Dynalite Installers Course Training Guide

8/18/2019 Dynalite Installers Course Training Guide

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Installers Course

Training GuideAdvanced lighting controls made easy

Version 1.1


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2 Installers Course User Guide Topic 1: Infrastructure

Background

Philips Dynalite is a highly specialized company whose principal occupation is to provide ‘cutting

edge’ solutions for lighting control. Our achievements have been recognized worldwide and

Philips Dynalite is generally the system of choice for projects involving integration with third-

party vendor’s equipment and for large-scale applications.

Philips Dynalite’s philosophy is to provide the best solution possible for each and every project.

This is the key to our success. Our considerable investment in Research & Development ensures

that we remain at the forefront of our industry. Our position as a world leader in lighting

management systems for the future is sustained through our total commitment to innovation.

We are represented around the world by distributors and dealers who are handpicked for theirability to provide the highest possible level of service.

From a stock exchange in Shanghai, to a luxury resort in Dubai, a smart

home in Sao Paulo to limestone caves in New Zealand, Philips Dynalite’s

innovative solutions deliver intelligent light.

Ongoing research and development has enabled Philips Dynalite to create secure automated

systems that control tens of thousands of individual light fittings in high-rise office buildings from

any location anywhere in the world. Our networks are engineered to deliver instant notification

of power or system failure, and report via a LAN, internet, or through an SMS gateway to a

mobile phone. This provides the assurance necessary in applications where continuous operation

is vital, such as road tunnels, computer servers or cold storage units.

Philips Dynalite’s modular product design philosophy also improves system flexibility. Through

this approach, specific application requirements can be accommodated with greatly reduced lead

times. As an industry leader Philips Dynalite is committed to creating superior lighting controland energy management systems, setting new benchmarks in performance and efficiency.

In receiving the International Association of Lighting Designers award for Most Innovative

Product, the Philips Dynalite control system has been independently recognized as ‘A user

friendly and sensible modular approach, which takes it from sophisticated domestic settings to

large architectural spaces’.


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Contents

Topic 1: Infrastructure .......................................................................................................................... 9

Overview ............................................................................................................................................................................... 9

Learning outcomes ......................................................................................................................................................... 9

Cabling ................................................................................................................................................................................... 9

Networking requirements ............................................................................................................................................ 9

CAT 5 cable limits ........................................................................................................................................................ 10

CAT 5 wiring diagram .................................................................................................................................................. 11

Recommended DyNet color coding for CAT5 cable .......................................................................................... 11

Recommended DyNet CAT 5 data cable types .................................................................................................... 12

Belden wiring diagram .................................................................................................................................................. 12

Recommended DyNet color coding for Belden cable ......................................................................................... 13

S-Flat 6 cable limits ....................................................................................................................................................... 13

Recommended DyNet color coding for S-Flat 6 cable ........................................................................................ 14

Pin out conversion for RJ45 cable testers............................................................................................................... 14

RJ12 socket connections ............................................................................................................................................. 14

Termination ........................................................................................................................................................................ 15

CAT5 Instructions ........................................................................................................................................................ 15

Flat cable instructions .................................................................................................................................................. 22

DyNet voltages .................................................................................................................................................................. 22

Network architecture ...................................................................................................................................................... 23

The DyNet Network ................................................................................................................................................... 23

The Physical Layer ........................................................................................................................................................ 23

Trunk & spur network ..................................................................................................................................................... 24

Implementing trunk & spur topology ....................................................................................................................... 24

Trunk & spur network ................................................................................................................................................. 25

DLight III trunk &spur network ................................................................................................................................. 26

Ethernet networks ............................................................................................................................................................ 27

Multi trunk networks ................................................................................................................................................... 28

Network cable current limits and voltage drop ........................................................................................................ 29

HF Ballast installation ....................................................................................................................................................... 30

Installation instructions ................................................................................................................................................ 30

DyNet 1 & 2 networks .................................................................................................................................................... 31

Operational differences ............................................................................................................................................... 31

Network addressing ......................................................................................................................................................... 31

DALI network wiring ....................................................................................................................................................... 32

Device compatibility ..................................................................................................................................................... 32

Normal DALI ................................................................................................................................................................. 34

DALI Multi Master ........................................................................................................................................................ 34

Enumeration ................................................................................................................................................................... 35

Emergency lighting ............................................................................................................................................................ 35

Self contained luminaries ............................................................................................................................................. 36

Testing emergency lighting.......................................................................................................................................... 38

Essential supply load shedding.................................................................................................................................... 38

Maintaining circuits by bypassing load controllers ................................................................................................ 40


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DMX ..................................................................................................................................................................................... 40

End of line resistors ...................................................................................................................................................... 40

Topic 2: Installing load controllers.................................................................................................... 41

Overview ............................................................................................................................................................................. 41

Learning outcomes ....................................................................................................................................................... 41

Hardware controls ........................................................................................................................................................... 41

Service LED and switch ............................................................................................................................................... 41

AUX input ....................................................................................................................................................................... 42

Top set ............................................................................................................................................................................ 42

Wall mounted devices ..................................................................................................................................................... 42

Select a suitable location ............................................................................................................................................. 42

Fixing the device ............................................................................................................................................................ 44

Allow for cable entry ................................................................................................................................................... 44

Supply & load cable ....................................................................................................................................................... 44

Powering up the dimmers prior to commissioning .............................................................................................. 45

Operating environments ............................................................................................................................................. 45

DIN rail mounted devices ............................................................................................................................................... 45

Instructions ..................................................................................................................................................................... 45

Circuit breakers ............................................................................................................................................................ 47

Multi controllers ............................................................................................................................................................ 47

Structured wiring boxes .................................................................................................................................................. 49

Select a suitable location ............................................................................................................................................. 49


Wiring terminations ..................................................................................................................................................... 50

Supply and output connections.................................................................................................................................. 50

Dry contact switch input connections ..................................................................................................................... 51

Network connections .................................................................................................................................................. 51

Topic 3: Installing panels ..................................................................................................................... 53

Overview ............................................................................................................................................................................. 53


Instructions ..................................................................................................................................................................... 53

Connecting data cables ................................................................................................................................................ 53

Factory presets .............................................................................................................................................................. 54

Changing button configurations ..................................................................................................................................... 56

DLP & DL2P ................................................................................................................................................................... 57

DR2P ................................................................................................................................................................................ 57

DPN 58

Panel network connections ............................................................................................................................................ 58

Dingus .............................................................................................................................................................................. 58

LSP-PRO .......................................................................................................................................................................... 59

FFC-LSP ........................................................................................................................................................................... 59

Topic 4: Installing motion sensors .................................................................................................... 61

Overview ............................................................................................................................................................................. 61


Installation instructions ................................................................................................................................................ 61

Mounting PIR motion sensors .................................................................................................................................... 62


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Mounting Ultra sonic motion sensors ...................................................................................................................... 62

DUS704C motion coverage ....................................................................................................................................... 63

DUS804C and DUS804C-SM motion coverage .................................................................................................... 63

DUS804C-UP ultra sonic motion coverage ........................................................................................................... 64

Motion detection lens pattern ................................................................................................................................... 64

Optional motion detector lens for DUS704W ..................................................................................................... 65

Selecting sensor installation locations ...................................................................................................................... 66

Sensor mounting for PE (photo electric) ................................................................................................................ 67

Infrared receiver mounting location ......................................................................................................................... 68

Installing DUS704W-MB mounting brackets .......................................................................................................... 68

Topic 5: Installing touch screens ....................................................................................................... 70

Overview ............................................................................................................................................................................. 70


General installation points for touch screens ........................................................................................................ 70

Installing the DTP170 ....................................................................................................................................................... 71


Installing the DTP100 ....................................................................................................................................................... 72

Fixing the Device ........................................................................................................................................................... 73

Power supply .................................................................................................................................................................. 73

Topic 6: Installing integration devices .............................................................................................. 74

Overview ............................................................................................................................................................................. 74


Installing the DDMIDC8 .................................................................................................................................................. 74

Features ........................................................................................................................................................................... 74

Installation notes ........................................................................................................................................................... 75

Electrical diagram .......................................................................................................................................................... 75

Analogue fader ............................................................................................................................................................... 76

Installation steps ............................................................................................................................................................ 76

Installing DDNG485 ......................................................................................................................................................... 76

DPMI940 .............................................................................................................................................................................. 77

Using the DPMI940 ....................................................................................................................................................... 78

Installation steps ............................................................................................................................................................ 78

Electrical diagram .......................................................................................................................................................... 79

Mounting details ............................................................................................................................................................ 79

Connecting to a motion detector ............................................................................................................................. 79

Connecting volt free inputs ........................................................................................................................................ 80

Install DDFCUC024 / DDFCUC10 .............................................................................................................................. 81

Topic 7: Testing and troubleshooting .............................................................................................. 82

Overview ................................................................................................................................................ 82


Walk through test procedure ........................................................................................................................................ 82

LED tracking ................................................................................................................................................................... 82

Luminaires ....................................................................................................................................................................... 82

Sensors ............................................................................................................................................................................ 82

Touch screens ................................................................................................................................................................ 83

Troubleshooting ................................................................................................................................................................ 83


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Network Fault finding .................................................................................................................................................. 83

Power Supply faultfinding ............................................................................................................................................ 83

Panel Fault finding.......................................................................................................................................................... 83

End of line resistors ...................................................................................................................................................... 84

Common problems ...................................................................................................................................................... 84

DDMIDC8 Troubleshooting ...................................................................................................................................... 85

Do’s and don’ts of dimming low voltage transformers ............................................................................................ 85

Do’s and don’ts of dimming fluorescent lighting ....................................................................................................... 86


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About this guide

Guide Overview

This guide is designed to assist in the configuration of Dynalite control devices.

A working knowledge of EnvisionProject and Dynalite commissioning processes is required to

effectively use this document. For more information on commissioning processes, consult the

Dynalite Programmers Guide.

Parameters in the software may require information that must be sourced from third party

manufacturer’s device details and specifications.

Disclaimer

These instructions have been prepared by Philips Dynalite and provide information on PhilipsDynalite products for use by registered owners. Some information may become superseded

through changes to the law and as a result of evolving technology and industry practices.

Any reference to non- Philips Dynalite products or web links does not constitute an

endorsement of those products or services

Copyright

© 2011 Dynalite manufactured by WMGD Pty Ltd (ABN 33 097 246 921). All rights reserved.

Not to be reproduced without permission. Dynalite, Dimtek, DLight, DyNet and associated logos

are the registered trademarks of WMGD Pty Ltd.

Philips Dynalite 6/691 Gardeners Road Mascot NSW 2020 Australia

P: +61 (0)2 8338 9000 F: +61 (0)2 8338 9999 E: [email protected] W: www.philips.com/dynalite

http://www.philips.com/dynalitehttp://www.philips.com/dynalite


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Topic 1: Infrastructure Installers Course User Guide 9

Topic 1: Infrastructure

OverviewIn this topic we investigate network architecture of Philips Dynalite networks, cabling

requirements and terminations of different cabling types.

Learning outcomes

The approach to programming a Philips Dynalite system can be broadly categorized as follows:

• Cabling requirements of a Dynalite network

• Termination of data cables

• Topology of small networks

• Topology of trunk & spur networks

• Topology of Ethernet networks.

• Termination of different cabling types.

CablingNetworking requirements

Here are some important points to understand about cabling requirements:

• The system communicates over screened, stranded RS485 data cable (such as Cat5) and

requires a minimum of three twisted pairs.

• It is recommended that the data cable is connected between devices in a ‘daisy chain’

arrangement. Start at the first device then loop in then out of devices, with a single cable

terminating at the last device.

• If it is necessary to wire the system in a star configuration the system will still operate

normally but diagnosing installation network faults should this be necessary will be more

difficult.


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Figure 2 – CAT5

CAT 5 wiring diagram

Figure 3 – CAT5 Wiring

Recommended DyNet color coding for CAT5 cable

COLOR SIGNAL

Blue MateBlue

Data-Data+

Orange MateOrange

} Paralleled for +12Volts.

Green MateGreen

} Paralleled for Ground.

Brown MateBrown } Spare pair if required to repair damaged cable or canbe used as a drain for static if unshielded cable usedin the installation.


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Recommended DyNet CAT 5 data cable types

MANUFACTURER PART NUMBER

Philips Dynalite DyNet STP-Cable

Belden 9503

Garland MCP3S

Garland STPL5e

Hartland HCK603

M & M Cable B2003CS

M & M Cable B9503CS

Multicables AWM E120236 2092 20

RS Components 368-687

Belden wiring diagram

Figure 4 – Belden Wiring


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Recommended DyNet color coding for Belden cable

COLOR SIGNAL

Black Ground

Blue Data+

White Data-

Red +12Volts/+24 Volts

The recommended cable types for Belden are:

• #1502R

• #1502P

S-Flat 6 cable limits

Flat data cable is specifically designed for high reliability localized network wiring as found in hotel

rooms and residential applications.

In addition to a conductor pair for data, conductors are provided to supply DC power to

network powered peripherals.

Conductors have an overall shield for maximum data integrity. The data cable is flexible, as all

conductors are stranded.

It is designed for rapid crimp termination into RJ12 plugs for use with Philips Dynalite products

with supporting RJ12 sockets.

The cable is supplied in 200 meter rolls, or in pre-terminated leads of 3, 5 and 10 meter lengths.

Cable limits:

• Maximum Philips Dynalite devices per special flat cable: 10.

• Maximum special flat cable length: 100m.

Silver

White

Red

Yellow

Green

Brown

Figure 5– Flat cable


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Recommended DyNet color coding for S-Flat 6 cable

COLOR SIGNAL

Silver Not connected

White Ground

Red Data +

Green Data -

Yellow +12 Volts

Brown Not connected

Pin out conversion for RJ45 cable testers

RJ12 PINS RJ45 CABLE COLOR

- 1 -

1 2 Silver drain

2 3 White

3 4 Red

4 5 Green

5 6 Yellow

6 7 Orange

- 8 -

RJ12 socket connections

The diagram below details RJ12 socket connections:

Figure 6 - RJ12 Socket Connection


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Termination

CAT5 Instructions

Follow instructions below for CAT5 cable termination on a Philips Dynalite network.

1. Using side-cutters cut a slit at the end of the cable. Use care to ensure only the out

plastic sheath is cut, avoiding the inner cores and shielding sheath.

Figure 7

2. Locate the draw string between the outer sheath and the foil shield wrapper and using

pliers pull downwards to cut a 90mm slit in the outer sheath shown in figure 8.

Figure 8


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Figure 9

3. Using side-cutters carefully trim away the outer plastic sheath, again ensuring not to cut

the inner cores.

Figure 10


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4. Locate the shield drain wire and separate from the shield’s foil sheath. Once separated

carefully trim away the foil shield and plastic wrap.

Figure 11

5. Bend the Brown/Brown-White pairs back towards the outer sheath to be kept as spares.

Figure 12


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6. Using a cable-tie secure the two cables together.

Figure 13

7. Trim away the excess from the cable tie.

8. Twist both of the shield wires together.

Figure 14


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9. On both cables untwist the Blue/Blue-White pairs.

Figure 15

10. Twist together the Blue wire from each pair.

11. Twist together the Blue/White wire from each pair.

12. Twist together the Green-Green/White wire from each pair.

13. Twist together the Orange-Orange/White wire from each pair.

Figure 16


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14. Strip 10mm of sheath from each of the wires and twist together.

Figure 17

15. Fold this back on itself to improve contact with the screw terminal, this should then be

5mm in length.

16. Over the shield wire slide a piece of sheathing. This is to help prevent the shield being

inadvertently shorted.

Figure 18


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Terminate each cable as shown.

• Shield - Shield

• Ground - Green/Green-White

• Data + - Blue

• Data - - Blue-White

• +12V – Orange/Orange-White.

Figure 19

17. Ensure the conductors are fully inserted into the terminals with no loose strands

escaping.

Figure 20

18. The process in complete.


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Flat cable instructions

Correctly stripped cable Incorrectly stripped cable – shield still present

Figure 21 Figure 22

Figure 23

DyNet voltages

Below are voltage values for proper operation of a DyNet network:

• Max – Min voltages: EU/AUS 10-18V, NA 18-26

• Max ripple: 1Vrms @100/200Hz

• Max voltage range for Data+ and Data –: -6.5V - +6.5V (Data+ must be greater)

• Min voltage difference between Data + and Data-: 500mV recommended, 200mV is

absolute minimum


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• Max voltage range for power connections: +9V- +16V

Network architecture

The concept of a centralized controller and the complicated task of ‘binding’ individual slave

devices to the central controller in a DyNet network is completely eliminated. Each individual

device will inherently know what they are and simply listen to and broadcast onto the network.

This means that in most cases, particular devices on the network do not know or care about

other devices. They simply respond to network messages, to which they are inherently sensitive,

and broadcast their own class of messages with no particular destination in mind.

A key principle of the DyNet network is that all of the functions associated with a particular

device are located within that device. For example, all scene preset information is stored within

the actual controllers. This means that if any device should fail, only the functions associated with

that device are lost, other devices on the network are not affected. From a maintenance point ofview, this concept of distributed control (self-contained) units both speeds up fault-finding, and

allows a high level of fault tolerance in large systems.

This ‘Broadcast Network’ operating principle provides the necessary flexibility to ensure that the

system can be easily (and at low cost) altered or added to after installation. It is possible to add

extra equipment at any time without the need to re-configure or rewire the entire system.

The DyNet Network

The DyNet network is the communications layer that links the various Dynalite products

together and enables them to interact with each other. For the purpose of discussion it can be

divided into two sections, the Physical Layer and the network protocol.

The Physical Layer

Dynalite products utilize RS485 which is an industry standard method of data transmission as

detailed in the TIA/EIA-485-A specification, with some variations.

The TIA/EIA-485-A specification defines a UL (Unit Load), which declares that an RS-485 driver

must be able to drive 32 ULs. This means that an RS-485 network supports 32 nodes, when each

node bears a unit load on the line. Dynalite products use 1/8 UL drivers, which allow up to 256

devices on a network segment.

Another important variation from the TIA/EIA-485-A specification is the addition of an extra

conductor that carries a DC supply, which is generated by an integral power supply contained

within all mains powered devices and is used to energize those devices that do not connect to

mains power, such as motion detectors and wall switches.


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Trunk & spur network

Implementing trunk & spur topology

This style of topology is used in large installations, where there are one or more data trunk

cables that may interconnect network bridges located at different floors or distribution boards.

The second port on the network bridge is then connected to a spur that feeds the dimmers and

control panels in that locale. The recommended method of connection is to connect the Spur to

the Port 1, and the trunk to the Port 2. Some reasons for implementing Trunk/Spur topology

include:

Optical isolation – A fault on a Spur will be localized to that Spur only, the rest of the system

will be unaffected.

Quantity of network devices – A finite number of devices can be connected to a single RS485

data cable. The recommended maximum number of devices is 100. The use of network bridge

gives a maximum of 100 devices per spur, with 128 spurs per trunk gives a total of 12800 devices

per trunk. Adding network isolators on spurs and running multiple trunks removes any realistic

limitation from a single Philips Dynalite network.


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Trunk & spur network

Figure 24


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DLight III trunk &spur network

Figure 25


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Ethernet networks

It is possible to use an Ethernet network to work as a trunk with DyNet spurs.

The figure below shows an Ethernet trunk connected to DyNet spurs with the DNG100BTEthernet interface.

Figure 26


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Multi trunk networks

Multi trunk networks are used in large multi story projects, the purpose of a multi trunk network

is to increase the speed of communication.

Figure 27


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Network cable current limits and voltage drop

Because a number of devices are powered over the network the quantity of consuming devices

such as panels and sensors needs to be considered. Typically most panels and sensors will run

between 10-15V DC @ 25mA.

To overcome voltage drop or large numbers of consuming devices a secondary power supply

(DDNP1501) may be added to boost the overall network voltage. The DDNP1501 will deliver

15V at 1.5A.

Generally most Philips Dynalite load controllers generate around 100mA to the DyNet network

and will drive 4 or 5 consuming devices without the need for a secondary power supply.

It is important to note that all Cat5 cable has a maximum current capacity of 2A. It is important

that the network is designed not to exceed this rating.

Devices such as touch screens draw as much as 400-1000mA from the DC supply. In this case it

is recommended that the touch screen be feed directly from a DDNP1501. Furthermore we

would recommend that the connections at this device be limited to only GND, D+ and D- to

avoid exceeding the 2A cable limit. See below figure.

Figure 28 – Data only Connection Figure 29 – Power only connection


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Power Supply

Power only

connection

Data only

connectionStandardconnection

DyNet network

Touch screen

Leading edge

Trailing edge0-10V

Figure 30

HF Ballast installation

Installation instructions

1. Calculate loads to ensure any channels are not overloaded, then connect loads to theoutput channels. The maximum loading of this device is as follows:

2. *DALI broadcast mode: 80 ballasts per channel, do not exceed 500 ballasts in total

3. *1-10V mode: 100mA, 50mA source

4. *DSI Mode: 100 ballasts per channel, do not exceed 1200 ballasts

5. Remember that most 1-10V cabling scenarios are polarity conscious. DALI and DSI cables

are not polarity conscious.

6. Connect a single phase 0.5A feed to the supply terminals. This device must be earthed.

7. Connect data cables to the device as per diagram in instruction manual for the controller.


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8. If the Auxiliary input is to be used, connect a dry contact device in between the AUX and

GND terminals. Keep cable runs between the controller and the dry contacts under 2

meters. The function of the Auxiliary input will need to be programmed at the time of

commissioning.

Note: The correct operation of DALI broadcast mode relies on the ballasts being set to

their factory defaults. If problems are encountered, press the service switch 3 times, this will

reset all ballasts connected and energized to their default settings.

DyNet 1 & 2 networks

Operational differences

The maximum number of available Areas in a DyNet 1 network is 255. DyNet 1 is an open

protocol.

The maximum number of available Areas in a DyNet 2 network is 65536. DyNet 2 is a closed

protocol.

Network addressing

A DyNet network has two different addressing modes:

Physical addressing is used primarily during the testing and commissioning stage to configure

DyNet Devices. It is also used for physical, location specific parameters such as circuit breaker

trip signaling. A Device Type, Box Number and Physical channel number are used to identify each

individual lighting circuit.

Logical addressing is used in the day-to-day operation of the lighting system. Lighting circuits

and control panels are configured to Areas; independent of the physical device they are

connected to. An Area Number and Logical channel number are used to identify single or groups

of Physical Channels.

Areas are used to group related lighting points by the area/room they are in. Consider the

example of a load controller that supplies lighting circuits to 2 rooms, with a control panel in

each room. The controllers lighting circuits and the control panel in Room 1 could be configured

as Area 2, and the controllers lighting circuits and the control panel in Room 2 could be

configured as Area 3.

The end result would be that the control panel configured to Area 2 would only control circuits

designated Area 2. The control panel configured to Area 3 would only control circuits designated

Area 3. This allows the two rooms to operate independently of one another.


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Area 2

Office 1

Area 3

Office 2

Logical 2Logical 1Logical 2Logical 1

CP 1 CP 2

Figure 31

DALI network wiringDevice compatibility

Philips Dynalite DALI compatible load controller range is listed below, :

• DMBC110 - HF Ballast Fixture Coupler

− 1 x output selectable to: DALI Broadcast, 1-10V, DSI

− DALI Ballasts and transformers: 5, 0-10V: 10mA source or 20mA sink DSI Ballasts

and transformers: 15.

• DDBC100 - DALI- DALI HF Ballast Controller

− 1 x DALI control output, supporting a full DALI universe of 64 channels, including

backward channel

− Diagnostics include; Lamp failure reporting, Ballast failure reporting, Ballast run time

tracking for each ballast, Device Online/Offline status.


− 3 DALI control outputs, each supporting a full DALI universe of 64 channels (192

total), including backward channel.


− 3 DALI control outputs, each supporting a full DALI universe of 64 channels (192

total), including backward channel

− 3 x 20A feed through switched circuits for DALI ballast mains supply.


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• DDMC802 - Multipurpose Controller

− DDBM100 1 channel ballast module, suitable for controlling DALI (Broadcast mode

only), DSI & 1-10V ballasts and transformers (a relay module must be paired with a

HF ballast module when controlling 1-10V ballasts).

• DDBC1200 - HF Ballast Controller

− 12 control outputs, selectable to DALI (Broadcast mode only), 0-10V or DSI

− Output capacity - DALI mode: 80 DALI ballasts per channel, 500 total, 0-10V mode:

100mA sink, 50mA source per channel, DSI: 100 DSI ballasts per channel, 1200 total.

• DBC905 - 1-10V & DSI HF Ballast Controller

− 9 x HF ballast control outputs, each selectable to 1-10V, DSI or DALI.

• DBC1220GL - DALI, DSI & 1-10V & HF Ballast Controller

− 12 x HF ballast control outputs, each selectable to 1-10V, DALI (Broadcast mode) or

DSI

− Output capacity - DALI mode: 64 DALI ballasts per channel, up to a maximum of

400.

• DBC1210 - DALI, DSI & 1-10V HF Ballast Controller.

− 12 x HF ballast control outputs, each selectable to 1-10V, DALI (Broadcast mode) or

DSI.

− Output capacity - DALI mode: 64 DALI ballasts per channel, up to a maximum of

400, DSI mode: 100 ballasts per channel, up to a maximum of 1,200, 1-10V mode:

50mA sink/source per channel.


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Normal DALI

Figure 32

DALI Multi Master

Figure 33


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Enumeration

DALI ballast enumeration can cause some trouble shooting confusion, below is a list of points to

keep in mind when addressing DALI issues:

• Hit the service switch 4 times to start the test sequence. (wait for the time out or resetdevice)

• Check that the number of ballasts does not exceed 64 per universe

• Check voltage on circuits, it should be 15v

• Split the universe and then enumerate.- this will narrow down the search area for the

defective ballast.

• Check for miss wired ballasts – miss wired ballasts will cause a variety of dimming issues

• Check that all ballasts have been earthed correctly

• Check ballasts are wired correctly – make sure that the long and short wires are

connected correctly, to check remove the lamp and short the 2 wires together, this

should cause the universe to alternate between 0% and 100%.

Figure 34

• Cable length to long or too skinny

• We recommend the Tridonic – config tool v1.5

• Cross wired universes.

Emergency lighting

There is a common requirement for emergency lighting to be used alongside general lighting

connected to a control system. There are a few ways of achieving this, the most appropriate

method is dependent on the type of emergency lighting fixture and control equipment used.

Following is a description of several different

techniques and their respective deployment methods. Sometimes it will be necessary to combine

two or more techniques to achieve the desired outcome.


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Self contained luminaries

There are three common types of Self Contained Luminaires (also known as Single Point

Luminaires):

Maintained luminaires - This is an exit or emergency luminaire, where the lamps used foremergency lighting also operate under normal supply. The lamps used in these luminaires are

often fluorescent, with a dimmable ballast and can be controlled in exactly the same manner as a

normal dimmable fluorescent luminaire.

Maintained Luminaires have two line inputs. One is connected to the Normal lighting output of

the load controller. The Maintained input is connected to the load side of the load controller’s

circuit breaker, which supplies power to charge the internal battery and to use as a signal to turn

the lamp on in the event of a power failure. In this example the Maintained Luminaire is also used

for Normal Lighting, it’s ballast is dimmable so ballast control lines are shown. Commonly used

control protocols are DALI, DSI and 1-10V.

Figure 35

Non-maintained luminaires - This is an exit or emergency luminaire, where the lamps used

for emergency lighting only operate when the normal supply fails. The lamps used in these

luminaires are often incandescent such as the small “Spitfire” halogen lamp and the larger, sealed

beam flood lamp units.

Non-Maintained Luminaires are connected to the load side of the load controller’s circuit

breaker, which supplies power to charge the internal battery and to use as a signal to turn the

lamp on in the event of a power failure. This connection method allows full control of the

normal lighting while providing for emergency lighting in the event of a circuit breaker trip or

power supply failure.


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Figure 36

Sustained luminaires - This is an exit or emergency luminaire with two or more lamps where

at least one lamp operates in non-maintained mode and is only illuminated when normal supply

fails. The other lamp operates on the normal supply only. This is identical in functionality tohaving a Non-Maintained Luminaire and a Normal Luminaire both in the same housing. charge

the internal battery and to use as a signal to turn the lamp on in the event of a power failure. In

this example the normal half of the Sustained Luminaire is used for Normal Lighting, it’s ballast is

dimmable so two ballast control lines are shown, common protocols are DALI, DSI and 1-10V.

Sustained Luminaires have two line inputs. One is connected to the Normal lighting output of

the load controller. The Sustained input is connected to the load side of the load controller’s

circuit breaker, which supplies power to charge the internal battery and to use as a signal to turn

the lamp on in the event of a power failure. In this example the normal half of the SustainedLuminaire is used for Normal Lighting, it’s ballast is dimmable so two ballast control lines are

shown, common protocols are DALI, DSI and 1-10V.

Figure 37


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Testing emergency lighting

Most local lighting codes require the testing of emergency lighting systems at defined intervals.

Common problems include failed lamps and aged batteries that no longer meet the luminaire’s

rated duration.

To assist in the testing process, some models of Dynalite load controllers are optionally available

with Emergency Lighting Outputs (ELx). This controlled output is fed via an NC relay and

provides power to the maintained input of Emergency Luminaires. The ELx outputs from

multiple load controllers can be remotely disconnected for a defined period of time, for example

a test button would switch off all ELx outputs for a particular office floor, maintenance staff

would then perform a ‘walk through’ to identify failed components. This process can be

automated with the addition of extra hardware in the luminaire.

Figure 38

Essential supply load shedding

Some sites are equipped with a standby generator, which will automatically start upon failure of

normal supply and, after operating parameters are reached, will switch part or all of the site from

the normal supply circuit to the generator’s output, resulting in the site being re-energised some

10 to 20 seconds after normal supply failure. Quite often the standby generator is coupled with a

UPS (Uninterruptible Power Supply), which ensures there is no power dropout during the

changeover period. In theory, the lighting system should operate as it would on normal supply,

but in practice it is often desirable to modify its behavior. Two common reasons for doing this

are:

The Standby Generator does not have the power capacity required to operate the site normally.

In this case it is desirable to place the lighting system into a load shedding mode.


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The site should not be occupied while normal power is not available. In this case it is desirable to

place the lighting system into an egress mode.

To change the operating mode, the lighting system must be made aware that the generator is

online. This is typically carried out via a relay that actuates when the generator is online, (or

sometimes via a relay that actuates when the normal supply fails) providing a dry contact signal to

an input unit on the lighting control network, such as a DDMIDC8 Multifunction Input Interface.

1 Phase40 AMP

Figure 39

In egress mode The DDMIDC8 locks out all control devices such as wall mounted

Control panels, touch screens, motion detectors etc, and selects a global egress preset, which ispre-defined to illuminate egress paths and reduce lighting in workspaces to assist in alerting

occupants that something is amiss. When normal power is restored the DDMIDC8 restores

normal control functionality.

Load shed mode The DDMIDC8 instructs all load controllers to use a different set of presets

than the normal ones. Consider the example of a room with two channels of lighting and a

control panel that recalls four presets:

During normal operation, presets 1-4 are recalled from the control panel. In load shed mode the

DDMIDC8 uses a part of the DyNet feature set called ‘Preset Offset’, which instructs the load

controllers to recall presets 5-8. This function can target a single or group of rooms, or morecommonly, the whole site. If it is desirable that no lighting is on at all in particular rooms in load

shed mode, then all load shed presets are set to 0%. This method has the advantage of minimal

impact on the site, as lighting levels in particular rooms are not disturbed if they are already off or

at low levels.


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Maintaining circuits by bypassing load controllers

When there are only a small number of circuits to be maintained when a site changes over to a

standby generator or UPS, a simple solution is to bypass the lighting control system with

contactors that connect the circuits to be maintained directly to the essential supply.

Figure 40

In this scenario the non-essential supply is used to hold a contactor closed, connecting the lamp

to the load controller. When the non-essential supply fails the load controller will be de-

energized as will the contactor, which will connect the lamp to the essential supply.

DMXEnd of line resistors

• At 9600 Baud the distortion of the original signal is usually within limits and so EOL

resistors are not recommended on a standard DyNet system.

• Baud rates greater than 9600 Baud must be terminated using a 120Ω resistor across D+

and D-.

• Usually fitted into network connector strip for 1st and last devices.

• For DMX integration – network must be daisy chained with end of line resistors.

D+

D--

D+

D--

1 2 0 R

1 2 0 R

Figure 41


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Topic 2: Installing load controllers Installers Course User Guide 41

Topic 2: Installing load controllers

Overview• This document is a guide to installing Philips Dynalite components to a state where it is

really to be commissioned.

• Every Dynalite product is delivered with a comprehensive instruction manual. It is

important that you read the installation instructions for each product before using this

guide.

Learning outcomesBy the end of this topic you’ll be able to detail the installation steps for the following devices:

• Wall mounted devices

• DIN rail mounted devices

• Mounting structured wiring boxes

• Mounting panels

• Mounting sensors

• Mounting touch screens

• End of line resistors.

Hardware controls

Service LED and switchThe Service LED has 3 signaling modes, which are useful for troubleshooting:

• Blinking slowly (1Hz) = Normal Operation

• Blinking fast (0.25Hz) = Network Activity Detected

• On = Fault.


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42 Installers Course User Guide Topic 2: Installing load controllers

The Service Switch, when pressed, causes a “sign-on” message to be transmitted onto the

network. If the transmission is successful, the Service LED will indicate “network activity

detected”. The Sign-on message contains information about the device, such as: box number,

device type and embedded software version. This information is captured by DLight

configuration software to speed up commissioning of large systems.

The Service Switch three states are:

• 1 push = Transmit Network ID

• 3 pushes = All Channels 100%

• Push & hold for 4 sec = Reboot.

AUX input

This is a dry contact interface that is active low. The dry contact is connected between the AUX

and GND terminals on the DyNet connector strip. The function of the AUX input is

programmable. Ensure that the cable length between the dry contact and terminal strip is no

longer than 2 meters.

Top set

This adjusts the maximum output that all other control sources can select, i.e. if the Top Set is

fully clockwise, 100% selected by a control source will give 100% output. If it is fully anti-

clockwise, 100% selected by a control source will give 50% output. This control is useful for

extending lamp life and can be operated without any form of network control, effectively turning

the device into a stand-alone power conditioner and lamp protector.

Wall mounted devices

Select a suitable location

Some of Philips Dynalite products are available in the wall mounted form factor, these include:

• Load controllers

• Network Bridges.

Wall mounted devices are designed for indoor use only. If installing in an external location, the

device must be housed in a suitable well-ventilated enclosure. Choose a dry location that will be

accessible after the installation is complete.

To ensure the cooling system functions correctly, the load controller should only be mounted

vertically, the right way up.


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The load controller will generate heat when operating, approximately 2 Watts per Amp of load,

and requires an air gap of 200mm on each side and at the top and bottom of the device.

This air gap is also required to ensure serviceability of the load controller without complete

removal from the mounting surface.

This device may emit some mechanical noise. Take this into account when deciding the mounting

location.

Figure 42 Figure 43

Figure 44


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Fixing the device

The load controller has integral mounting brackets attached to the enclosure. The brackets are

designed to accommodate 4 fixing screws up to 8mm diameter.

The load controller can be fixed to the wall without opening the cabinet or removing covers.Make sure no dust or other debris enters the device during installation.

Do not leave the front cover off for any length of time. Excessive dust and dirt can degrade the

cooling of internal components.

Allow for cable entry

Supply and load cables enter the enclosure at the top. If these cables are fed from below the

mounting position, they should be routed around the enclosure to enter at the top. An

alternative method is to stand the enclosure off from the mounting surface by mounting it on a

cable tray or a Unistrut style product.

The cables can then be routed between the enclosure and the mounting surface, and enter the

enclosure via the cut out provided on the mounting face. The control cables enter at the bottom

of the enclosure. Control cables should never be run in the mains voltage sections of the

enclosure.

Supply & load cable

Supply Cables -The supply input terminals are located toward the top of the enclosure and

consist of Earth, Neutral, and Phase. The supply cables should have enough capacity to allow the

device to be loaded to its maximum capacity.

Load Cables - Load cables can be terminated on the 4 x 3 way load terminal strips (one for

each channel), a Neutral link and an Earth link located at the centre of the enclosure. It is

important that an individual output circuit is not overloaded. Calculate the intended load, and

ensure that it is below the maximum capacity of an individual channel. To ensure compliance

with interference standards, the load neutral cables must be individually connected to the neutral

link terminals inside the cabinet. Never use a common neutral at a remote location.

Emergency Lighting Connections - Connect the emergency lighting circuit active to the load

side on the circuit breaker for the relevant channel, as indicated by the labels next to the circuit

breakers. Do not remove any cables that may already be terminated at this location.

Energizing the Device - If it is necessary to energies load circuits before any control cables are

connected, it is acceptable to replace the cover and energies the device immediately, as the

default factory programming is to have all channels set to 100% output. This device should be de-

energized before terminating the control and data cables.


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Powering up the dimmers prior to commissioning

All devices are pre-programmed with a default configuration before leaving the factory. When all

the devices are installed and networked together, every button panel will control all the dimmers.

The Dynalite engineer requires the system to be installed to this level to commission the project

successfully.

All Dynalite load controllers are set to provide full output to the load as the default, irrespective

of having the network connected. When the network is connected, every button panel will

operate every circuit of every device.

Operating environments

This device is designed for indoor use only. If installing in an external location, the

DLE1205 must be housed in a suitable well ventilated enclosure. Choose a dry location that will

be accessible after the installation is complete.

In addition the load controller must not be in a location that exceed the following limits for

temperature and humidity:

0º to 40ºC ambient temperature

0% to 95% RH non condensing.

DIN rail mounted devicesInstructions

A number of devices are available in the DIN rail form factor, these include:

• Load controllers

• Time clocks

• Power supplies

• Network gateways

• Dry contact interface devices.


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Follow the points below to ensure correct installation of DIN rail mounted devices:

• Mount the device on a DIN rail inside an approved enclosure.

• Calculate loads to ensure any channels are not overloaded, then connect loads to the

output channels.

• This device must be earthed

• Connect data cables to the device as per diagrams in the previous topic.

• If the Auxiliary input is to be used, connect a dry contact device in between the AUX and

GND terminals. Keep cable runs between the device and the dry contacts under two

meters. The function of the Auxiliary input will need to be programmed at the time of

commissioning.

• Every Dynalite product is delivered with a comprehensive instruction manual. It isimportant that you read the installation instructions for each product before installation.

Figure 45


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Figure 46

Circuit breakers

Required by each device, consult the product data sheet or instruction manual for details.

Multi controllers

When installing Multi Controllers there are some additional considerations to take into account

regarding the controller modules.

Verify that the Output Cards supplied are suitable for your intended loads. Pay attention to any

Output Card specific documentation that may be packed with Output Cards. When dimming

electronic transformers, ensure that the intended transformer is included in Dynalite’sCompatible Electronic Transformer List, the latest revision is available at dynalite-online.com

1. Snap the cover off the base unit. Plug each Output Card into the slots provided on the

main circuit board. Replace the base unit’s cover. If using different types of Output Cards,

remember which type is associated with each set of output terminals.

2. Mount the device on a DIN rail inside an approved enclosure.

3. Calculate loads to ensure any channels are not overloaded, then connect loads to the

output terminals. The maximum loading of this device is 16A. A de-rating factor may

need to be applied if installed in a smaller sealed switchboard when using Leading orTrailing edge dimmers, contact your dealer for details.


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The output card ratings are:

• DDBM100 Ballast Controller – Digital mode : 5 x Ballasts

• DDBM100 Ballast Controller – DSI mode : 15 x DSI Ballasts

• DDBM100 Ballast Controller – 1-10V mode : 10mA source, 20mA sink

• DDCM102 Curtain Controller : 2 Amps

• DDFM102 Fan Controller : 1 x Fan, max 400VA

• DDLM102 Leading Edge Dimmer : 2 Amps

• DDLM104 : Leading Edge Dimmer : 4 Amps

• DDRM104 Relay Controller : 4 Amps

• DDTM102 Trailing Edge Dimmer : 2 Amps

WARNING : Ballast controller output is referenced to mains neutral and is live. Only mains

rated cables and control ports should be connected.

Ensure that lamp holders are marked with the maximum permissible lamp size that will not

overload a channel. This is to protect the end user from inadvertently overloading a channel by

replacing lamps with higher wattage types.

1. Every time the front cover is removed, ensure that all modules are correctly seated and

locked into sockets before the cover is replaced.

2. Ensure that lamp holders are marked with the maximum permissible lamp size that will

not overload a channel. This is to protect the end user from inadvertently overloading a

channel by replacing lamps with higher wattage types.

3. Connect a single phase 16A feed to the supply terminals, via a 16A circuit breaker or

HRC fuse. This device must be earthed.

4. Connect data cables to the device as per diagrams below.

5. The Auxiliary input is connected via a dry contact device in between the AUX and GND

terminals. Keep cable runs between the device and the dry contacts under two metres.

The function of the Auxiliary input will need to be programmed at the time of

commissioning.


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Structured wiring boxes

Select a suitable location

This device is designed for indoor use only. If installing in an external location, the DBC905 must

be housed in a suitable enclosure. Choose a dry location that will be accessible after the

installation is complete. To prevent dust or particle penetration the controller should be

mounted so that connector apertures do not face directly upwards. Recommended mounting

methods include surface wall, slab, cable tray or “drop rod” suspension.

Fixing the device

The controller has two keyhole slots located at each end of the housing, which can accommodate

fixing screws up to 6mm diameter. The preferred method of mounting is shown below using

“drop rods” with appropriate fastening clips.

Figure 47


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Wiring terminations

Removable connectors are utilized for all wiring terminations to simplify maintenance, installation

and replacement. Note that controllers are supplied without connectors. Please order

connectors separately as required.

Figure 48

Supply and output connections

The DBC905 is available in two configurations supporting popular structured wiring brands; CMS

Electracom / Modular Wiring tag series and Wieland GST18 series. Units are designated by item

code as DBC905C (CMS) OR DBC905W (Wieland).

Both cable vendors offer a range of wiring solutions and accessories for both the upstream supply

and downstream load wiring. The upstream wiring solutions combine both the mains supply and

floor network circuits into one wiring assembly, which can dramatically reduce installation time.

Please refer to respective vendor for guidelines on connector and cable assembly selection.

DBC905W Output Connector Pole Assignments

Figure 49

DBC905W pole mains input socket

Figure 50

DBC905C Output Connector Pole Assignments

Figure 51


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DBC905C pole mains input socket

Figure 52

Dry contact switch input connections

The DBC905 incorporates 4 x voltage free single pole double throw (SPDT) switch inputs,

momentary or latch action with four x 3 pole removable terminal sockets for connection of two

way on and off retroactive switches.

Figure 53

Network connections

Serial ports are used to interconnect other dimmers, smart control panels, sensors and AV

controllers.

The DBC905 circuit design incorporates multiple layers of isolation to deliver robust fault

tolerance and uncompromising safety. It should be noted that most structured wiring solutions

for upstream supply circuitry which include both network and power (i.e. 5 pole systems) only

provide functional isolation between the data and mains circuits. Where such wiring systems are

used, the floor network must be considered at mains potential not SELV and all floor network

wiring should include the appropriate provision for prevention of access to live parts.

The main floor network port on the DBC905 is isolated for this reason. The isolation will

tolerate a fault which raises the floor network to mains potential.

Note that this does not include mains potential applied across D+ and D- which would of course

result in destruction of circuit components. Isolation is also separately provided to the local

DyNet ports and switch inputs. This ensures that all switch inputs and local network circuits are

SELV and prevents propagation of faults from these circuits across the floor network.

Where an upstream structured wiring solution is used, care should be made when terminating

network spur wiring at floor bridges (area controllers), to again prevent access to parts and

wiring considered potentially live. In this case only DBC905 controllers should be connected to

the floor network as they incorporate the isolated port. Under no circumstances should a


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standard user interface be connected directly to the floor network as this may permit user access

to potentially live parts.

All user interfaces such as sensors and panels should be connected to the local network ports on

the DBC905 which provide SELV isolation from mains and the floor network. Where it is

necessary to connect user interfaces to a floor network of this type, a bridge should be always

used to provide effective isolation.


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Topic 3: Installing panels Installers Course User Guide 53

Topic 3: Installing panels

OverviewThis topic covers the requirements and step for installing the Philips Dynalite range of panels.

Instructions for DLP, DPN and DR2P are covered.

Learning outcomes

By the end of this topic you’ll be able to:

• Install DR2P series user interface panels

• Install DLP user interface panels

• Install DPN user interface panels.

Instructions

Follow the points below to ensure correct installation:

• Use the mounting screws provided

• To comply with local electrical standards, some products may be required to be installed

into a metal wall box (not supplied).

Connecting data cables

• Follow the points below when connecting data cables to ensure correct installation:

• Use screened, stranded RS485 data cable with three twisted pairs.

• Connect data cable to devices in a ‘daisy chain’ whenever possible. Start at the first

device, then loop in then out of devices, with a single cable terminating at the last device.

• Devices may be wired in any order.

• Physical constraints may dictate that data cable spurs are necessary. In these cases,

Network Bridges may be needed.

• The Data Cable should be segregated from any Mains Cables by a minimum of 300mm. If

the Data Cable has to cross over any Mains Cables, it should do so at a 90° angle.

• A data cable that is connected to an energized dimmer is live. Do not cut or terminate

live data cables.

• Panels can be mounted vertically or horizontally if desired.


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54 Installers Course User Guide Topic 3: Installing panels

Factory presets

Default preset levels are factory preprogrammed into give basic level of functionality.

These can be customized to specifically suit each room or area.

Figure 54 Figure 55

The default preset levels are listed below:

PRESET LIGHT LEVEL

P1 100%

P2 70%

P3 40%

P4 0%

P5 80%

P6 60%

P7 50%

P8 20%

Note: Hold down a button for 5 seconds to sign on a panel to a network.


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Antumbra panel details

Front of device Back of device

Communications module

Terminal connection Pin connectors

DyNet

connection

plug

Network LED

Network sign

on plug

Function DIP

switches

Labeling space

Location

socket

Connection header

Button switch

Light level

sensor plug

Rim finish

Tempreature sensor Button clip Network LED

Network LED

Locating pin guide Pin header

Button guides


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Installation steps

The mounting plate needs to be installed with

the locating tabs into the wall.

The network cables and connector plug pulls

though the mounting bracket.

The plate’s orientation can be either way.

Using the long mounting screws provided fix

the mounting bracket to the wall. Installers

must use the screws provided as different

screws could damage the panel once fully

installed.

Ensure that the mounting plate is level and

make adjustments if required.

Once the mounting bracket is mounted plug the

five-way network socket into the mounted

Communications module.


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The whole panel assembly can be pushed into

the mounting bracket. Locate and fix the

application base to the mounting bracket using

the two smaller screws through the mounting

holes. Recheck the level of the panel and adjustif required

Changing button configurations

DLP & DL2P

Buttons, bezels and covers snap-on, remove the fascia to access buttons without the need for anytools or extra wiring.

Figure 56 Figure 57

DR2P

DR2P panel buttons are changed individually, see figure 47 below:


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Figure 58

DPN

Buttons for DPN panels can be replaced without the need for any tools or extra wiring. By

pinching the button cap on the sides and pulling gently the cap can be removed. The fascia of the

DPN panel doesn’t need to be removed for button maintenance.

Figure 59

Panel network connections

Dingus

You can connect to the back of a panel using a Dingus supplied with the DTK622 PC node.

Figure 60

In addition to the dingus, the LSP-PRO and FFC-LSP can be used to connect to the DyNetnetwork via DL2P and DR2P panels.


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LSP-PRO

Remove the panel’s fascia to access the connector shown in figure 61 below:

Figure 61 Figure 62

FFC-LSP

A third type of connector can be used to connect to the DyNet network via a DR2P panel

Remove the panel’s fascia to access the connector shown in figure 48 below:

Figure 63 Figure 64


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Topic 4: Installing motion sensors Installers Course User Guide 61

Topic 4: Installing motion sensors

OverviewThis topic covers the requirements and step for installing the Philips Dynalite range of sensors.

Instructions for DUS704C, DUS704W and DUS804C are covered.

Learning outcomes

By the end of this topic you’ll be able to:

• Install motion sensors using PIR motion control

• Install motion sensors using ultra sonic motion control

• Install motion sensors for light control

• Install sensors for IR control.

Installation instructions

Follow the points below to ensure correct installation:

• WARNING * Do not touch the Pyro Sensor with your fingers. For indoor use only.

• Select an appropriate indoor mounting location, as detailed in the location guidelines on

the following pages. Note that this product has three functions, and the optimum

mounting location for each individual function may conflict with each other, and may

require the use of multiple sensors.

• Remove the cover from the base unit by turning the

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