pH Probe Biannual 7.53 7.39 pH units - 6.5 - 9.5 no
10/05/2016 BH10 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH10 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH10 Chromium ICP-OES Biannual 2.7 2.15 ug/l 37.5 30 noBH10 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH10 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH10 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH10 Manganese ICP-OES Biannual <2 <2 ug/l - 50 no
BH10Mercury Vapour Atomic
Fluorescence Biannual <0.01 <0.01
ug/l0.75 1
noBH10 Nickel ICP-OES Biannual <2 <2 ug/l 15 20 noBH10 Tin ICP-OES Biannual <5 <5 ug/l - - noBH10 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH10Mineral Oil(>C10-40) GC-FID. Biannual <10 <10
ug/lno
BH10TPH (>C10-
40) GC-FID. Biannual <10 <10ug/l - 10 no
BH10 MTBE # GC-FID Biannual <5 <5 ug/l noBH10 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH10 Toluene # GC-FID Biannual <5 <5 ug/l noBH10 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH10 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH10 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH10 Conductivity Probe Biannual 196 173 uS/cm 800-1875 1000 noBH10 pH Probe Biannual 7.35 7.275 pH units - 6.5 - 9.5 no
10/05/2016 BH11 Arsenic ICP-OES Biannual <2.5 <2.5 ug/l 7.5 10 no24/11/2016 BH11 Cadmium ICP-OES Biannual <0.5 <0.5 ug/l 3.75 5 no
BH11 Chromium ICP-OES Biannual 24.9 13.2 ug/l 37.5 30 noBH11 Cobalt ICP-OES Biannual <2 <2 ug/l - - noBH11 Copper ICP-OES Biannual <7 <7 ug/l 1500 30 noBH11 Lead ICP-OES Biannual <5 <5 ug/l 18.75 10 noBH11 Manganese ICP-OES Biannual 5 3.5 ug/l - 50 no
BH11Mercury Vapour Atomic
Fluorescence Biannual <0.01 <0.01
ug/l0.75 1
noBH11 Nickel ICP-OES Biannual 10 6 ug/l 15 20 noBH11 Tin ICP-OES Biannual <5 <5 ug/l - - noBH11 Titanium ICP-OES Biannual <5 <5 ug/l - - no
BH11Mineral Oil(>C10-40) GC-FID. Biannual <10 <10
ug/lno
BH11TPH (>C10-
40) GC-FID. Biannual <10<10 ug/l - 10 no
BH11 MTBE # GC-FID Biannual <5 <5 ug/l no
19
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016BH11 Benzene # GC-FID Biannual <5 <5 ug/l 0.75 noBH11 Toluene # GC-FID Biannual <5 <5 ug/l noBH11 Ethylbenzene # GC-FID Biannual <5 <5 ug/l noBH11 m/p-Xylene # GC-FID Biannual <5 <5 ug/l noBH11 o-Xylene # GC-FID Biannual <5 <5 ug/l noBH11 Conductivity Probe Biannual 502 469.5 uS/cm 800-1875 1000 noBH11 pH Probe Biannual 6.87 6.79 pH units - 6.5 - 9.5 no
Surfacewater EQS
Groundwaterregulations
GTV's
Drinkingwater(privatesupply)standards
Drinking water (publicsupply) standards
Interim GuidelineValues (IGV)
**Depending on location of the site and proximity to other sensitive receptors alternative Receptor based Water Quality standards should be used inaddition to the GTV e.g. if the site is close to surface water compare to Surface Water Environmental Quality Standards (SWEQS), If the site is close to a
drinking water supply compare results to the Drinking Water Standards (DWS)
More information on the use of soil and groundwater standards/ generic assessmentcriteria (GAC) and risk assessment tools is available in the EPA published guidance(see the link in G31) Guidance on the Management of Contaminated Land and Groundwater at EPA Licensed Sites (EPA 2013).
*please note exceedance of generic assessment criteria (GAC) such as a Groundwater Threshold Value (GTV) or an Interim Guideline Value (IGV) or anupward trend in results for a substance indicates that further interpretation of monitoring results is required. In addition to completing the above table,
please complete the Groundwater Monitoring Guideline Template Report at the link provided and submit separately through ALDER as a licensee return oras otherwise instructed by the EPA.
20
Groundwater/Soil monitoring template Lic No: P0830-02 Year 2016
Table 3: Soil results
Date ofsampling
Samplelocationreference
Parameter/Substance Methodology
Monitoringfrequency
MaximumConcentration
AverageConcentration unit
SELECTSELECT
Where additional detail is required please enter it here in 200 words or less
21
Environmental Liabilities template Lic No: P0830-02 Year 2016
2016
Commentary
1
Submitted and agreed by EPA 14/08/2014
2 Review required and completed
3 3,276,013
4 Submitted and agreed by EPA May-16
5 €6,000,000,
6 parent company guarantee
7 N/A8 Closure plan submitted and agreed by EPA 05/08/20149 Review required and completed 30/09/2016
10 Submitted and agreed by EPA May-1611 2,411,56112 parent company guarantee13 N/AFinancial provision for Closure expiry date
Financial Provision for Closure - type
ELRA initial agreement status
ELRA review status
Amount of Financial Provision cover required as determined by the latest ELRA
Financial Provision for ELRA status
Financial Provision for ELRA - amount of cover
Financial Provision for ELRA - type
Click here to access EPA guidance on Environmental Liabilities and Financialprovision
Financial provision for ELRA expiry dateClosure plan initial agreement status
Closure plan review statusFinancial Provision for Closure status
Financial Provision for Closure - amount of cover
22
Environmental Management Programme/Continuous Improvement Programme template Lic No: P0830-02 Year 2016Additional Information
1Yes
2 Yes
3 Yes
4 Yes
Environmental Management Programme (EMP) reportObjective Category Target Status (% completed) How target was progressed Responsibility Intermediate outcomes
Additional improvementsRetain certification to14001 100%
2 opportunites forimprovement and 1 minornon-conformities Section Head
Improved EnvironmentalManagement Practices
Additional improvements
Earth Day Event(Community basedInitiative) 100% Beach Clean up - Sept 2016 Individual
Improved EnvironmentalManagement Practices
Materials Handling/Storage/Bunding Chemical Sweep 100%
Review of chemical storageareas, bunding, storage ofchemicals, SDS availabilty &emergency arrangements Individual
Improved EnvironmentalManagement Practices
Materials Handling/Storage/Bunding Permit Day Event 100%
Tested reponses of siteteam as to a MajorEnvironmental Scenario Section Head
Improved EnvironmentalManagement Practices
Groundwater protectionNo exceedance ornotifiable spills 100%
No notifiable exceedancesof consented ELV Section Head
Increased compliance withlicence conditions
Reduction of emissions to Air CEMS Crosscheck 100% Veerification of CEMS Section HeadIncreased compliance withlicence conditions
Reduction of emissions to Air Replacement CEMS PC 100% Upgrading of control Section HeadIncreased compliance withlicence conditions
Groundwater protectionProcess Drainage Integritytesting 100%
Testing of all Process lineson site Section Head
Improved EnvironmentalManagement Practices
Groundwater protectionNeutralisation Pitsresurfacing 100% Relined Pits Section Head
Improved EnvironmentalManagement Practices
Groundwater protectionRemedial Works to surfacewater lines 100%
Reline lines with identifiedweakness Section Head
Improved EnvironmentalManagement Practices
Waste reduction/Raw material usage efficiencyInstallation of new waterusage meters 0%
Improved water usagemonitoring Individual
Installation of infrastructure
Reduction of emissions to Wastewater
Fit a cover over on of thetwo neutralisation basinsin the ETP. 0%
Improved waste watertreatment Individual
Installation of infrastructure
ISO 14001:2015
Do you maintain an environmental documentation/communication system to inform the public onenvironmental performance of the facility, as required by the licence
Highlighted cells contain dropdown menu click to view
Does the EMS reference the most significant environmental aspects and associated impacts on-site
Does the EMS maintain an Environmental Management Programme (EMP) as required in accordancewith the licence requirements
Do you maintain an Environmental Mangement System (EMS) for the site. If yes, please detail inadditional information
23
Environmental Management Programme/Continuous Improvement Programme template Lic No: P0830-02 Year 2016Highlighted cells contain dropdown menu click to view
Materials Handling/Storage/Bunding Bund Modification 80%Installation of improved OilDetection Systems Individual
Increased compliance withlicence conditions
Energy Efficiency/Utility conservation Energy assessments 100% Undertake Energy Efficency AssessmentSection HeadImproved EnvironmentalManagement Practices
24
Lic No: P0830-02 Year 20162016
1 Yes
2 NoiseGuidancenote NG4
Yes
3 Yes4 30/11/2016
5 No
Date ofmonitoring Time period
Noise location(on site)
Noisesensitive
location -NSL(if applicable) LAeq
LA90 LA10 LAmax Tonal or Impulsivenoise* (Y/N)
If tonal /impulsive noise wasidentified was 5dB penaltyapplied?
Comments (ex. main noise sources onsite, & extraneous noise ex. road traffic)
Is site compliant withnoise limits(day/evening/night)?
11/08/[email protected]
30 Minute Day NSL144 33.9 43.8 73.1
No No Yes
11/08/[email protected]
30 Minute Day NSL144.6 33 44 78.1
No No Yes
11/08/[email protected]
30 Minute Day NSL148.3 33 48.7 72
No No Yes
11/08/[email protected]
30 Minute Eve NSL144.5 35.1 44.1 65.3
No No Yes
11/08/[email protected]
30 Minute Night NSL140 35 37.6 62
No No Yes
11/08/[email protected]
30 Minute Night NSL146.4 33.6 47.3 73.8
No No Yes
11/08/[email protected]
30 Minute Day NSL256 33.5 53.5 79.9
No No Yes
11/08/[email protected]
30 Minute Day NSL253.5 33.8 51 75.2
No No Yes
11/08/[email protected]
30 Minute Day NSL253.4 32.6 50 76.6
No No Yes
11/08/[email protected]
30 Minute Eve NSL244.6 35.9 40.4 70.8
No No Yes
11/08/[email protected]
30 Minute Night NSL248 34.1 38.7 76.2
No No Yes
11/08/[email protected]
30 Minute Night NSL251.2 30.1 39.8 78.8
No No Yes
*Please ensure that a tonal analysis has been carried out as per guidance note NG4. These records must be maintained onsite for future inspection
Was noise monitoring a licence requirement for the AER period?If yes please fill in table N1 noise summary below
Was noise monitoring carried out using the EPA Guidance note, including completion of the"Checklist for noise measurement report" included in the guidance note as table 6?Does your site have a noise reduction planWhen was the noise reduction plan last updated?
The LAeq for the day time round one, two and threemeasurements was 44.0dB, 44.6dB and 48.3dB respectively. TheLAeq for the evening time measurement was 44.5dB and theLAeq for the night time round one and two measurements was40.0dB and 46.4dB respectively. The second measured nighttime round the LAeq levels are above the night time noise limitof 45dBL Aeq as set out in Guidance Note for Noise (NG4) [1].However, the major contributor to measured LAeq levels duringthis measurement is considered to be noise from activity withinthe car park. The constant and steady nature of noise generatedby the Power Station, can be referenced as the LA90. The LA90for the day time round one, two and three measurements was33.9dB, 33.0dB and 33.0dB respectively, evening timemeasurement was 35.1dB and the L A90 for the night timemeasurements was 35.0dB and 33.6dB respectively. MeasuredLA90 values as deemed attributable to the Power Station arebelow the day, evening and night limits of 55dB, 50dB and 45dBLA90 as set out in Guidance Note for Noise (NG4) [1].
The LAeq for the day time round one, two and threemeasurements was 56.0dB, 53.5dB and 53.4dB respectively. TheLAeq for the evening time measurement was 44.6dB and theLAeq for the night time round one and two measurements was48.0dB and 51.5dB respectively. The measured day time roundone and the measured night time round two LAeq levels areabove the day and night time noise limit values of 55dB and45dB LAeq as set out in Guidance Note for Noise (NG4) [1].However as mentioned above, the major contributor tomeasured LAeq levels during this measurement is considered tobe noise from passing cars. Due to the constant and steadynature of noise generated by the Power Station, the LA90 asdiscussed above can be referenced to determine the specificnoise level from the facility at this location. The LA90 for the daytime round one, two and three measurements was 33.5dB,33.8dB and 32.6dB respectively. The LA90 for the evening timemeasurement was 35.9dB and the LA90 for the night time roundone and two measurements was 34.1dB and 30.1dB respectively.Measured LA90 values as deemed attributable to the PowerStation are below the day, evening and night limits of 55dB,50dB and 45dB LA90 as set out in Guidance Note for Noise (NG4)[1].
Noise monitoring summary report
Have there been changes relevant to site noise emissions (e.g. plant or operational changes) since the last noisesurvey?
Table N1: Noise monitoring summary
If noise limits exceeded as a result of noise attributed to site activities, please choose the corrective action from the following options?
25
** please explain the reason for not taking action/resolution of noise issues?
In June 2016, Silencers were installed on the Hogger Relief Vents and the PRV. In July, an acoustic barrier was installed around the site of the Hogger. Thepurpose of these noise control measures was to reduce the tonal component that was been reportly heard during start-up process from this system. Sincethat date, Whitegate have had experienced no further complaints regards noise. Further noise assessments have been undertaken to demonstratereduction that there is no detected tonal or impulsive components by Allegro Acoustics in November 2016. Assessment included at end.
26
Resource Usage/Energy efficiency summary Lic No: P0830-02 Year 20162016
Additional information
1 16/12/2016
Site is only operationalsince 2010. Number of
plant modificationsmade to increaseefficency of unit.
2
SEAI - LargeIndustry EnergyNetwork (LIEN) No
3 Yes
Energy Use Previous year Current year
Production +/- %compared toprevious reportingyear**
EnergyConsumption +/- %vs overall siteproduction*
Total Energy Used (MWHrs) 4083113.456 5249870.036 28.58%Total Energy Generated (MWHrs) 1964552 2634129 34.08% -4.11%Total Renewable Energy Generated (MWHrs) 0 0 0Electricity Consumption (MWHrs) 44360 52724 18.85% -0.26%Fossil Fuels Consumption:
Heavy Fuel Oil (m3) 0 0 0.00%Light Fuel Oil (m3) 31.4 4.3 -86.31%
Natural gas (m3) 373780327.2 504478639.2 34.97%Coal/Solid fuel (metric tonnes) 0 0 0.00%
Peat (metric tonnes) 0 0 0.00%Renewable Biomass 0 0 0.00%
Renewable energy generated on site 0 0 0.00%* where consumption of energy can be compared to overall site production please enter this information as percentage increase or decrease compared to the previous reporting year.** where site production information is available please enter percentage increase or decrease compared to previous year
Water Emissions Water Consumption
Water useWater extractedPrevious year m3/yr.
Water extractedCurrent year m3/yr.
Production +/- %compared toprevious reportingyear**
EnergyConsumption +/- %vs overall siteproduction*
Volume Dischargedback toenvironment(m3yr):
Volume used i.e notdischarged toenvironment e.g.released as steamm3/yr Unaccounted for Water:
Groundwater 0 0 0.00%Surface water 0 0 0.00%Public supply 73000 77480 6.14% 15368 62112 Steam from hogger and blowdown tanksRecycled water 80617 105069 30.33% 0 0Total 153617 182549 18.83% 15368 62112* where consumption of water can be compared to overall site production please enter this information as percentage increase or decrease compared to the previous reporting year.** where site production information is available please enter percentage increase or decrease compared to previous year
Total Landfill Incineration Recycled OtherTable R3 Waste Stream Summary
Table R2 Water usage on site
When did the site carry out the most recent energy efficiency audit? Please list the recommendations in table 3 below
Is the site a member of any accredited programmes for reducing energy usage/water conservationsuch as the SEAI programme linked to the right? If yes please list them in additional information
Where Fuel Oil is used in boilers on site is the sulphur content compliant with licence conditions? Please state percentage inadditional information
Table R1 Energy usage on site
27
Resource Usage/Energy efficiency summary Lic No: P0830-02 Year 2016Hazardous (Tonnes) 87.463 2.48 84.983Non-Hazardous (Tonnes) 91.057 67.926 23.131
28
Resource Usage/Energy efficiency summary Lic No: P0830-02 Year 2016
Date of audit RecommendationsDescription ofMeasures proposed Origin of measures
Predicted energysavings % Implementation date Responsibility Completion date
Status andcomments
16/12/2016
Replacefluorescentlamps with LED Replace failures with LED Ongoing measure 50 Apr-15 Maintenance Ongoing
16/12/2016 Occupancy Control Lighting
Occupancy sensing beimplemented in electricalswitch rooms and theWaste Water TreatmentPlant Building Energy Audit 80 Under review EHS team Ongoing
16/12/2016Energymanagement
Monitoring of largeconsumers over time Energy Audit 5 Under review EHS team Ongoing
16/12/2016
Staff training inenergyawareness Staff training, Posters, etc Energy Audit 5 Under review EHS team Ongoing
Table R5: Power Generation: Where power is generated onsite (e.g. power generation facilities/food and drink industry)please complete the following informationUnit ID: WG1 Unit ID Unit ID Unit ID Station Total
Technology CCGTPrimary Fuel Natural GasThermal Efficiency 56.30%Unit Date of Commission 08/11/2010Total Starts for year 20Total Running Time 7743Total Electricity Generated (GWH) 2634.129House Load (GWH) 52.724KWH per Litre of Process Water 15.63123602KWH per Litre of Total Water used on Site 14.42970928
Table R4: Energy Audit finding recommendations
29
Complaints and Incidents summary template Lic No: P0830-02 Year 2016
Yes
Date Category Other type (please specify)
Brief description ofcomplaint (Free txt <20words)
Corrective action< 20words
Resolution status Resolution date Further information
08/04/2016 Noise
Local Neighbour re:noisefrom plant which occuredduring start up. Explainedour noise resolution plan
Installed silencers andacoustic barrier insummer of 2016
Complete 01/07/2016
Total complaintsopen at start ofreporting year 6Total newcomplaintsreceived duringreporting year 1Total complaintsclosed duringreporting year 1Balance ofcomplaints end ofreporting year 0
Yes
What is an incident
Table 2 Incidents summary
Date of occurrence Incident nature Location of occurrenceIncident category*pleaserefer to guidance Receptor Cause of incident
Othercause(pleasespecify)
Activity in progressat time of incident Communication Occurrence Corrective action<20 words
Preventativeaction <20 words Resolution status
Resolutiondate
Likelihood ofreoccurence
06/01/2016 Monitoring equipment offline Licenced discharge point (A2-1)1. Minor Air Plant or equipment issuesMonitoring equipment malfunction/maintenanceNormal activities EPA RecurringCEMS PC Replaced WithSpares available.
New PC purchasedand installed byService Contractor Complete Apr-16 Low
12/10/2016 Monitoring equipment offline Licenced discharge point (SW1)1. Minor Water Plant or equipment issuesMonitoring equipment malfunction/maintenanceNormal activities EPA New
A temporary arrangement hasbeen installed beside autosamplerlocation. A line has been takenfrom the sample pipe, and a hoseconnected that fills into a drumwhilst discharge taking place. Acomposite sample shall be takenfrom this drum and stored on siteas per normal requirements.
Extra spares kit forthe autosamplerordered, and oncethe spare kitarrived on site, therelevant partswere installed. Complete 25/10/2016 Low
SELECT SELECT SELECT SELECT SELECT SELECT SELECT SELECT SELECT SELECTTotal number ofincidents currentyear 2Total number ofincidents previousyear 4% reduction/increase 200%
Complaints
Have you received any environmental complaints in the current reporting year? If yes please complete summarydetails of complaints received on site in table 1 below
Table 1 Complaints summary
Incidents
Have any incidents occurred on site in the current reporting year? Please list all incidents for current reportingyear in Table 2 below
*For information on how to report and whatconstitutes an incident
30
WASTE SUMMARY Lic No: P0830-02 Year 2016
PRTR facility logon
Additional Information
1 No
2No
3
No
Table 1 Details of waste accepted onto your site for recovery, disposal or treatment (do not include wastes generated at your site, as these will have been reported in your PRTR workbook)EWC code Description of waste
acceptedPlease enter anaccurate and detaileddescription - whichapplies to relevant EWCcode
Quantity of wasteaccepted in currentreporting year (tonnes)
Reason forreduction/ increasefrom previousreporting year
Packaging Content (%)-only applies if thewaste has a packagingcomponent
European Waste Catalogue EWC codes European WasteCatalogue EWC codes
4 SELECT
5 SELECT6 SELECT7 Did your site experience any abatement system bypasses? If yes please detail them in table A3 below SELECT8 Do you maintain a sludge register on site? SELECT
Table 2 Waste type and tonnage-landfill only
Waste types permittedfor disposal
Authorised/licenced annual intake fordisposal (tpa)
Actual intake for disposal inreporting year (tpa)
Remaining licensedcapacity at end of
reporting year (m3) Comments
Table 3 General information-Landfill only
Total disposalarea occupiedby waste
Lined disposalarea occupied bywaste
Unlined area
SELECTUNIT
SELECT UNIT SELECT UNIT
Cell 8
SECTION A-PRTR ON SITE WASTE TREATMENT AND WASTE TRANSFERS TAB- TO BE COMPLETED BY ALL IPPC AND WASTE FACILITIES dropdown list click to see options
SECTION B- WASTE ACCEPTED ONTO SITE-TO BE COMPLETED BY ALL IPPC AND WASTE FACILITIES
Were any wastes accepted onto your site for recovery or disposal or treatment prior to recovery or disposal within the boundaries of your facility ?; (waste generated within yourboundaries is to be captured through PRTR reporting)
If yes please enter details in table 1 below
Did your site have any rejected consignments of waste in the current reporting year? If yes please give a brief explanation in the additional information
Was waste accepted onto your site that was generated outside the Republic of Ireland? If yes please state the quantity in tonnes in additional information
Licenced annualtonnage limit for your
site (totaltonnes/annum)
Source of waste accepted Quantity of waste accepted inprevious reporting year (tonnes)
Reduction/Increase overprevious year +/ - %
Disposal/Recovery ortreatment operation carriedout at your site and thedescription of this operation
Quantity ofwasteremaining onsite at theend ofreporting year(tonnes)
Comments -
SECTION C-TO BE COMPLETED BY ALL WASTE FACILITIES (waste transfer stations, Composters, Material recovery facilities etc) EXCEPT LANDFILL SITES
Is all waste processing infrastructure as required by your licence and approved by the Agency in place? If no please list waste processing infrastructure required onsite
Does your facility have relevant nuisance controls in place?
Accepted asbestos in reportingyear
Comments onliner type
SECTION D-TO BE COMPLETED BY LANDFILL SITES ONLY
Date landfilling commenced Inert or non-hazardousPredicted date tocease landfilling
Is all waste storage infrastructure as required by your licence and approved by the Agency in place? If no please list waste storage infrastructure required on site
Does your facility have relevant nuisance controls in place?
Area ID Date landfilling ceasedLicence permits
asbestosIs there a separate cell
for asbestos?Currently landfilling
Private or PublicOperated
31
WASTE SUMMARY Lic No: P0830-02 Year 2016
SECTION A-PRTR ON SITE WASTE TREATMENT AND WASTE TRANSFERS TAB- TO BE COMPLETED BY ALL IPPC AND WASTE FACILITIES dropdown list click to see optionsTable 4 Environmental monitoring-landfill only Landfill Manual-Monitoring StandardsWas meterologicalmonitoring incompliance withLandfill Directive (LD)standard in reportingyear +
Was leachate monitored in compliancewith LD standard in reporting year
Was Landfill Gas monitored incompliance with LD standardin reporting year
Was SW monitored incompliance with LDstandard in reportingyear
Have GW trigger levelsbeen established
Were emission limit values agreed withthe Agency (ELVs)
Was topographyof the sitesurveyed inreporting year
Has the statementunder S53(A)(5) ofWMA beensubmitted inreporting year Comments
.+ please refer to Landfill Manual linked above for relevant Landfill Directive monitoring standardsTable 5 Capping-Landfill only
Area uncapped* Area with temporary cap
SELECT UNIT SELECT UNIT
*please note this includes daily cover areaTable 6 Leachate-Landfill only
9 Is leachate from your site treated in a Waste Water Treatment Plant? SELECT10 Is leachate released to surface water? If yes please complete leachate mass load information below SELECT
Volume of leachate inreporting year(m3) Leachate (BOD) mass load (kg/annum)
Leachate (COD) mass load(kg/annum)
Leachate (NH4) massload (kg/annum)
Leachate (Chloride)mass load kg/annum Leachate treatment on-site
Specify type ofleachatetreatment Comments
Table 7 Landfill Gas-Landfill only
GasCaptured&Treated by
LFG System m3 Power generated (MW / KWh) Used on-site or to national grid
Was surface emissionsmonitoring performedduring the reporting
year? Comments
SELECT
Please ensure that all information reported in the landfill gas section is consistent with the Landfill Gas Survey submitted in conjunction with PRTR returns
Area with final cap to LDStandard m2 ha, a Area capped other
Area with waste thatshould be permanentlycapped to date under
licence What materials are used in the cap Comments
| PRTR# : P0830 | Facility Name : Bord Gais Energy Ltd | Filename : PRTR P0830_2016.xls | Return Year : 2016 | 6067 21/03/2017 12:21
Guidance to completing the PRTR workbook
Version 1.1.19REFERENCE YEAR 2016
1. FACILITY IDENTIFICATIONParent Company Name Bord Gais Energy Ltd
Facility Name Bord Gais Energy LtdPRTR Identification Number P0830
Licence Number P0830-02
Classes of ActivityNo. class_name
- Refer to PRTR class activities below
Address 1 Whitegate Power StationAddress 2 Whitegate (Corkbeg & Glanagow Townlands)Address 3Address 4
CorkCountry Ireland
Coordinates of Location -8.25029 51.8149River Basin District IESW
NACE Code 3521Main Economic Activity Manufacture of gas
AER Returns Contact Name Melissa MorrisseyAER Returns Contact Email Address [email protected]
AER Returns Contact Position EHS ManagerAER Returns Contact Telephone Number 0214656515
AER Returns Contact Mobile Phone Number 0860228844AER Returns Contact Fax Number
Production Volume 450.0Production Volume Units MW
Number of Installations 1Number of Operating Hours in Year 8760
Number of Employees 31User Feedback/Comments
Web Address
2. PRTR CLASS ACTIVITIESActivity Number Activity Name1(c) Thermal power stations and other combustion installations
3. SOLVENTS REGULATIONS (S.I. No. 543 of 2002)Is it applicable? No
Have you been granted an exemption ? NoIf applicable which activity class applies (as per
Schedule 2 of the regulations) ? NoIs the reduction scheme compliance route being
used ? No
4. WASTE IMPORTED/ACCEPTED ONTO SITE Guidance on waste imported/accepted onto siteDo you import/accept waste onto your site for on-
site treatment (either recovery or disposalactivities) ? No
This question is only applicable if you are an IPPC or Quarry site
PRTR Returns Workbook
4.1 RELEASES TO AIR Link to previous years emissions data | PRTR# : P0830 | Facility Name : Bord Gais Energy Ltd | Filename : PRTR P0830_2016.xls | Return Year : 2016 | 21/03/2017 12:218 12 20 20 28 28 6 7 6 6 6 6 12
SECTION A : SECTOR SPECIFIC PRTR POLLUTANTSPlease enter all quantities in this section in KGs
QUANTITYA2-1 A1-1
No. Annex II Name M/C/E Method Code Designation or Description Emission Point 1 Emission Point 2 T (Total) KG/YearA (Accidental)KG/Year
F (Fugitive)KG/Year
08 Nitrogen oxides (NOx/NO2) M ALT EN15267-3: 2007 434285.0 548.71 434833.71 0.0 0.002 Carbon monoxide (CO) M ALT EN15267-3: 2007 38213.2 0.0 38213.2 0.0 0.011 Sulphur oxides (SOx/SO2) M ALT EN15267-3: 2007 16228.8 2.31 16231.11 0.0 0.086 Particulate matter (PM10) C OTH USEPA Method 5B 2293.4 2.98 2296.38 0.0 0.003 Carbon dioxide (CO2) C ETS 960410664.0 0.0 960410664.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
SECTION B : REMAINING PRTR POLLUTANTSPlease enter all quantities in this section in KGs
QUANTITY
No. Annex II Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year F (Fugitive) KG/Year0.0 0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
SECTION C : REMAINING POLLUTANT EMISSIONS (As required in your Licence)Please enter all quantities in this section in KGs
QUANTITY
Pollutant No. Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year F (Fugitive) KG/Year0.0 0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
Additional Data Requested from Landfill operators
Landfill: Bord Gais Energy Ltd
Please enter summary data on thequantities of methane flared and / or utilised
additional_pollutant_no T (Total) kg/Year M/C/E Method CodeDesignation or
DescriptionFacility Total Capacity m3
per hourTotal estimated methane generation (as per
site model) 0.0 N/AMethane flared 0.0 0.0 (Total Flaring Capacity)
Methane utilised in engine/s 0.0 0.0 (Total Utilising Capacity)Net methane emission (as reported in Section A
above) 0.0 N/A
Method Used
For the purposes of the National Inventory on Greenhouse Gases, landfill operators are requested to provide summary data on landfill gas (Methane)flared or utilised on their facilities to accompany the figures for total methane generated. Operators should only report their Net methane (CH4)emission to the environment under T(total) KG/yr for Section A: Sector specific PRTR pollutants above. Please complete the table below:
Method Used
Method Used
RELEASES TO AIRPOLLUTANT METHOD
Method Used
POLLUTANT
RELEASES TO AIR
RELEASES TO AIRMETHOD
POLLUTANT METHOD
4.2 RELEASES TO WATERS Link to previous years emissions data | PRTR# : P0830 | Facility Name : Bord Gais Energy Ltd | Filename : PRTR P0830_2016.xls | Return Year : 2016 | 21/03/2017 12:218 9 17 17 25 28 6 7 6 6 6 6 28
SECTION A : SECTOR SPECIFIC PRTR POLLUTANTS Data on ambient monitoring of storm/surface water or groundwater, conducted as part of your licence requirements, should NOT be submitted under AER / PRTR Reporting as this only concerns Releases from your facilityPlease enter all quantities in this section in KGs
QUANTITYSW1 SW2
No. Annex II Name M/C/E Method Code Designation or Description Emission Point 1 Emission Point 2 T (Total) KG/YearA (Accidental)KG/Year
F(Fugitive)KG/Year
76 Total organic carbon (TOC) (as total C or COD/3) M ALT 0.0 56.149 56.149 0.0 0.013 Total phosphorus M ALT ISO 17025:2005 1.7 0.0 1.7 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
SECTION B : REMAINING PRTR POLLUTANTSPlease enter all quantities in this section in KGs
QUANTITY
No. Annex II Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year F (Fugitive) KG/Year0.0 0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
SECTION C : REMAINING POLLUTANT EMISSIONS (as required in your Licence)Please enter all quantities in this section in KGs
QUANTITY
Pollutant No. Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year F (Fugitive) KG/Year303 BOD M ALT ISO 17025:2005 135.79 135.79 0.0 0.0238 Ammonia (as N) M ALT ISO 17025:2005 9.67 9.67 0.0 0.0240 Suspended Solids M ALT ISO 17025:2005 71.13 71.13 0.0 0.0363 Total Dissolved Solids M ALT ISO 17025:2005 28042.0 28042.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
Method Used
POLLUTANTMethod Used
POLLUTANT
POLLUTANTRELEASES TO WATERS
Method Used
RELEASES TO WATERS
RELEASES TO WATERS
4.3 RELEASES TO WASTEWATER OR SEWER Link to previous years emissions data | PRTR# : P0830 | Facility Name : Bord Gais Energy Ltd | Filename : PRTR P0830_2016.xls | Return Year : 2016 |21/03/2017 12:218 8 16 16 6 6 6 6
SECTION A : PRTR POLLUTANTSPlease enter all quantities in this section in KGs
QUANTITY
No. Annex II Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year F (Fugitive) KG/Year0.0 0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
SECTION B : REMAINING POLLUTANT EMISSIONS (as required in your Licence)Please enter all quantities in this section in KGs
QUANTITY
Pollutant No. Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year F (Fugitive) KG/Year0.0 0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
OFFSITE TRANSFER OF POLLUTANTS DESTINED FOR WASTE-WATER TREATMENT OR SEWER
OFFSITE TRANSFER OF POLLUTANTS DESTINED FOR WASTE-WATER TREATMENT OR SEWER
Method Used
Method Used
POLLUTANT METHOD
POLLUTANT METHOD
4.4 RELEASES TO LAND Link to previous years emissions data | PRTR# : P0830 | Facility Name : Bord Gais Energy Ltd | Filename : PRTR P0830_2016.xls | Return Year : 2016 | 21/03/2017 12:218 8 16 16 6 6 6 6
SECTION A : PRTR POLLUTANTSPlease enter all quantities in this section in KGs
QUANTITY
No. Annex II Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
SECTION B : REMAINING POLLUTANT EMISSIONS (as required in your Licence)Please enter all quantities in this section in KGs
QUANTITY
Pollutant No. Name M/C/E Method Code Designation or Description Emission Point 1 T (Total) KG/Year A (Accidental) KG/Year0.0 0.0 0.0
* Select a row by double-clicking on the Pollutant Name (Column B) then click the delete button
POLLUTANT METHODMethod Used
RELEASES TO LAND
RELEASES TO LAND
POLLUTANT METHODMethod Used
5. ONSITE TREATMENT & OFFSITE TRANSFERS OF WASTE | PRTR# : P0830 | Facility Name : Bord Gais Energy Ltd | Filename : PRTR P0830_2016.xls | Return Year : 2016 | 21/03/2017 12:215 33 Please enter all quantities on this sheet in Tonnes 25
Quantity(Tonnes per
Year)
Haz Waste : Name andLicence/Permit No of Next
Destination Facility NonHaz Waste: Name andLicence/Permit No of
Recover/Disposer
Haz Waste : Address of NextDestination Facility
Non Haz Waste: Address ofRecover/Disposer
Name and License / Permit No. andAddress of Final Recoverer /
Disposer (HAZARDOUS WASTEONLY)
Actual Address of Final Destinationi.e. Final Recovery / Disposal Site(HAZARDOUS WASTE ONLY)
Transfer DestinationEuropean Waste
Code Hazardous Quantity T/Year Description of Waste
WasteTreatmentOperation M/C/E Method Used
Location ofTreatment Name and Licence / Permit No. of Recoverer / Disposer / Broker Address of Recoverer / Disposer / Broker Name and Address of Final Destination i.e. Final Recovery / Disposal Site (HAZARDOUS WASTE ONLY) Licence / Permit No. of Final Destination i.e. Final Recovery / Disposal Site (HAZARDOUS WASTE ONLY)
Within the Country 07 02 13 No 0.895 waste plastic D9 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
To Other Countries 08 01 11 Yes 0.11waste paint and varnish containing organicsolvents or other dangerous substances R1 M Weighed Abroad
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Recyfuel SA,DPA D 3200/61080/ RGPED/ 2008/AP-PU,Zonig Industirald'Hein,4480Engis,Liege,n/a,Belgium
Zonig Industiral d'Hein,4480Engis,Liege,n/a,Belgium
Within the Country 13 05 07 Yes 17.8 oily water from oil/water separators D9 M Weighed Offsite in Ireland Enva,WO184-1
Clonminam IndustrialEstate,.,Portlaois,Laois,Ireland
Enva,WO184-1,ClonminamIndustrialEstate,.,Portlaoise,Laois,Ireland
Clonminam IndustrialEstate,.,Portlaoise,Laois,Ireland
Within the Country 13 07 01 Yes 3.019 fuel oil and diesel D9 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Rilta EnvironmentalLimited,W0192-03,Block402,Grant's Drive,GreenogueBusiness Park,RathcooleDublin,Ireland
Grant's Drive,Block402,Greenogue BusinessPark,RathcooleDublin,Ireland
Within the Country 13 08 02 Yes 10.318 other emulsions D9 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Rilta EnvironmentalLimited,W0192-03,Block402,Grant's Drive,GreenogueBusiness Park,RathcooleDublin,Ireland
Grant's Drive,Block402,Greenogue BusinessPark,RathcooleDublin,Ireland
Within the Country 13 08 02 Yes 18.78 other emulsions D9 M Weighed Offsite in Ireland Enva,WO184-1
Clonminam IndustrialEstate,.,Portlaois,Laois,Ireland
Enva,WO184-1,ClonminamIndustrialEstate,.,Portlaoise,Laois,Ireland
Clonminam IndustrialEstate,.,Portlaoise,Laois,Ireland
Within the Country 15 01 02 No 0.466 plastic packaging R9 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Within the Country 15 01 06 No 3.525 mixed packaging R3 M Weighed Offsite in Ireland Greenstar Ltd,W0136-02
Sarsfield Court IndustrialEstate,Glanmire,Cork,n/a,Ireland
Within the Country 15 01 10 Yes 0.02packaging containing residues of orcontaminated by dangerous substances R3 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Rilta EnvironmentalLimited,W0192-03,Block402,Grant's Drive,GreenogueBusiness Park,RathcooleDublin,Ireland
Grant's Drive,Block402,Greenogue BusinessPark,RathcooleDublin,Ireland
To Other Countries 15 02 02 Yes 1.464
absorbents, filter materials (including oilfilters not otherwise specified), wipingcloths, protective clothing contaminated bydangerous substances R1 M Weighed Abroad
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Recyfuel SA,DPA D 3200/61080/ RGPED/ 2008/AP-PU,Zonig Industirald'Hein,4480Engis,Liege,n/a,Belgium
Zonig Industiral d'Hein,4480Engis,Liege,n/a,Belgium
To Other Countries 15 02 03 No 0.262
absorbents, filter materials, wiping clothsand protective clothing other than thosementioned in 15 02 02 R1 M Weighed Abroad
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Within the Country 16 02 14 No 0.062discarded equipment other than thosementioned in 16 02 09 to 16 02 13 R4 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
To Other Countries 16 03 03 Yes 0.018inorganic wastes containing dangeroussubstances D10 M Weighed Abroad
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
RZR Herten,.,ImEmscherbruch,11,Herten,45699,Germany
Im Emscherbruch,11,Herten,45699,Germany
To Other Countries 16 05 07 Yes 0.037discarded inorganic chemicals consisting ofor containing dangerous substances D10 M Weighed Abroad
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
RZR Herten,.,ImEmscherbruch,11,Herten,45699,Germany
Im Emscherbruch,11,Herten,45699,Germany
Within the Country 16 05 07 Yes 0.037discarded inorganic chemicals consisting ofor containing dangerous substances R1 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Rilta EnvironmentalLimited,W0192-03,Block402,Grant's Drive,GreenogueBusiness Park,RathcooleDublin,Ireland
Grant's Drive,Block402,Greenogue BusinessPark,RathcooleDublin,Ireland
Within the Country 16 06 04 No 0.618 alkaline batteries (except 16 06 03) R4 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
To Other Countries 16 10 01 Yes 0.05aqueous liquid wastes containing dangeroussubstances R1 M Weighed Abroad
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Recyfuel SA,DPA D 3200/61080/ RGPED/ 2008/AP-PU,Zonig Industirald'Hein,4480Engis,Liege,n/a,Belgium
Zonig Industiral d'Hein,4480Engis,Liege,n/a,Belgium
Within the Country 16 10 01 Yes 35.57aqueous liquid wastes containing dangeroussubstances D9 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Rilta EnvironmentalLimited,W0192-03,Block402,Grant's Drive,GreenogueBusiness Park,RathcooleDublin,Ireland
Grant's Drive,Block402,Greenogue BusinessPark,RathcooleDublin,Ireland
Within the Country 16 10 02 No 54.54aqueous liquid wastes other than thosementioned in 16 10 01 D9 M Weighed Offsite in Ireland Enva,WO184-1
Clonminam IndustrialEstate,.,Portlaois,Laois,Ireland
Within the Country 20 01 21 Yes 0.031fluorescent tubes and other mercury-containing waste R5 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Irish Lamp Recycling,WFP-KE-14-0072-01,WoodstockIndustrial Estate,.,Athy,Co.Kildare,Ireland
Woodstock IndustrialEstate,.,Athy,Co.Kildare,Ireland
Within the Country 20 01 30 No 0.264detergents other than those mentioned in 2001 29 R1 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Within the Country 20 01 38 No 3.42 wood other than that mentioned in 20 01 37 R3 M Weighed Offsite in Ireland Greenstar Ltd,W0136-02
Sarsfield Court IndustrialEstate,Glanmire,Cork,n/a,Ireland
Within the Country 20 01 40 No 4.08 metals R4 M Weighed Offsite in Ireland Greenstar Ltd,W0136-02
Sarsfield Court IndustrialEstate,Glanmire,Cork,n/a,Ireland
Within the Country 20 03 01 No 8.051 mixed municipal waste D5 M Weighed Offsite in Ireland Greenstar Ltd,W0136-02
Sarsfield Court IndustrialEstate,Glanmire,Cork,n/a,Ireland
Within the Country 20 03 07 No 12.96 bulky waste D5 M Weighed Offsite in Ireland Greenstar Ltd,W0136-02
Sarsfield Court IndustrialEstate,Glanmire,Cork,n/a,Ireland
Within the Country 20 01 08 No 0.8 biodegradable kitchen and canteen waste R3 M Weighed Offsite in Ireland Greenstar Ltd,W0136-02
Sarsfield Court IndustrialEstate,Glanmire,Cork,n/a,Ireland
Within the Country 15 01 02 No 0.054 plastic packaging R5 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Within the Country 15 02 03 No 1.06
absorbents, filter materials, wiping clothsand protective clothing other than thosementioned in 15 02 02 D9 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Within the Country 16 03 03 Yes 0.006inorganic wastes containing dangeroussubstances R1 M Weighed Offsite in Ireland
Lehane Environmental andIndustrial ServicesLtd.,NWCPO-08-04574-03
Unit 1-3 ,WallingstownIndustrial Estate,LittleIsland,Co. Cork,Ireland
Rilta EnvironmentalLimited,W0192-03,Block402,Grant's Drive,GreenogueBusiness Park,RathcooleDublin,Ireland
Grant's Drive,Block402,Greenogue BusinessPark,RathcooleDublin,Ireland
* Select a row by double-clicking the Description of Waste then click the delete button
Link to previous years waste dataLink to previous years waste summary data & percentage changeLink to Waste Guidance
Method Used
Allegro Acoustics Limited, Unit 2A Riverside, Tallaght Business Park, Tallaght, Dublin 24
Tel/Fax: +353 (0) 1 4140485
www.allegroacoustics.ie
GE Energy Ireland
Whitegate Power Station,
Fort Davis Road, Whitegate, Co. Cork
ENVIRONMENTAL NOISE MONITORING
Graball Bay
30 November 2016
Report Author: Stephen Kearney
Report: DC1468-03
Page | 2 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
REPORT CONTROL
Document Title: Environmental Noise Monitoring – Graball Bay
Project: Whitegate Power Station
Client: GE Energy Ireland
Job Number: DC1468
File Origin: Z:\Allegro Acoustics Live\Projects\DC1468\Reports
Report Author: Stephen Kearney BEng MIEI
Signed:
Issue Date Status Checked By Signed
1 30/11/2016 FINAL David Cawley BE MSc CEng MIEI MIOA
2
3
4
Page | 3 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
EXECUTIVE SUMMARY
Previous noise assessments carried out by Allegro Acoustics on behalf of Whitegate Power Station (DC1119 & DC1415) concluded that Whitegate Power Station is inaudible at Graball Bay when online and operating normally. However, the operation of the Hogger and Safety Relief Valve (SRV), which are used during the Power Station’s start up procedure were thought to result in noise annoyance at a residential dwelling in Graball Bay. To address this potential issue, acoustic attenuators were installed on the Hogger Exhaust (2) and SRV Outlet (1). In addition, an acoustic screen was installed to minimise the residual noise generation from these plant items towards Graball Bay. These measures were completed in July 2016.
To verify the effectiveness of these mitigation measures, noise monitoring was carried out at Graball Bay from 23:00 on the 22nd of November 2016 until 07:00 on the 23rd of November 2016. This specific period was chosen due to neutral weather conditions. Both the Hogger and SRV were activated during this time. Whitegate Power Station was otherwise online for the duration of the noise survey.
Measured noise data was analysed to ensure that there was no evidence of elevated noise levels, impulsive or tonal noise at Graball Bay while the Hogger and SRV were operating. The measured noise levels were also compared to the night time noise limits, outlined for Whitegate Power Station in Industrial Emissions Licence (IEL) PO830-02. The summarised results from this noise assessment are as follows:
Hogger
The Hogger was activated from 03:05 until 03:30 on the 23rd of November 2016. No elevated noise levels or tonal noise attributable to Whitegate Power Station was measured at Graball Bay during this time, thereby indicating that the Hogger is now inaudible at Graball Bay. This can be seen in the table and figure below.
Measurement Start Time Duration dB LAeq dB LA90 dB LAFMax
23/11/2016 02:30 00:30:00 37.2 34.9 46.0
23/11/2016 03:00 00:30:00 36.2 34.2 48.7
23/11/2016 03:30 00:30:00 36.4 34.3 47.0
Table: Noise levels measured at Graball Bay before, after and while the Hogger was operating. Measured noise levels while Hogger was operating are denoted in bold.
Figure: 1/3rd Octave Band Frequency Analysis of a measurement taken at Graball Bay while the Hogger was operating compared with noise measurements taken when it was off. As can be seen, there is no noticeable difference in the noise climate across the 1/3rd octave spectrum while the Hogger was operational (Blue), compared with while it was off (Yellow and Grey).
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Safety Relief Valve (SRV)
The SRV was activated from 03:10 to 03:11 and from 03:20 to 03:21 on the 23rd of November 2016. When the SRV operates, it emits quick blasts as it releases pressure from the Hogger system. The audibility of this process would be identifiable at Graball Bay by an increase in the LAFmax and LAeq statistical indicator while the SRV was operating. A previous noise assessment carried out by Allegro Acoustics identified that the SRV causes elevated sound energy at Graball Bay in the 1kHz to 8kHz frequency range.
The tables and graphs below show that there is no spike in the measured LAFmax or LAeq or in sound energy in the 1kHz to 8kHz frequency range at Graball Bay while the SRV is operating. This indicates that the SRV is inaudible at Graball Bay.
Start Time Duration dB LAeq dB LA90 dB LAFMax
23/11/2016 03:10 00:01:00 35.7 34.0 38.3
23/11/2016 03:20 00:01:00 38.0 36.7 40.4
Table: Noise levels measured at Graball Bay while the SRV was operating.
Figure: LAFmax noise levels measured at Graball Bay during the noise survey.
Figure: Breakdown of the LAeq time history for the 30 minute measurement taken while the SRV was activated, the periods were the SRV is operating are marked in green.
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Figure: 1/3rd Octave Band Frequency Analysis of a measurement taken at Graball Bay while the SRV was activated compared with noise measurements taken when the SRV was not operating.
Industrial Emissions Licence
The measured noise levels throughout the noise survey were compared with the 45dB LAeq night time noise limit outlined for the Power Station in IEL PO830-02. The graphs below show that Whitegate Power Station remained below this 45dB night time noise limit at all times throughout the noise survey and that there was no evidence of tonal noise attributable to Whitegate Power Station.
Allegro Acoustics therefore considers Whitegate Power Station to be demonstrating compliance with Industrial Emission Licence PO830-02.
Figure: LAeq and LA90 noise levels measured at Graball Bay during the noise survey. The night time noise limit of 45dB LAeq is marked in green.
Page | 6 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
Figure: Measured Leq and L90 noise levels at Graball Bay in each 1/3rd Octave Band between 12.5Hz and 20kHz. As detailed in Section 3, the elevated sound energy levels observed between 31.5Hz and 50Hz are considered to be attributable to an oil fuelled boiler which is located at the side of a nearby residence and are not thought to relate in any way to Whitegate Power Station.
Page | 7 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
TABLE OF CONTENTS
1 INTRODUCTION ............................................................................................................................... 8
1.1 Description of Major Noise Sources ....................................................................................... 8
1.2 Description of Terminology..................................................................................................... 9
2 METHODOLOGY .............................................................................................................................. 9
2.1 Noise Monitoring Location ..................................................................................................... 9
2.2 Noise Measurement Instrumentation .................................................................................. 10
2.3 Assessment Criteria .............................................................................................................. 10
2.4 Determination of Tonal Character ........................................................................................ 11
2.5 Meteorological and Local Environmental Conditions ........................................................... 11
3 RESULTS......................................................................................................................................... 11
3.1 Hogger ................................................................................................................................... 12
3.2 Safety Relief Valve (SRV) ....................................................................................................... 12
3.3 Industrial Emissions Licence ................................................................................................. 16
4 CONCLUSION ................................................................................................................................. 17
5 REFERENCES ................................................................................................................................. 17
APPENDICES
Appendix A - Noise Measurement Data
Appendix B - Weather Data
Appendix C - Calibration Certificate
Page | 8 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
1 INTRODUCTION
Allegro Acoustics was retained by Whitegate Power Station to undertake environmental noise monitoring to verify the effectiveness of noise mitigation measures undertaken by the Power Station to the Hogger Exhaust and SRV Outlet in response to a noise nuisance complaint from a resident in Graball Bay.
Previous noise assessments carried out by Allegro Acoustics on behalf of Whitegate Power Station (DC1119 & DC1415) concluded that the Power Station is inaudible at Graball Bay when online and operating normally. However, the operation of the Hogger and Safety Relief Valve (SRV), which are used during the Power Station’s start up procedure were thought to result in noise annoyance at a residential dwelling in Graball Bay. To address this potential issue, acoustic attenuators were installed on the Hogger Exhaust (2) and SRV Outlet (1). In addition, an acoustic screen was installed to minimise the residual noise generation from these plant items towards Graball Bay. These measures were completed in July 2016.
To verify that potential noise from the Hogger and SRV has been successfully mitigated, continuous noise monitoring was carried out at Graball Bay from 23:00 on the 22nd of November 2016 until 06:30 on the 23rd of November 2016.
The Power Station was online throughout this noise survey and the Hogger and SRV were activated during the noise survey. All noise mitigation measures at Whitegate Power Station pertaining to the Hogger and SRV were finished and in place prior to the noise survey taking place.
The measured noise data at Graball Bay was analysed to ensure that there was no evidence of elevated noise levels, impulsive or tonal noise at Graball Bay while the Hogger and SRV were operating. The measured noise levels were also analysed to ensure that Whitegate Power Station is demonstrating compliance with the night time noise limit values, outlined for the Power Station in Industrial Emissions Licence (IEL) PO830-02.
1.1 Description of Major Noise Sources
The noise sources considered as part of this assessment are described below:
Safety Relief Valve Outlet – this outlet was previously located at a height of 23m above ground level between the ACC Fan enclosure and Turbine Building. This outlet has been relocated and is now at a height of 17m. Noise emanates from this outlet if the steam pressure in the Hogger line gets too high and the valve must open to reduce pressure upon the line. When this valve opens, steam can be seen and heard rapidly “blasting” from the outlet. When active, this is the most dominant noise source at the Power Station. This element only operates occasionally and for short durations (between 15s and 45s).
Hogger Exhaust – these are the two outlets of the Hogger system visible at either end of a C duct located above the Hogger silencer. The Hogger Exhaust pipes are also located between the ACC fan enclosure and Turbine Building and are at a height of 17m above ground level. While the Hogger is in full operation, there is a constant noise emitted from both of these pipes. There is also an occasional “whine” from both pipes and steam can typically be seen and heard “popping” out of both exhaust pipes. This has been found to be the second most dominant noise source at the Power Station.
To mitigate these items, Allegro Acoustics have designed and overseen the installation of noise mitigation measures to attenuate the Hogger and SRV. These mitigation measures comprised of the installation of an acoustic screen at the Hogger and SRV in addition to acoustic attenuators fitted to the Hogger Exhaust (2) and SRV Outlet (1).
Page | 9 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
1.2 Description of Terminology
Noise indicators referenced throughout this report are defined below.
LAeq: Equivalent Continuous A-weighted Sound Level. The continuous steady noise level, which would have the same total A-weighted acoustic energy as the real fluctuating noise measured over the same period of time.
LA90: The A-weighted noise level that is equalled or exceeded for 90% of the measurement period. This is typically used to indicate the background noise level at a location. This indicator can also be used to determine the specific noise level attributable to a constant noise source at a location.
LAFmax: The A-weighted maximum noise level that is measured throughout a noise measurement. The impulsive noise previously observed to emanate from the SRV can be quantified and identified using the LAFMax.
1/3rd Octave Band Analysis: Frequency analysis of sound such that the frequency spectrum is sub divided into bands of one third of an octave each. This analysis can be used to identify a tonal component to audible sound (note such as a hum, whine or whistle). The “whine” previously observed to emanate from the Hogger can be quantified and identified using 1/3rd octave band analysis.
2 METHODOLOGY
2.1 Noise Monitoring Location
Noise monitoring was carried out between 23:00 on the 22nd of November 2016 and 06:30 on the 23rd of November 2016 at a residential dwelling in Graball Bay. This monitoring location is situated approximately 2.5km from Whitegate Power Station across the Cork Bay and is denoted in Figure 1 below as monitoring location N1.
The sound level analyser was located in the front garden of the property and oriented towards the power station. The microphone was positioned at a height of approximately 2m. Otherwise, the microphone was located at least 3.5m away from any sound reflecting surfaces. A windshield was placed on the microphone to reduce any wind interference during measurements.
Figure 1: Satellite image showing Whitegate Power Station and noise monitoring location N1 at Graball Bay.
Page | 10 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
2.2 Noise Measurement Instrumentation
Noise measurements were taken using a Cirrus CR:171B Sound Level Meter (SLM) which measures simultaneously in every 1/3rd octave frequency band from 12.5Hz to 20 kHz. The Sound Level Meter was calibrated before and after noise measurements were carried out using a Bruel and Kjaer Type 4231 acoustic calibrator. Calibration certification, SLM serial number, calibrator used and microphone serial number for the SLMs are presented in the factory calibration certificate as displayed in Appendix C. The Cirrus CR:171B is a Class 1 instrument in accordance with IEC 61672 and IEC 60651. The Time Weighting used was Fast and the Frequency Weighting was A-weighted as per IEC 61672.
2.3 Assessment Criteria
Measured noise levels are assessed herein with specific reference to Condition 4.5 and Schedule B.4 of Whitegate Power Station’s Industrial Emissions License P0830-02. Condition 4.5 and Schedule B.4 are detailed below.
Figure 2: Excerpt taken from the IE license for the Power Station (PO830-02) showing Condition 4.5.
Figure 3: Excerpt taken from the IE license for the Power Station (PO830-02) showing Schedule B.4.
Cognisance is also paid in this assessment to the recommended noise limit criteria outlined in Guidance Note for Noise (NG4) [1]. The NG4 document [1] outlines the following recommended noise limits for residential or otherwise sensitive areas:
Daytime Noise Criterion, dB LAr,T (07:00 to 19:00hrs): 55dB
Evening Noise Criterion, dB LAr,T (19:00 to 23:00hrs): 50dB
Night-time Noise Criterion, dB LAeq,T (23:00 to 07:00hrs): 45dB
For the purposes of this noise survey, the noise levels measured at Graball Bay have been compared to the night time noise limit of 45dB LAeq as this is the most stringent noise limit for the Power Station.
It is worth noting that the LAeq statistical noise indicator takes all audible noise into consideration, the measured LAeq noise level can often include the noise generated by other sources such as passing road traffic and localised people movements.
In the case of Whitegate Power Station which when online, generally operates as a constant noise source without any intermittent or impulsive characteristics, the LA90 statistical indicator may be considered representative of the specific noise level from the facility and should also be compared to the 45dB night time noise limit outlined in the Power Station’s IEL and in Guidance Note for Noise (NG4) [1].
Page | 11 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
The LA90 statistical indicator is recognised as being representative of the background noise level at a location and is defined as follows:
The noise level that is equalled or exceeded for 90% of the time – the L90 statistical noise indicator is an indicator of the constant background noise level at any location.
2.4 Determination of Tonal Character
Both Guidance Note for Noise (NG4) [1] and Whitegate Power Station’s IEL state that there should be no clearly audible tonal or impulsive component from the Power Station at the nearest residential or otherwise noise sensitive receptor.
Impulsive noise can be identified using the LAFmax statistical indicator and tonal noise can be be identified by determining if one particular 1/3rd octave frequency band exceeds both its adjacent 1/3rd octave frequency bands by a significant number of decibels. The following guidelines are outlined in Guidance Note for Noise (NG4) [1] to conclude a tonal characteristic to the specific noise emanating from a facility:
Referring to the sound pressure levels in each 1/3rd octave band: The appropriate level differences vary with frequency. They should be greater than or equal to the following values in both adjacent 1/3rd octave bands:
15dB in low-frequency 1/3rd octave bands (25Hz to 125Hz)
8dB in middle-frequency bands (160Hz to 400Hz)
5dB in high-frequency bands (500Hz to 10,000Hz)
2.5 Meteorological and Local Environmental Conditions
Weather data for the monitoring period has been obtained from the Met Éireann weather station at Cork Airport. This monitoring station shows that weather conditions were suitable for the taking of noise measurements as there was no significant rainfall and that wind speeds generally remained below 5m/s throughout the monitoring period. A summary of the weather data for the monitoring period is available to view in Appendix B.
3 RESULTS
Noise monitoring was carried out while the Power Station was online and operating as normal. Both the Hogger and SRV were manually activated during the noise survey. Table 1 below show the times that the Hogger and SRV were operating. A full table of Leq and L90 1/3rd Octave data for each measurement is available to view in Appendix A.
Time Power Station Status Operation
03:05 Online Hogger On
03:10 Online SRV Open
03:11 Online SRV Close
03:20 Online SRV Open
03:21 Online SRV Close
03:30 Online Hogger Off
Table 1: Times that the Hogger and SRV were operating during the noise survey.
Page | 12 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
3.1 Hogger
Table 2 below shows the measured noise levels before, after and while the Hogger was operating, these noise levels can be compared with each other to show that the Hogger does not result in an increase or significant change in LAeq, LA90 or LAFMax noise levels at monitoring location N1 at Graball bay. This indicates that the Hogger is likely to be inaudible at Graball Bay.
Measurement Start Time Duration dB LAeq dB LA90 dB LAFMax
23/11/2016 02:30 00:30:00 37.2 34.9 46.0
23/11/2016 03:00 00:30:00 36.2 34.2 48.7
23/11/2016 03:30 00:30:00 36.4 34.3 47.0
Table 2: Noise levels measured at Graball Bay while the Hogger was operating. Measured noise levels while Hogger was operating is denoted in bold.
Figure 4 below show the measured noise level in each 1/3rd Octave frequency band while the Hogger was operating and also compares the measured noise level in each 1/3rd Octave frequency band while the Hogger was operating with corresponding measured noise data from when the Hogger was not operating.
Figure 4 shows that there were no tonal components measured while the Hogger was operating. This graph also shows that the Hogger operating does not result in an increase or significant change in noise levels in any of the 1/3rd Octave bands when compared to corresponding measurements taken while the Hogger was off. This indicates that the previously identified “whine” from the Hogger is likely to be inaudible at Graball Bay.
Figure 4: 1/3rd Octave Band Frequency Analysis of a measurement taken at N1 while the Hogger was operating compared with noise measurements taken when the Hogger was not operating.
3.2 Safety Relief Valve (SRV)
Table 1 above shows that the SRV was operating between 03:10 and 03:11 and between 03:20 and 03:21 on the 23/11/2016. Table 3 below shows the measured LAeq, LA90 and LAFMax noise level as concluded using NoiseTools Software by Cirrus Research for the specific 1 minute period during which the SRV was operating.
Start Time Duration dB LAeq dB LA90 dB LAFMax
23/11/2016 03:10 00:01:00 35.7 34.0 38.3
23/11/2016 03:20 00:01:00 38.0 36.7 40.4
Table 3: Noise levels measured at Graball Bay (N1) while the SRV was operating.
Page | 13 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
When the SRV operates, it emits quick blasts as it releases pressure from the Hogger system. If noise from the SRV was audible at Graball Bay, this would appear as an increase in LAFMax noise levels at N1. The measured LAFMax values throughout the entire measurement period are shown in Figure 5 below. As can be seen in Figure 5, the operation of the SRV does not give rise to elevated LAFMax values. This indicates that the impulsive, instantaneous sound generated by the SRV has not been measured at Graball Bay and that the SRV is likely inaudible at Graball Bay.
Figure 5: LAFmax noise levels measured at Graball Bay (N1) during the noise survey.
The blasts from the SRV would also appear as large spikes in the LAeq time history for the measurement. Figure 6 below shows that there are no significant or sudden spikes in the measured LAeq during the periods where the SRV was operating. The periods were the SRV is operating are marked in green. The large spike shown in Figure 6 at 03:25 is discussed below.
Figure 6: Breakdown of the LAeq time history for the 30 minute measurement taken while the SRV was activated, the periods were the SRV is operating are marked in green.
Page | 14 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
A large spike in measured LAeq can be seen in Figure 6 above at 03:25. Figure 7 below shoes a zoomed in view of the spike in measured LAeq. It can be seen that this elevation in LAeq lasts for approximately 10 seconds. During this time, the measured LAeq increases over approximately 5 seconds, reaches its maximum and then and then decreases over approximately 5 seconds. Based on this pattern, it is highly likely that this spike in LAeq is attributable to vehicular movement at the crossroad near N1. Importantly, there was no specific Hogger or SRV activity during this time and the noise level pattern (gradual rise, peak, gradual decay) does not correlate with any noise source at Whitegate Power Station.
Figure 7: Zoomed in view of the elevated LAeq seen in Figure 6 above at 03:25.
A previous noise survey carried out by Allegro Acoustics (DC1415-01) found that the operation of the SRV was identifiable at monitoring location N1 in Leq data at frequencies between 1kHz and 8kHz. This is shown in Figure 8 below.
Figure 8: Extract from a previous report (DC1415) issued by Allegro Acoustics showing elevated sound energy in the 1kHz to 8kHz range while the SRV was activated.
Page | 15 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
By comparing Figures 8, 9 and 10 it can be seen that following the implementation of mitigation measures, the previously identifiable elevated noise levels between the 1kHz to 8kHz bands, are no longer identifiable.
Figures 9 and 10 also compares the measured noise level in each 1/3rd Octave frequency band while the SRV was operating with corresponding measured noise data from when the SRV was not operating. Figures 7 and 8 show that the SRV operating does not result in an increase or significant change in noise levels in any of the 1/3rd Octave bands when compared to corresponding measurements taken while the SRV was off. This also indicates that the SRV is likely to be inaudible at Graball Bay.
Figure 9: 1/3rd Octave Band Frequency Analysis of a measurement taken at N1 while the SRV was activated compared with noise measurements taken when the SRV was not operating.
Figure 10: 1/3rd Octave Band Frequency Analysis of a measurement taken at N1 while the SRV was activated compared with noise measurements taken when the SRV was not operating.
Page | 16 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
3.3 Industrial Emissions Licence
Table 4 and Figure 11 below show the measured noise levels recorded at monitoring location N1 at Graball Bay during the noise survey while Whitegate Power Station was online and operating as normal. This table and graph show that both the measured LAeq and LA90 remain below the night time noise limit of 45dB outlind in IE Licence PO830-02 throughout the noise survey.
Time Duration dB LAeq dB LA90 dB LAFMax
22/11/2016 23:00 00:30:00 37.0 35.4 46.0
22/11/2016 23:30 00:30:00 35.0 33.2 44.9
23/11/2016 00:00 00:30:00 34.3 32.7 44.5
23/11/2016 00:30 00:30:00 33.9 31.7 47.1
23/11/2016 01:00 00:30:00 35.0 31.8 43.8
23/11/2016 01:30 00:30:00 40.3 35.3 50.1
23/11/2016 02:00 00:30:00 34.6 31.8 52.1
23/11/2016 02:30 00:30:00 37.2 34.9 46.0
23/11/2016 03:00 00:30:00 36.2 34.2 48.7
23/11/2016 03:30 00:30:00 36.4 34.3 47.0
23/11/2016 04:00 00:30:00 38.5 35.2 55.0
23/11/2016 04:30 00:30:00 40.7 38.5 47.4
23/11/2016 05:00 00:30:00 40.2 36.6 46.8
23/11/2016 05:30 00:30:00 38.4 35.4 45.1
23/11/2016 06:00 00:30:00 40.1 37.2 47.9
23/11/2016 06:30 00:30:00 39.8 37.4 46.7
Table 4: Noise levels measured at Graball Bay (N1) during the noise survey. Measured noise levels while the Hogger and SRV were activated are marked in bold.
Figure 11: LAeq and LA90 noise levels measured at Graball Bay (N1) during the noise survey. The night time noise limit of 45dB is marked in green.
Figure 12 below displays the measured Leq and L90 noise levels in each 1/3rd Octave Band between 12.5Hz and 20kHz for four measurements chosen at random from the measured noise data. These graph shows that were no tonal components measured at monitoring location N1. A full table of Leq and L90 1/3rd Octave data for each measurement is available to view in Appendix A.
Page | 17 DC1468-03 Whitegate Power Station 30/11/2016 Environmental Noise Monitoring
It is worth nothing however that in some of the 1/3rd Octave graphs presented in Figure 4 below and in Appendix A, elevated sound energy is present between 31.5Hz and 50Hz. This sound energy is considered to be attributable to a residential oil boiler operating on an intermittent basis close to monitoring location N1. Previous noise surveys carried out at Whitegate Power Station (DC1119) did not find any sources of elevated sound energy at frequencies between 31.5Hz and 50Hz and this elevated sound energy is not considered to be attributable to Whitegate Power Station.
Figure 12: Measured Leq and L90 noise levels at N1 in each 1/3rd Octave Band between 12.5Hz and 20kHz.
4 CONCLUSION
This noise survey has demonstrated that the noise mitigation measures carried out on the Hogger Exhaust and SRV Outlet have successfully reduced the noise emanating from the these items sufficiently so that they are no longer audible at Graball Bay and therefore should not result in any annoyance to residents living in Graball Bay.
As the measured noise levels during the survey remained below the the night time noise limit of 45dB LAeq outlind in IE Licence PO830-02 and that there is otherwise no evidence of tonality or impulsivity that is attributable to Whitegate Power Station, Whitegate Power Station is considered by Allegro Acoustics to be demonstrating compliance with the noise limits outlined in IE Licence PO830-02.
5 REFERENCES
[1] ENVIRONMENTAL PROTECTION AGENCY, Guidance Note for Noise: License Applications, Surveys and Assessments in Relation to Scheduled Activities (NG4) (2016)
[2] INTERNATIONAL STANDARDS ORGANISATION, ISO 1996-01, Acoustics – Description,
Measurement and Assessment of Environmental Noise – Part 1: Basic Quantities and Assessment Procedures (2016)
www.allegroacoustics.ie
Appendix A
Noise Measurement Data
MyCount
Elapsed LAeq LA90 LAMax
Time dB dB dBN1 23/11/2016 03:00 00:30:00 36.2 34.2 48.7N1 23/11/2016 03:10 00:01:00 35.7 34.0 38.3N1 23/11/2016 03:20 00:01:00 38.0 36.7 40.4N1 22/11/2016 23:00 00:30:00 37.0 35.4 46.0N1 22/11/2016 23:30 00:30:00 35.0 33.2 44.9N1 23/11/2016 00:00 00:30:00 34.3 32.7 44.5N1 23/11/2016 00:30 00:30:00 33.9 31.7 47.1N1 23/11/2016 01:00 00:30:00 35.0 31.8 43.8N1 23/11/2016 01:30 00:30:00 40.3 35.3 50.1N1 23/11/2016 02:00 00:30:00 34.6 31.8 52.1N1 23/11/2016 02:30 00:30:00 37.2 34.9 46.0N1 23/11/2016 03:00 00:30:00 36.2 34.2 48.7N1 23/11/2016 03:30 00:30:00 36.4 34.3 47.0N1 23/11/2016 04:00 00:30:00 38.5 35.2 55.0N1 23/11/2016 04:30 00:30:00 40.7 38.5 47.4N1 23/11/2016 05:00 00:30:00 40.2 36.6 46.8N1 23/11/2016 05:30 00:30:00 38.4 35.4 45.1N1 23/11/2016 06:00 00:30:00 40.1 37.2 47.9N1 23/11/2016 06:30 00:30:00 39.8 37.4 46.7
Elapsed LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeq LZeqTime 12.5Hz 16Hz 20Hz 25Hz 31.5Hz 40Hz 50Hz 63Hz 80Hz 100Hz 125Hz 160Hz 200Hz 250Hz 315Hz 400Hz 500Hz 630Hz 800Hz 1 kHz 1.25 kHz 1.6 kHz 2 kHz 2.5 kHz 3.15 kHz 4 kHz 5 kHz 6.3 kHz 8 kHz 10 kHz 12.5 kHz 16 kHz 20 kHz
N1 23/11/2016 03:00 00:30:00 47.1 44.6 46.4 48.7 42.8 45.7 50.9 43.4 36.7 35.5 32.4 34.8 35.1 33.5 35.8 31.7 30.7 28.7 26.2 24.3 20.7 16.9 13 10.1 9 9.7 11.7 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 03:10 00:01:00 44.5 43.8 43.1 42.3 39.9 40.3 46.6 42.3 35.8 35.0 32.2 33.9 33.9 32.8 35.2 31.2 30.3 28.3 26.1 24.0 20.7 16.8 13.1 9.9 8.9 9.5 11.1 11.1 12.1 13.1 14.7 16.7 19.9N1 23/11/2016 03:20 00:01:00 46.6 42.9 42.8 42.3 41.1 39.7 46.0 43.1 36.4 35.1 33.8 35.5 36.1 35.5 37.2 33.8 33.8 30.8 28.1 26.2 22.1 18.3 13.9 10.1 8.9 9.6 11.8 11.1 12.1 13.1 14.7 16.7 19.9N1 22/11/2016 23:00 00:30:00 53.9 51.5 48.7 46.5 44.6 40.4 48.3 44.7 37 36.1 33.6 34.2 33.8 33.2 35.5 32.3 31.1 30.1 28.4 26.5 23.8 20.3 16.2 12.9 11.5 11.2 13.3 12 12.8 13.7 15.3 17.3 20.5N1 22/11/2016 23:30 00:30:00 51.1 48.7 45.8 43.8 42.3 37.8 48.7 42.2 35.2 35.1 31.8 33 32.7 30.9 33 29.8 29.1 28 26.5 24.8 22.2 18.8 15.1 11.9 10 10.3 12.1 11.5 12.4 13.2 14.8 16.8 20N1 23/11/2016 00:00 00:30:00 49.8 46.5 44.3 45.2 49.2 40 48.8 42.5 38.3 35.5 32.5 33.9 32.8 31.4 32.9 29.4 28.4 26.7 24.8 22.9 20.1 16.6 13.4 10.9 9.5 10.2 12 11.3 12.3 13.2 14.7 16.7 20N1 23/11/2016 00:30 00:30:00 44.5 43.5 42.5 54.6 63.1 46.7 47.1 43.4 40.4 36.2 32.8 33 31.6 29.9 31.2 28 27.4 26.2 24.1 22.7 20 16.7 13.4 10.7 9.4 9.9 12 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 01:00 00:30:00 45.2 42.2 42.4 45.7 49.1 47.3 48 43.4 40 38.4 35.7 34.8 34.3 32.3 33.5 30.5 29.3 27.5 24.7 22.6 19 14.9 10.9 9 8.8 9.8 12 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 01:30 00:30:00 46.6 44.6 45.9 47.1 50.6 59.6 58.7 48.8 45.5 48.4 46 38.9 38.8 36.9 37.2 33.5 32.7 31.8 30.1 28.4 25.3 21.3 16.6 11.8 9.4 9.8 11.9 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 02:00 00:30:00 44.2 42.6 40.4 39.3 39.5 47.5 52.2 42.1 38.9 38.6 34.4 36.2 36.7 32.5 33.5 27.4 27.8 26.3 22.9 21.1 18.2 14.7 12.5 10.2 9.3 10 11.9 11.3 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 02:30 00:30:00 47 45 43.8 43.1 42.7 51.4 54.7 44.4 40.4 41.3 38.2 38.1 38.3 36 36.9 31.5 30.4 28.2 25.1 23 19.4 15.5 12.4 10.1 9.1 9.8 11.9 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 03:00 00:30:00 47.1 44.7 46.4 48.7 42.8 45.7 50.9 43.4 36.7 35.5 32.4 34.8 35.1 33.5 35.8 31.6 30.7 28.7 26.2 24.3 20.7 16.9 13 10.2 9 9.7 11.7 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 03:30 00:30:00 47.4 44.5 43.7 44.2 44.2 41.7 47.3 43 36.3 34.6 31.9 35.2 36 34.2 36.1 31.9 30.5 28.6 26.5 24.5 20.8 16.8 12.9 10.5 9.2 9.7 11.7 11.2 12.2 13.1 14.7 16.7 19.9N1 23/11/2016 04:00 00:30:00 51.2 48.1 46.5 47.1 48.1 43.5 48.1 46 37.8 37 34.7 38.1 39.6 38.5 37.8 34.7 32.1 29.9 27.7 25.4 21.1 16.7 12.6 9.9 9.2 10 11.9 11.4 12.4 13.3 15 16.9 20.2N1 23/11/2016 04:30 00:30:00 51.8 49.3 48.8 52 51.9 47.1 51 51 41.3 40 37.5 40.5 40.3 39.8 40.1 37 35 32.2 30.1 27.2 22.6 17.6 12.4 9.7 9.2 10 11.7 11.7 12.5 13.2 14.8 16.8 20N1 23/11/2016 05:00 00:30:00 51.1 48.6 48.6 51.5 51.3 46.6 50.9 50.6 41.5 39.5 36.8 40.1 39.8 39.4 39.5 36.2 34.5 31.9 29.9 27 22.5 17.7 12.7 10 9.1 9.8 11.7 12.2 12.8 13.2 14.8 16.8 20N1 23/11/2016 05:30 00:30:00 49.2 46.1 45.6 47 47.8 43.5 48.7 46.5 39.3 37.1 35.5 37.9 38.4 37 37.8 34.3 32.4 30.4 28.2 25.8 21.2 16.4 11.5 9.6 9.1 10 12.9 12.4 12.9 13.1 14.7 16.7 20N1 23/11/2016 06:00 00:30:00 50.1 46.9 47.1 48.3 49.5 45.1 49.7 48 40.2 38.8 37.4 40.3 40.2 39.1 39.1 36.4 33.8 31.8 29.9 27.7 23 18.4 13.4 10.4 9.6 10.3 12.7 12.4 12.7 13.1 14.7 16.7 19.9N1 23/11/2016 06:30 00:30:00 49.2 46.4 46.9 49 51.3 46.6 50.5 50.3 41 39 36.6 38.5 38.9 38.6 39.1 36.1 34.1 31.5 29.4 26.9 22.9 19.5 14.4 11.4 10 10.3 11.8 12 12.6 13.1 14.7 16.7 19.9
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SLM:SLM Serial Number:SLM Factory Calibration Date:
Testing Agency:Testing Operator:
Free FieldFast
Operation
Hogger & SRVHogger & SRV
Hogger
Location Start Time
Start Time
Hogger Hogger & SRV
Sound Field Correction:Time Weighting:
Allegro AcousticsStephen Kearney BEng MIEI
Cirrus CR:171BG06677707/01/2016
Noise Measurement DataLocation Operation
1/3rd Octave dB Leq Measurement Data
Hogger & SRV
Power Station OnlinePower Station OnlinePower Station OnlinePower Station Online
Elapsed LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90 LZ90Time 12.5Hz 16Hz 20Hz 25Hz 31.5Hz 40Hz 50Hz 63Hz 80Hz 100Hz 125Hz 160Hz 200Hz 250Hz 315Hz 400Hz 500Hz 630Hz 800Hz 1 kHz 1.25 kHz 1.6 kHz 2 kHz 2.5 kHz 3.15 kHz 4 kHz 5 kHz 6.3 kHz 8 kHz 10 kHz 12.5 kHz 16 kHz 20 kHz
N1 23/11/2016 03:00 00:30:00 40.8 38.7 39 37.8 36.8 36.8 43 38.6 33 31.5 29.7 31.9 32.1 30.5 32.5 28.9 28.2 26.7 24.3 22.5 18.9 14.9 10.9 8.7 8.5 9.3 10.4 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 03:10 00:01:00 40.5 39.0 38.5 38.2 35.5 36.0 42.6 38.8 33.2 31.9 29.9 32.1 31.5 30.5 32.0 29.2 28.4 27.0 24.7 22.5 19.0 14.9 10.9 8.8 8.5 9.3 10.3 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 03:20 00:01:00 42.1 38.4 38.0 37.5 36.7 36.3 42.1 39.5 33.9 32.5 31.2 33.3 33.9 33.4 35.1 31.4 30.9 28.8 26.6 24.7 20.2 16.2 12.2 9.0 8.5 9.3 10.6 10.9 11.9 12.9 14.5 16.5 19.7N1 22/11/2016 23:00 00:30:00 41.8 40.3 39.8 39.4 38.8 35.7 42.3 39.2 33.5 32.5 30 31.3 31.2 30.4 32.6 30.2 29.4 28.5 26.9 25.1 22.2 18.5 13.9 10.1 8.9 9.5 10.8 11 12 12.9 14.5 16.6 19.8N1 22/11/2016 23:30 00:30:00 40.5 39.2 38.2 38.2 37.1 33.9 41.7 37.6 32.6 31.6 29.1 29.9 30 28.4 30.3 27.4 26.9 26 24.4 22.8 20 16.4 12.7 9.8 8.8 9.4 10.5 11 12 12.9 14.5 16.6 19.8N1 23/11/2016 00:00 00:30:00 40.6 38.2 38.2 38 36.8 34.1 41 37 33.9 31.6 29.7 31.3 30.1 28.7 30 27.1 26.4 25 23.1 21.1 17.8 14.1 10.6 8.7 8.5 9.3 10.6 10.9 12 12.9 14.5 16.6 19.8N1 23/11/2016 00:30 00:30:00 39 37.7 37.6 41.5 46.5 36.5 40.9 37.6 34.8 31.7 29.2 30.3 29 27.2 28.5 25.6 24.9 23.6 21.4 19.7 16.9 13.4 10.1 8.4 8.5 9.3 10.6 10.9 12 12.9 14.5 16.6 19.8N1 23/11/2016 01:00 00:30:00 39.1 36.6 37 39.4 40.8 36.1 41.1 36.8 33.1 32.4 28.5 30.2 29.6 27.6 29.4 26.9 26.1 24.2 21.7 19.7 16.3 12.2 8.7 7.9 8.3 9.3 10.5 10.9 12 12.9 14.5 16.6 19.8N1 23/11/2016 01:30 00:30:00 39.4 37.6 38.8 40.6 40.5 42.8 46.7 41 37.6 36 33.7 34.3 33.9 31.7 32.9 29.5 29 27.8 25 23.3 20 15.9 11.7 9 8.6 9.3 10.5 10.9 12 12.9 14.5 16.5 19.8N1 23/11/2016 02:00 00:30:00 38.8 36.8 35.7 35.1 34.4 40.4 45.5 37.5 34.6 32.9 30.4 32.6 31.5 28.8 29.8 24.8 24.7 23.5 20.1 18 14.3 10.9 9.1 8.2 8.4 9.3 10.6 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 02:30 00:30:00 40.3 39 38.8 38.3 37.9 42.2 46.2 39.9 36.1 36.4 32.8 34.3 34.1 32.1 33.3 27.5 27.2 25.6 22.1 20 16.2 12.5 9.7 8.3 8.4 9.3 10.6 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 03:00 00:30:00 40.8 38.7 39 37.8 36.8 36.8 43 38.6 33 31.5 29.7 31.9 32.1 30.5 32.5 28.9 28.2 26.7 24.3 22.5 18.9 14.9 10.9 8.7 8.5 9.3 10.4 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 03:30 00:30:00 40.4 38.3 38.5 38.7 37.5 36.6 41.4 38.6 33.1 31.1 29.2 32.2 32.7 30.8 32.8 28.6 28.2 26.8 24.3 22.3 18.8 14.9 11 8.8 8.5 9.3 10.4 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 04:00 00:30:00 41.6 39.1 40.1 40.7 41.3 38.5 43.1 40.1 33.9 32.1 30 33.5 33.9 32.6 33.8 30.6 29.2 27.5 25.4 23.3 19.2 14.9 10.5 8.5 8.5 9.3 10.4 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 04:30 00:30:00 44.1 41.6 43.3 45.5 46.8 43.3 46.8 45.1 37.7 36.1 33.7 37.1 37 36.7 37.3 34.3 32.3 30 28 25.5 20.8 16 10.6 8.5 8.5 9.3 10.5 10.9 12 12.9 14.5 16.5 19.8N1 23/11/2016 05:00 00:30:00 44.4 42.5 43 43.2 43 41.2 46.2 42.6 37.6 34.8 32.6 35.5 36.2 34.5 35.6 31.6 30.5 28.7 26.4 23.9 19.7 15.3 10.8 8.6 8.5 9.3 10.4 10.9 12 12.9 14.5 16.5 19.8N1 23/11/2016 05:30 00:30:00 42.6 38.9 39.5 40 40.3 38.5 43.8 40.3 36.1 32.7 31.5 33.5 34.3 32.7 34.1 30.3 29.1 27.5 25.5 23.3 19 14.6 9.9 8 8.3 9.4 10.8 10.9 11.9 12.9 14.5 16.5 19.8N1 23/11/2016 06:00 00:30:00 44.2 40.9 41.8 41.9 42.5 40.2 44.6 42.3 36.6 34.7 33.4 35.3 35.9 34.7 36 33.1 31.3 29.3 27.4 25.1 20.6 16 10.8 8.2 8.3 9.4 10.9 10.9 12 12.9 14.5 16.5 19.8N1 23/11/2016 06:30 00:30:00 44 40.8 41.6 42.7 43.8 41.8 45.3 42.7 37.2 35 33.6 35.3 35.9 34.8 36.1 33 31.6 29.4 27.3 24.8 20.3 15.8 10.8 8.5 8.4 9.3 10.5 10.9 11.9 12.9 14.5 16.5 19.8Power Station Online
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1/3rd Octave dB L90 Measurement DataOperation
Hogger Hogger & SRVHogger & SRV
Location Start Time
Figure A1: 1/3rd Octave Band Frequency Analysis at N1 with Hogger operating.
Figure A2: 1/3rd Octave Band Frequency Analysis at N1 with Hogger and SRV operating.
Figure A3: 1/3rd Octave Band Frequency Analysis at N1 with Hogger and SRV operating.
0
5
10
15
20
25
30
35
40
45
50
55
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
400
Hz
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 Hogger Operating (03:00 - 03:30)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - SRV Operating (03:10 - 03:11)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
12
.5H
z
16H
z
20H
z
25H
z
31
.5H
z
40H
z
50H
z
63H
z
80H
z
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
630
Hz
80
0H
z
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - SRV Operating (03:20 - 03:21)
dB Leq
dB L90
Figure A4: 1/3rd Octave Band Frequency Analysis at N1.
Figure A5: 1/3rd Octave Band Frequency Analysis at N1.
Figure A6: 1/3rd Octave Band Frequency Analysis at N1.
0
5
10
15
20
25
30
35
40
45
50
55
60
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (23:00)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (23:30)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5H
z
16H
z
20H
z
25H
z
31.
5H
z
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12.
5 kH
z
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Level (00:00)
dB Leq
dB L90
Figure A7: 1/3rd Octave Band Frequency Analysis at N1.
Figure A8: 1/3rd Octave Band Frequency Analysis at N1.
Figure A9: 1/3rd Octave Band Frequency Analysis at N1.
05
10152025303540455055606570
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Level (00:30)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (01:00)
dB Leq
dB L90
05
101520253035404550556065
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12.
5 kH
z
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (01:30)
dB Leq
dB L90
Figure A10: 1/3rd Octave Band Frequency Analysis at N1.
Figure A11: 1/3rd Octave Band Frequency Analysis at N1.
Figure A12: 1/3rd Octave Band Frequency Analysis at N1.
0
5
10
15
20
25
30
35
40
45
50
55
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (02:00)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
60
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (02:30)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12.
5 kH
z
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (03:00)
dB Leq
dB L90
Figure A13: 1/3rd Octave Band Frequency Analysis at N1.
Figure A14: 1/3rd Octave Band Frequency Analysis at N1.
Figure A15: 1/3rd Octave Band Frequency Analysis at N1.
0
5
10
15
20
25
30
35
40
45
50
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (03:30)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (04:00)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12.
5 kH
z
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (04:30)
dB Leq
dB L90
Figure A16: 1/3rd Octave Band Frequency Analysis at N1.
Figure A17: 1/3rd Octave Band Frequency Analysis at N1.
Figure A18: 1/3rd Octave Band Frequency Analysis at N1.
0
5
10
15
20
25
30
35
40
45
50
55
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (05:00)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kHz
12.
5 kH
z
16
kHz
20
kHz
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (05:30)
dB Leq
dB L90
0
5
10
15
20
25
30
35
40
45
50
55
12.
5Hz
16H
z
20H
z
25H
z
31.
5Hz
40H
z
50H
z
63H
z
80H
z
100
Hz
125
Hz
160
Hz
200
Hz
250
Hz
315
Hz
400
Hz
500
Hz
630
Hz
800
Hz
1 k
Hz
1.2
5 kH
z
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 kH
z
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12.
5 kH
z
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (06:00)
dB Leq
dB L90
Figure A18: 1/3rd Octave Band Frequency Analysis at N1.
0
5
10
15
20
25
30
35
40
45
50
55
12
.5H
z
16
Hz
20
Hz
25
Hz
31
.5H
z
40
Hz
50
Hz
63
Hz
80
Hz
10
0H
z
12
5H
z
16
0H
z
20
0H
z
25
0H
z
31
5H
z
40
0H
z
50
0H
z
63
0H
z
80
0H
z
1 k
Hz
1.2
5 k
Hz
1.6
kH
z
2 k
Hz
2.5
kH
z
3.1
5 k
Hz
4 k
Hz
5 k
Hz
6.3
kH
z
8 k
Hz
10
kH
z
12
.5 k
Hz
16
kH
z
20
kH
z
Sou
nd
Pre
ssu
re L
eve
l (d
B)
Sound Frequency (Hz)
N1 - Measured Noise Levels (06:30)
dB Leq
dB L90
www.allegroacoustics.ie
Appendix B
Weather Data
www.allegroacoustics.ie
Appendix C
Calibration Certificate