Kidde Aries Netlink - Miami-2012-handouts.pdf

Kidde DAC School

Welcome! Kidde, Fenwal & Chemetron D&C School Instructor: Ken Koerten Customer Technical Services Manager

INTRODUCTIONS •

Distributor personnel:  Name  Position  Company name & location  Any Addressable Panel Experience??

PRESENTATION SUMMARY • INTRODUCTION

• FEATURES & BENEFITS

• CHANGE OVER LEGACY

• QUESTIONS

3

1

Kidde DAC School

Multi-loop Addressable Panel

Kidde DAC School

Aries NETLink

MLX

FN8000

MULTI-LOOP PANEL

6

2

AGENCY TESTING & LISTING

FM requirements

• •

ANSI/NFPA-72

•

ANSI/UL864-9

ANSI/UL864-9

• •

Canadian ULC-S527-99

January 11, 2011

March 11, 2011

7

7

FORTHCOMING APPROVALS

NYFD

CSFM

Denver

CA - Seismic

Chicago

USCG 8

APPLICATIONS •

•

•

•

Commercial Industrial High Tech Historic

•

Server Rooms

•

Process Control Rooms

•

Data Processing Areas

•

Electronic Switch Rooms

•

Cabinets

•

Turbines

•

Warehouses

•

Power Generation

•

Museums

•

And more

9

3

PROTECTION SYSTEMS •

FM-200

•

Argonite

•

Novec 1230

•

FE-13

•

CO2

•

Dry Chemical

•

Wet Chemical

•

Foam

•

Water Mist

•

Pre-Action

•

Sprinkler/Deluge

•

Low-rise Fire Alarm 10

• INTRODUCTION

• FEATURES & BENEFITS

• CHANGE OVER LEGACY

• QUESTIONS

11

OUT-OF-THE-BOX FEATURES •

2 SLC w/ 255 addresses each

•

4 x 40 Display-Keypad

•

2 NACs

•

2 Release-NACs

•

3 Programmable Form-C relays

•

1 Trouble Form-C relay

•

2 APO rated 2 A each @ 24 VDC

•

2 USB ports for PC & printer

•

2 RS-232 ports for graphics

NEW

NEW

NEW

12

4

OUT-OF-THE-BOX FEATURES •

RS-485 Annunciator network

•

120/240 V 50/60 Hz AC input

•

5.4 A Power supply unit

•

NEMA 1 enclosure

•

4 programmable soft-switches

•

Ground fault detection by circuit

NEW

NEW

NEW

•

10,000 event log capacity

•

Real Time Clock w/ battery

•

Degrade mode operation

•

Battery replacement reminder

NEW

NEW

13

SLC RELAY R-NAC

CITY-TIE

31 Annunciator Devices Max. ATM-L/R 1 - 16

ICM Bus

Remote LED Annunciator 1-16

IIM Bus

Remote User Interface 1 - 15

Printer

PC Connections

24VDC IN

IIM DACT NETWORK

SYSTEM ARCHITECTURE

RS485

RS485

RS485

RS232

RS485

RS232

USB

USB

R-NAC 1 R-NAC 2

User Interface PMU

SLC1

MicroController

NAC 1 NAC 2

24VDC Switching Power Supply (optional)

24VDC Switching Power Supply

SLC2

MCB – Main Control Board

VFR_1 (TBL) VFR_2 (PROG) VFR_3 (PROG)

12VDC Battery

PSU Supervision

12VDC Battery

VFR_4 (PROG)

14

ENCLOSURE OPTIONS: 3-TIER

Global

PSU & PMU

Expansion Backplane

PSU & PMU

Expansion Backplane

PSU & Control Board

Canadian

Expansion Backplane

Expansion Expansion Backplane

PSU & PMU

12VDC Battery

PSU

12VDC Battery

15

5

ENCLOSURE OPTIONS: 2-TIER

Global

Canadian PSU & PMU

Expansion

PSU & PMU

PSU & Control Board

Expansion Backplane

PSU & PMU

12VDC Battery

PSU

12VDC Battery

16

ENCLOSURE OPTIONS - REMOTE

Remote Display-Control Module

Remote LED Annunciator Module 17

EXPANSION CARD CAGE & BACKPLANE

•

6-module positions per backplane

•

4 backplanes max per panel

•

Provides power & communication to modules

18

6

EXPANSION & FUNCTIONAL MODULES •

Panel supports up to 24 modules  SLC (max 6)  Release-NAC  Relay  City-Tie (max 1)  DACT (max 1)*  ICM (max 1)*

NEW

 NIC & FOCC (max 1)*

•

Addressing – no dip switches

* Next Release

19

SLC – MCB & EXPANSION RRM

ASM

Ion

Manual Photo D-A-F Abort Release

Air Sampling

AI

AAM SLC

NAC

ARC •

SLC: MCB  2; Cards  1 each

•

SmartOne Protocol – Backwards Compatible

SLC

– 255 Addresses – No device type restriction – Up to 140 RRMs / unit •

Class A, B and X wiring

•

Disconnect switch

•

Pluggable terminal blocks

Linear Heat

NEW NEW

20

R-NAC – MCB & EXPANSION CARDS •

MCB  4 circuits; Expansion Cards  3 each

•

Field selectable NAC or ARC  ARC - Control Heads, Solenoids & Actuators  NAC - Horns, Strobes, Bells

•

Pluggable terminal blocks

•

NFPA 72 Disconnect switch

•

R-G-Y Status LED‟s

•

Wiring styles:  ARCs: Class A & B  NACs: Class & B

NEW NEW NEW

NEW

•

NACs synchronizeA d

•

„Triple-R‟ Redundancy safeguard

21

7

“TRIPLE-R” REDUNDANCY SAFEGUARD TB1

4 3 21

4 3 21

SLC

RS 485

TB15 J5

J3 RS-232 B

RS-232 A

J8

Watchdog Timer

TB4

NO NC C NO NC C

TB8 TB10

NO NC C

High Watchdog

Low

NAC 2

S2

TB3 - -

TB14 NAC 1

+ + Batt Out

1 2 34

Style 4

J10

1 2 34

TB9

NO NC C

Relay 1 Relay 2 Relay 3 Trouble

Main Microprocessor

USB B

TB5

PSU J12 AC IN L N

240

Release 1

120 TB13

TB12 1 2 3 4

Release 2 TB11

Aux 24 VDC TB2

1 2 34

Combo 1 TB7

1 2 34

Combo 2 TB6

1 2 34

1 2 34

Release Circuit

22

RELAYS – MCB & EXPANSION CARD •

4 Form C Relays

•

Each Independently programmable

•

Contacts rated 3A at 30 VDC / 120 VAC

•

Interlocks management:  EPO  HVAC shutdown  Damper closure  Building fire alarm  BMS systems  Zone status annunciation

23

CITY-TIE MODULE •

3 independently operated circuits

•

Municipal Tie Inputs: – Local Energy – Shunt-Trip Master Box – Reverse Polarity

24

8

DIGITAL ALARM COMMUNICATOR TRANSMITTER (DACT)* •

Transmits system status over phone lines

•

SIA and CID formats supported

•

Transmits:

NEW

 System Status Normal  AC Failure  Low Battery Voltage  Alarm Per Point  System Supervisory  System Trouble  Ground Fault  NAC Trouble  Degraded operation due to microprocessor failure * Next release 25

NETWORKING* •

Robust token-passing, peerto-peer protocol

•

Remote configuration upload

•

Sub-network & grouping options

•

Node-level access protection

•

Network-wide access from single point using ICM

•

Master node option

•

Up to 64 nodes

•

2,040 addresses each node

•

130,560 across network

•

Single or Dual Channel operation

* Next release 26

NETWORK CONNECTIVITY OPTIONS

Optic Fiber

Copper

•

Backplane module

•

Daughter module

•

1 module per panel

•

1 module per panel

•

Generates & boosts communications

•

Noise & interference reduction

•

18 AWG

•

•

4,000 ft

62.5/125 or 100/140 multimode duplex media

•

5,280 ft

* Next release

27

9

SINGLE-ZONE WATERLESS SYSTEM SLC

NAC 1: Pre-Alm NAC 2: Pre-Rel / Rel R-NAC 2: Rel R-NAC 1: Actuators or Control Head

28

TWO-ZONE SYSTEM W/ CONTROL HEAD (AND PRE-ACTION SYSTEM)

Pre-Rel. / Rel. (NAC 1)

ASM

Pre-Alm R-NAC 1: Pre-Action Valve

Rel (NAC 2) Pre-Rel. / Rel. (R-NAC 2) Rel (R-NAC 3)

R-NAC 4: Control Head

Pre-action system CANNOT be aborted!! 29

REMOTE-RELEASE MODULE RRM

RRM

Auxiliary Power Supply

30

10

REMOTE-RELEASE MODULE •

Up to 140 modules per control unit

•

Grouping parameter  - “Simultaneous” activation  - Up to 7 groups of 20 RRMs per group

•

Each module can be in multiple groups

31

PERIPHERAL PRODUCTS

Signaling Line Circuit

RS-232 Communications

PALM

APIC

ORION XT Detector Internet Access*

ASD Detector

RS-485 Communications S2

S1

LK17 LK32 LK16

Out B Out A In B In A W1

+24 V Com PS Flt

A B

*Future

RDCM 1-15

LAM 1-16

Trouble Sup. Sil. Out Pre Alm Alarm Pw r On

Lamp Test Com Ack Reset Silence Drill

LK15

LK14

LK13

LK12

LK11

LK10

LK9

LK8

LK7

LK6

LK5

LK4

LK3

LK2

LK1

16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1

LK31

LK30

LK29

LK28

LK27

LK26

LK25

LK24

LK23

LK22

LK21

LK20

LK19

LK18

32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17

Driver Board* 1-16

32

• INTRODUCTION

• FEATURES & BENEFITS

• CHANGE OVER LEGACY

• QUESTIONS

33

11

CHANGES OVER LEGACY PANELS •

Programmable SLC Style/Class all loops

•

Manual Disconnect switches for SLCs, NACs and R-NAC

•

Configurable SLC loop controller to map degrade mode alarm to a NAC on MCB

•

'Autoconfigure' operation for creating a default EOC output control configuration.

•

Alpha numeric password

•

System restart

•

Entering serial number

•

Expanded RRM groups:7 groups of 20 RRMs per group

34

USER INTERFACE – LOCAL & REMOTE 4 x 40 characters

Soft-Keys

Status LEDs

NEW

System Keys

NEW

35

RS-485 ANNUNCIATOR NETWORK •

Supports 31 remote annunciators  1 to 16 LED Annunciators (R-LAM) NEW  1 to 15 User-Interfaces (RDCM)  1 to 16 LED Drivers (ATM-L & ATM-R)*

R-LAM

RDCM

* Next release 36

12

LED ANNUNCIATOR – REMOTE & LOCAL NEW

•

48 independent LED‟s

•

Three system-level LED‟s:  Power  Trouble  Signal Silenced

•

2 functional switches

•

Dual color LED‟s

Local

Remote 37

INTERNET COMMUNICATION MODULE (ICM) •

Provides Internet connectivity

•

Configuration Program download

•

Network-wide access from single node

•

Automatic email notification

•

Event viewing Distributor Internet

Protected Site

Corporate Loss Prevention * Next Release 38

CONFIGURATION SOFTWARE •

Displays & Day/Night/ Annunciators Weekend

PC-based program

•

Expandable configuration

•

Text-Editing for EOC

•

Soft keys

•

Isolation Macros  Selective input/output isolations  Initiating devices

EOC

Control Board I/O

Network IIM Display Strings Site & System Settings Addressable Devices (SLC) Expandable I/O Modules

Co nfi gu To rati on ol

 Control modules and/or on-board outputs •

Separate Test Logs  Walk Test  Initiating Devices

•

Multi-Alarm Acknowledge

•

Global Alarm Acknowledge

39

13

GROUND FAULT DETECTION •

Voice of Customer  Ground fault diagnosis  Timely detection

•

Implementation  In circuit detection  Push button trigger

•

Benefit  Fast system commissioning  Lower Cost of installation

40

REMOVABLE TERMINALS •

Voice of Customer  Ability to isolate outputs  Easy & quick

•

Implementation  Pluggable & Polarized terminals

•

Benefit  Easy system wiring  Fast system commissioning  Lower Cost of installation

41

HINGED MAIN BOARD •

Voice of Customer  Easy access to PSU  Field replaceable

•

Implementation  Hinged main board  Swings open

•

Benefit  Faster installation  Quick service & checkout

42

14

FLEXIBLE WIRING KNOCKOUTS •

Voice of Customer  Multiple conduit penetration  Large 1” AC

•

Implementation  Triple access knockouts  1” center expansion

•

Benefit  Fewer external junction boxes  Wiring zone separation

43

POWER SUPPLY OPTIONS •

One common PS across all panels: – Less inventory to stock – Common wiring method – 5 years of proven reliability

•

Expandable to 20 Amps per enclosure

•

Charges up to – 165 AH batteries for UL applications – 132 AH batteries for ULC applications 44

SEAMLESS INTEGRATION NO OTHER COMPETITOR CAN MATCH THIS OFFERING RANGE Control

AND LEVEL OF INTEGRATION

Detection

Suppression

SINGLE POINT OF RESPONSIBILITY 45

15

INSTALLED BASE RETROFIT

MIGRATION STRATEGY

46

INSTALLED BASE RETROFIT •

Voice of Customer

•

Implementation

 Reuse existing field wiring & devices

 SmartOne protocol PEGAsys

 Retrofit Kit •

Benefit  Preserve investment  Maintain agency approvals  Maintain competitive position

ARIES NETLink

47

• INTRODUCTION

• FEATURES & BENEFITS

• CHANGE OVER LEGACY

• QUESTIONS

48

16

QUESTIONS?

Kidde DAC School

Intelligent System Overview

• INTRODUCTION

• INTELLIGENT SYSTEM

• SMARTONE DEVICES

• HANDS ON EXERCISE

51

17

SYSTEM OPERATION Initiate Alarms Annunciate Fire Location Notify Occupants Activate Safety Procedures Release Extinguishing System Call Fire Department

52

SEQUENCE OF OPERATION

Flammable-Liquid Fires Fast Response w/ Minimal Delay

Electrical Fires Staged, Sequential Response

53

SEQUENCE OF OPERATION(ELECTRICAL FIRES)

Pre-Alarm

Smoke Detector

Pre-Release w/ Longer Time Delay

Requires confirmation signal Counting- or Cross-Zoned Detectors

Release signal

Upon expiration of delay and no abort

54

18

DEVICES

• INTRODUCTION

• INTELLIGENT SYSTEM

• SMARTONE DEVICES

• HANDS ON EXERCISE

56

INTELLIGENT VS. CONVENTIONAL SYSTEMS SLC Address 6

Address 5

Address 4

Address 3

Address 2

Address 1

Initiation, control, notification, and release via Signaling Line Circui t

Multiple Discreet Initiating Circuits 57

19

SMARTONE INITIATING DEVICES

Sample for fire signatures every 9 sec Sample rate increases to every 2 sec on initial fire-signature detection Issue alarm if 2 of 3 additional samples are positive

58

SMARTONE COMMUNICATIONS Called Broadcast Indexed Polling Potential 255 addresses broken into 8 groups of 32 addresses each Group 1 Group 2 Group 3

0 - 31 32 - 63 64 - 95

59

BROADCASTS Alternating indexed and group polls Indexed poll checks each group for alarm and trouble messages Group poll checks for device presence when index poll has no alarm or trouble messages responding device when index poll has alarm or trouble messages

60

20

POLL PATTERN

Index

Group 1

Index Group 2

Index Group 3

Index

Group 4

Index Group 5

Index Group 6

Index

Group 7 Index

Group 8 Index

Group 1

Pattern repeats continuously

61

WHEN INDEX POLL POSITIVE Sequentially checks addresses until reporting device is found Handshakes with device to determine device message (i.e., alarm or trouble) Confirms message via follow-up handshakes 3 more for alarm 2 more for trouble 62

• INTRODUCTION

• INTELLIGENT SYSTEM

• SMARTONE DEVICES

• HANDS ON EXERCISE

63

21

SMARTONETM DETECTOR

Alarm (By Detector)

(By Detector)

64

DRIFT COMPENSATION Accounts for changes in detectionchamber output over time Factors that can cause changes Dirt Dust Component Aging

65

DRIFT COMPENSATION Smoke Detectors

Detectors Continuously Monitor – Background obscuration levels – Record levels 256 times per day – Compute daily and accumulated averages – Make first drift compensation after 32 days of operation

66

22

INITIAL DRIFT COMPENSATION

Average obscuration level measured during first 32 days of operation replaces factory cleanair reference value

67

EVERY DAY THEREAFTER

Detector Records Background obscuration levels Averages 256 samples per day

Maintains Continuous 32-day rolling average FIFO

68

FACTORY CALIBRATION

Precise smoke obscuration level

Establishes correlation between obscuration levels and detectionchamber outputs

Clean-air reference value

69

23

AFTER FIRST 32 DAYS OF OPERATION

Precise smoke obscuration level

Adversely alters factory correlation between obscuration levels and detection-chamber outputs

New clean-air value after 32 days Factory clean-air reference value

70

INITIALLY-COMPENSATED DETECTOR New smoke-obscuration calibration level Precise smoke obscuration level Restores factory correlation between obscuration levels and detection-chamber outputs

New clean-air value after 32 days Factory clean-air reference value 71

AGING / DIRTY DETECTOR

Current obscuration calibration level

Adversely alters new correlation between obscuration levels and detection-chamber outputs

New clean-air reference value Previous clean-air reference value

72

24

COMPENSATED DETECTOR Adjusted smoke-obscuration calibration level

Current obscuration calibration level

Restores proper correlation between obscuration levels and detection-chamber outputs

Adjusted clean-air reference value Previous clean-air reference value

73

BENEFIT

Takes the same amount of smoke to activate detector regardless of age or state of cleanliness as long as there is no drift error.

74

AUTOMATIC INITIATING DEVICES • CPD-7052 Ionization Detector • PSD-7152 Photoelectric Detector • THD-7252 Heat Detector • DH-2000

Duct Detector

75

25

IONIZATION DETECTOR No Smoke

Smoke Detection

76

IONIZATION DETECTOR Advantages

Disadvantages

– Small particle detector

– Slow response to large particles (i.e., smoldering fires)

– Fast, flaming fires

– Adversely affected by air flow and ambient pressure

– Good confirmation detector – Sensitivity range 0.5 - 1.5 %/ft.

77

PHOTOELECTRIC DETECTOR Light Source

No Smoke

Light Receiver

Smoke Detection

Light Source

Light Receiver

78

26

PHOTOELECTRIC DETECTOR Advantages

Disadvantages

– Large particle detector

– Slow response to small particles (i.e., flaming fires)

– Slow, smoldering fires – Good early-warning detector

– Adversely affected by dark smoke

– Sensitivity range 0.5 3.5 %/ft.

79

HEAT DETECTOR No Heat

Heat Detection Low Resistance

High Resistance

Thermistor Bead

Thermistor Bead

80

HEAT DETECTOR Advantages

Disadvantages

– Activated by the most reliable fire signature

– Slowest response to fires

– Very large Listed spacing

– Fire is large when detected

– Sensitivity range 135 155°F – Good for dusty environment where smoke detector is not desirable

81

27

DH-2000 DUCT DETECTOR

Always use Photoelectric Detector! 82

MANUAL INITIATING DEVICES

AI

Monitor Module

83

SMARTONE MODULES • AI

Monitor Module

• AO

Control Module

• ASM

Addressable Signal Module

• RRM

Remote Release Module

• Loop Isolator Module

84

28

LOOP ISOLATOR

85

SMARTONE OUTPUT DEVICES AO, ASM and RRM Sequentially activated Approximately 1/2-sec for each output NOTE: AOs must be grouped in order to meet NFPA code when 20 or more AOs are to be activated.

86

ADDRESSABLE SIGNAL MODULE

87

29

ADDRESSABLE SIGNAL MODULE FROM PREVIOUS SLC DEVICE

TO NEXT SLC DEVICE

REGULATED 24 VOLT SUPPLY

NAC

88

REMOTE RELEASE MODULE

89

REMOTE RELEASE MODULE TO NEXT SLC DEVICE

FROM PREVIOUS SLC DEVICE

SLC

REMOTE RELEASE MODULE (RRM) 24VDC

PSU

RELEASE

STATUS

RELEASE DEVICE

REGULATED 24 VOLT SUPPLY

90

30

SPECIALTY MODULES • PALM

AnaLASER-II Interface Module

• APIC

Addressable Protocol Interface Card

• AAM

Addressable AlarmLine Module

PALM

APIC

AAM

91

ANALASER® II INTERFACE MODULE

92

AIR-INTELLIGENCE APIC APIC

Addressable Protocol Interface Card

93

31

ADDRESSABLE ALARMLINE MODULE

94

SMARTONE ADDRESSING & REGISTRATION

• Electronically Addressed (except the APIC, AIM) • SmartOne devices Registered into the control unit

95

SMARTONE ADDRESSING & REGISTRATION •

SmartOne devices are addressed via - Handheld Programmer (except APIC, AIM) - FN-8000-ML Menu Procedure (except APIC, AIM)

•

APIC: addressed via Hex1 and Hex2 switches

•

AIM: addressed via LASERNET or control unit.

•

All SmartOne devices are registered via - FN-8000 Menu Procedure - AutoLearn - Configuration Upload

96

32

PROGRAMMER

97

SMARTONETM HAND-HELD PROGRAMMER •

Compact design & user friendly

•

Convenient means to assign device address information

•

Supports all intelligent SmartOne modules

•

AC and battery power operation.

98

SMARTONETM HAND-HELD PROGRAMMER-FEATURES •

Integral detector base

•

Snap-in AI/AO programming adapter

•

SLC interface connectors

•

AC power adapter

•

4 x AA rechargeable batteries-Internal battery Supervision 99

33

SMARTONETM HAND-HELD PROGRAMMER-FEATURES •

Optional carrying case

•

Status & charging LED‟s

•

Auto power save

•

Contract & Backlight Adjustment

•

specific trouble codes

100

SMARTONETM HAND-HELD PROGRAMMERFEATURES –CONTINUED Integral Detector Fixture: - For use w/photo, ion, and thermal detectors -Eliminates need for SLC wiring -Reduces connection time -Optional automatic alarm test (user configurable) -Approx 15 seconds per device -Sequential device addressing (device range selection)

101

SMARTONETM HAND-HELD PROGRAMMERFEATURES –CONTINUED AI/AO module adapter: -Snaps directly to HHP detector fixture -NO wiring or end-of-line resistors required (except NC AI‟s) Reduces connection time -Optional automatic alarm test (user configurable) -Approx 15 seconds addressing time per device -Sequential device addressing (device range selection) 102

34

SMARTONETM HAND-HELD PROGRAMMERFEATURES –CONTINUED SLC “flying leads” -Plug-in type connector -For use with RRM, ASM, and AAM modules -NO external power or endof-line resistors required to program modules.

103

SMARTONETM HAND-HELD PROGRAMMERFEATURES –CONTINUED Menu Navigation Keys

104

ADDRESSING ASM TO PROGRAMMER

SET FOR AUDIO MODE 4.7K

4.7K

105

35

ADDRESSING RRM TO PROGRAMMER

SLC

REMOTE RELEASE MODULE (RRM) 24VDC

PSU

RELEASE

STATUS

Power NOT needed 106

HSSD INTERFACE MODULE Addressed via • LASERNET or Orion Software • Panel Menu Procedure Registered via • Panel Menu Procedure • AutoLearn • Configuration Upload Cannot be addressed via programmer!

107

QUESTIONS?

108

36

HANDS ON EXERCISE

Assign addresses to SmartOne devices

109

Kidde DAC School

Installation, Assembly & Circuits Review

• INTRODUCTION

• INSTALLATION & ASSEMBLY

• WIRING

• HANDS ON EXERCISE

111

37

CONTENT OF BOX-BASE UNIT •

NEMA 1 enclosure with door

•

1 Power Management Board (PMU)

•

1 Power Supply Unit (PSU)

•

Main Circuit Unit board (MCB) with User interface (UI)

•

Hardware Kit

•

Installation configuration kit – Installation manual – Configuration software manual

•

Installation instructions

•

Enclosure door label

•

Installer‟s wiring diagram

112

• INTRODUCTION

• INSTALLATION & ASSEMBLY

• WIRING

• HANDS ON EXERCISE

113

INSTALLATION & ASSEMBLY SEQUENCE 1. Mount the enclosure per 2-4.1 2. Install PMU per 2-4.4 3. Make AC power connection per 2-4.5 4. Install PSU per 2-4.3 5. Install battery per 2-7.4 and 2-7.5 6. Install expansion Card Cage assembly per 2-7.1 7. Install expansion cards per 2-7.2 8. Install MCB w/UI per 2-4.6 9. Make SLC devices and output devices connections per 2-8.4 and 2-8

114

38

CONFIGURATION SEQUENCE 1. Power the system up and perform the following functions per 4-9: – Enter serial number when prompted – Change installer and owner passwords (4-8.2) 2. Configure the system (chapter 3) 3. Perform initiating and output devices tests (chapter 5).

115

SURFACE MOUNT ENCLOSURE INSTALLATION 3-T Enclosure

2-T Enclosure

5-3/8 5-3/8

14-3/8

14-3/8

116

SEMI-FLUSH MOUNT ENCLOSURE INSTALLATION 3-T Enclosure

2-T Enclosure

0.059 inch Thick Trim Ring Trim Ring Dimensions (LXB) • 3-Tier: • 2-Tier:

17-1/2 x 34-5/8 (in) 17-1/2 x 34-5/8 (in) 117

39

POWER MANAGEMENT UNIT INSTALLATION - PRIMARY AC INPUT •

1 Power Supply Unit – 120VAC 50/60Hz, 3.2 A – 240VAC 50/60Hx, 1.6 A

•

2 Power Supply Unit – 120VAC 50/60Hz, 6.4 A – 240VAC 50/60Hx, 3.2 A

•

Each PMU can interface with 2 PSU‟s for a total of 10.8 A @ 27.6 Vdc.

118

POWER MANAGEMENT UNIT INSTALLATION

119

AC POWER CONNECTION

120

40

POWER SUPPLY UNIT •

One common PS across all panels

•

Each PSU provides 5.4 A

•

Can be expanded to 20 A per enclosure with 4 PSU

121

POWER SUPPLY UNIT INSTALLATION Appearance of Voltage-Selector Slide Switch when set for either 120 VAC or 220/240 V

115 V

230 V

(Slide to required position. Default position is 115 VAC.)

Threaded hole for mounting screw

Fastening tab for mounting screw

122

POWER SUPPLY CONNECTIONS

1 2 3

1 2 3 4 5

= = = = =

4

5

White & black wire White wire Green wire Double black wire Double red wire 123

41

BATTERY CONNECTIONS

124

AUXILIARY POWER INPUT CAPACITANCE

Module

Max. Input Capacitance

Addressable Signal/Sounder Module (ASM)

100 µF

Remote Release Module (RRM)

220 µF

Remote LED Annunciator Module (RLAM)

100 µF

Remote Control Display Module (RDCM)

100 µF

470µF max. capacitance per output 125

STANDBY BATTERY CONNECTIONS

126

42

BATTERY CHARGER • High-rate charger • Charges up to - 165 AH batteries for US applications - 132 AH batteries for Canadian applications • Only charges when required • Disconnect Batteries on Alarm condition

127

EXPANSION CARD CAGE ASSEMBLY To PMU 24 Vdc Earth ground

To MCB Communication Terminal (J9) 24 Vdc outputs

To Next Backplane Com Terminal (J10)

128

MAIN CONTROL BOARD (MCB)

129

43

• INTRODUCTION

• INSTALLATION & ASSEMBLY

• WIRING

• HANDS ON EXERCISE

130

MAIN CONTROL BOARD (MCB) IN-B OUT-A

RS485

IN-A

SLC 1 & SLC 2

To RDCM & LAM

OUT-B IN-

OUT-

IN+

OUT+

J8

SLC 1 or 2

J19 or J20

NORM

ISOL

IN-

OUT-

IN+

OUT+

NORM

ISOL

IN-

OUT-

SLC 1

IN+

OUT+

SLC 2 J20

J19

Relay-Contact Rating

NC

RS232 A or RS232 B

TB3

TBL RELAY NC C NO

RS232 B TB3

J2 PMU COMMS OUT

Main Control Board (MCB)

J10 24 VDC IN

Circuits & COM Ports • 2 SLC • 2 NAC • 2 R-NAC • 4 relays • 2 RS232 ports • 2 USB port • 1 24 VDC output • 1 RS485 port on UI

RS232 A

J8 RELAY 3

NO C

Trouble Relay

USB HOST USB DEVICE

J9 BACKPLANE COMMS OUT

NC

TB2

NO C

RELAY 2

NC

TB1

Programmable Relays

RELAY 1

NO C

3.0 A @ 30 VDC (resistive) 3.0 A @ 120 VAC (resistive)

J17

J18

J16

R-NAC 1 OUT+

IN+ IN-

J15 NAC 1

R-NAC 2 OUT-

ISOL

NORM

OUT+

IN+ IN-

OUT-

ISOL

NORM

J17 or J18

OUT+

IN+ IN-

NAC 2 OUT-

ISOL

NORM

OUT+

IN+ IN-

OUT-

ISOL

To Backplane J10

To optional PMU J12

To PMU J3, J4 or J5

NORM

J15 or J15

R-NAC 1 or 2 OUT+

IN+ IN-

R-NAC 1 or 2

OUT-

OUT+

R-NAC 1 & R-NAC 2

IN+ IN-

OUT-

NAC 1 & NAC 2

131

INTERNAL 24VDC POWER CONNECTIONS

132

44

INTERNAL COMMUNICATION CONNECTIONS Jumper for RS485 bus

133

SIGNALING LINE CIRCUIT - ONBOARD

• 2 SLC loops with 255 devices each • No device type restriction •SLC wiring options – Class A – Class A, style 7 – Class B

• Maximum Resistance per loop = 40 Ω • Maximum Capacitance per loop = 0.5 µF

Note: Class A style 7 is now referred to as Class X by NFPA 134

SIGNALING LINE CIRCUIT-EXPANSION •

1 SLC loops with 255 devices each

•

Up to 6 SLC cards per control unit

• •

No device type restriction SLC wiring options – Class A – Class A, style 7 – Class B

•

Maximum Resistance per loop = 40 Ω

•

Maximum Capacitance per loop = 0.5 µF

Note: Class A style 7 is now referred to as Class X by NFPA 135

45

SLC CLASS A WIRING Class A, Style 6 SLC Wiring

P OUT+

IN+

OUT-

PSD7152

S

CPD7052

THD7252

AI

AO

+

+

ASM

RRM

IN-

Do not use looped wire under terminals of detector bases for Models PSD-7152, CPD7052, and THD-7252. Break SLC wire run to provide supervision of connections.

SLC 1 or 2

J19 or J20

To PMU, To PMU, AUX-1 or 2 - AUX-1 or 2 +

Class A, Style 7 SLC Wiring (Loop Isolators required)

136

SLC CLASS B WIRING

P OUT+

IN+

OUT-

S

PSD7152

CPD7052

THD7252

AI

AO

+

ASM

+

RRM

IN-

SLC 1 or 2

J19 or J20 THD7252

To PMU, To PMU, AUX-1 or 2 - AUX-1 or 2 +

Class B, Style 4 SLC Wiring

137

SLC CLASS A WIRING RESISTANCE Resistance Measurement

Ohmmeter

Capacitance Measurement Procedure • Obtain capacitance per foot of wire information from wire manufacturer • Multiply value by total wiring footage Maximum Resistance per SLC Loop = 40 Ω. Maximum Capacitance per SLC Loop = 0.5 µF 138

46

SLC CLASS B WIRING RESISTANCE Jumper Branch 1

Maximum Resistance per SLC Loop = 40 Ω.

Branch 2

Branch 4

Ohmmeter

Resistance Measurement Procedure

Branch 3

• Short the ends of each branch line one at a time. • Measure the resistance from the terminating points at the control unit to the end of the branch line. • Remove the shorting jumper after each branch-line resistance measurement. 139

SLC CLASS B WIRING CAPACITANCE Capacitance per SLC Loop = 0.5 µF Capacitance Measurement Procedure • Obtain capacitance per foot of wire information from wire manufacturer • Multiply value by total wiring footage

140

NOTIFICATION APPLIANCE CIRCUITS

• Regulated 24 VDC, 28 Vdc max. • Wiring: Class A, Style Z or Class B, Style Y • NAC Current: -2.0 A (max., Non-Synchronized) -1.5A (max., Synchronized) • Voltage Drop: 2.0 V (max.)

24 VDC input * Can be programmed for synchronization.

141

47

NOTIFICATION-APPLIANCE CIRCUITS WIRING Class A, Style Z NAC Wiring

• NAC are power limited • Compatible with conventional, ULListed notification appliances such as: • MT Series Multi-Tone Horns and Horn/Strobes • NS Series Horn/Strobes *

Class B, Style Y NAC Wiring

• NH Series Horns • RSS(P) Series Strobes * • Exceeder Series * • Commander Series * Can be programmed for synchronization.

142

NOTIFICATION APPLIANCE CURRENT Use twisted, unshielded, low-capacitance wire

143

RELEASE NOTIFICATION APPLIANCE CIRCUITS

•NAC configuration supports - one synchronized circuit or - non-synchronized circuit • Release configuration supports - one solenoid per circuit - up to 8 actuators per circuit 144

48

TYPICAL RELEASE NOTIFICATION APPLIANCE CIRCUITS WIRING NORM

ISOL

IN-

OUT-

IN+

OUT+

NORM

ISOL

IN-

SLC 1

OUT-

IN+

OUT+

SLC 2 J20

J19

Relay-Contact Rating

NC

TB2

NO C

RELAY 2

NC

TB1

Programmable Relays

RELAY 1

NO C

3.0 A @ 30 VDC (resistive) 3.0 A @ 120 VAC (resistive)

RS232 A

J8 TB3

NC

RELAY 3

NO C

TBL RELAY NC C NO

RS232 A or RS232 B RS232 B

TB3

Trouble Relay

USB HOST USB DEVICE

S

P

S

Power Limited

P

Main Control Board (MCB)

J10 24 VDC IN

J2 PMU COMMS OUT

Supervised

J9 BACKPLANE COMMS OUT

Legend:

J17

J18 R-NAC 1 OUT+

IN+ IN-

J16

J15 NAC 1

R-NAC 2 OUT-

ISOL

NORM

OUT+

IN+ IN-

OUT-

ISOL

NORM

OUT+

IN+ IN-

NAC 2 ISOL

OUT-

S

J17 or J18

NORM

P

OUT+

IN+ IN-

OUT-

ISOL

To Backplane J10

To optional PMU J12

To PMU J3, J4 or J5

NORM

S

P

Notification-Appliance Circuit Notification-Appliance Circuit

R-NAC 1 or 2 OUT+

P +

End-of-Line Resistor 10 k +/- 5%, 0.5 W

IN+ IN-

OUT-

S

+

Blk

+

R-NAC 1 or 2 OUT+

IN+ IN-

OUT-

+

End-of-Line Resistor 10 k +/- 5%, 0.5 W

Red

J17 or J18

Actuator / Protractor Circuit

S R-NAC 1 or 2

10 ohm Current Limiting Resistor Blk

Actuator / Protractor

End-of-Line Resistor 10 k +/- 5%, 0.5 W

Notification-Appliance Circuit

Solenoid Circuit J17 or J18 (Class B, Style Y) In-Line Releasing Device, P/N 06-220023-001 (Must be close nippled to solenoid enclosure)

Or

+

+

Or

OUT+

IN+ IN-

OUT-

P

(Non-Power-Limited when In-Line Device not used) See General Note 3.

Red

In-Line Releasing Device, P/N 06-220023-001 (Must be close nippled to actuator / protractor)

Or Solenoid Circuit J17 or J18 (Class A, Style Z) R-NAC 1 or 2

S

P

In-Line Releasing Device, P/N 76-800000-004 (Must be close nippled to solenoid enclosure) Blk

Red

OUT+

IN+ IN-

OUT-

End-of-Line Resistor 10 k +/- 5%, 0.5 W

(Non-Power-Limited when In-Line Device not used) See General Note 3.

145

RELEASE APPLIANCE CIRCUITS WIRING FOR SOLENOIDS

146

RELEASE APPLIANCE CIRCUITS WIRING FOR ACTUATORS Release Circuits-Actuators CLASS B, Non-Power-Limited Wiring

Compensation resistor Compensation resistor

In-Line Releasing Device. P/N 06-220023-001 (Must be closed nipped to actuator assembly

Do not intermix different types of actuator in the release circuit. When measuring the total release circuit resistance, use an ohmmeter with 10mA maximum current output. 147

49

REMOTE-RELEASING MODULE WIRING SLC (out) SLC (in)

Be sure to connect module casing to earth ground! SLC

REMOTE RELEASE MODULE (RRM) 24VDC

RELEASE

PSU STATUS

24 VDC (in) 24 VDC (out)

Red

Control Head or Solenoid

Blk

Power Limited

4.7kΩ, 0.5W

In-Line Releasing Device

Auxiliary Power Supply N.O. Trouble Contact

148

REMOTE-RELEASING MODULE WIRING SLC (out) SLC (in)

Be sure to connect module casing to earth ground! SLC

In-Line Releasing Device (RRM) REMOTE RELEASE MODULE 24VDC

RELEASE

PSU STATUS

24 VDC (in) 24 VDC (out)

Red

Blk

Red

Blk

Control Head or Solenoid

Power Limited 4.7kΩ, 0.5W Auxiliary Power Supply N.O. Trouble Contact

Control Head or Solenoid

149

REMOTE-RELEASING MODULE WIRING SLC (out) SLC (in)

SLC

REMOTE RELEASE MODULE(RRM) 24VDC

PSU

RELEASE

STATUS

Compensating Resistor 24 VDC(in) 24 VDC(out)

End-of-Line Resistor 4.7kO, 0.5 W

Supervised and Non -Power - Limited Auxiliary Power Supply N.O. Trouble Contact

Initiator Assemblies (P /N 31- 199932 -004 or P/N 93- 191001 -001)

150

50

RELAY CIRCUITS • 4 Form C Relays - 3 programmable - 1 dedicated trouble (Onboard only) • Contact Ratings - 3.0 A @ 30 Vdc (resistive) - 3.0 A @ 120 Vac (resistive)

Onboard Relays

Expansion Relays card 151

RELAY CIRCUITS NORM

ISOL

IN-

OUT-

IN+

OUT+

NORM

ISOL

SLC 1

IN-

OUT-

IN+

OUT+

SLC 2 J20

J19

Relay-Contact Rating

USB HOST USB DEVICE

RS232 A

J8 TB3

NC

RELAY 3

NO C

RS232 A or RS232 B

TBL RELAY NC C NO

RS232 B

TB3

J9 BACKPLANE COMMS OUT

NC

TB2

NO C

RELAY 2

NC

TB1

Trouble Relay

RELAY 1

Programmable Relays

NO C

3.0 A @ 30 VDC (resistive) 3.0 A @ 120 VAC (resistive)

J10 24 VDC IN

J2 PMU COMMS OUT

Main Control Board (MCB)

J17

J18 R-NAC 1 OUT+

IN+ IN-

J16

J15 NAC 1

R-NAC 2 OUT-

ISOL

NORM

OUT+

IN+ IN-

OUT-

ISOL

NORM

OUT+

IN+ IN-

NAC 2 OUT-

ISOL

NORM

OUT+

IN+ IN-

OUT-

ISOL

To Backplane J10

To optional PMU J12

To PMU J3, J4 or J5

NORM

Relay Output Diagram

152

PRINTER AND COMPUTER CONNECTION

Compatible Printers; drivers already installed for these printers • Okidata Microline 186 (USB printer) • Okidata Microline 320 (Both USB and RS232 printers) • Epson FX-890 (USB printer) 153

51

RDCM/LAM INSTALLATION

Surface Mount

Semi-Flush Mount

154

RDCM/LAM CONNECTIONS

155

PERIPHERAL-DEVICES CURRENT

Use chart to estimate the maximum length of wire that can be connected to RS-485 peripheral 156

52

ADDRESSING LAM Addressing a brand new LAM 1. Connect LAM to main board or RS485 network and power up the system. 2. On Power up LAM goes to addressing Mode by flashing green POWER LED. 3. On pressing the ACK key, first LED turns yellow. The first LED correspond to address 1. LAM address can be selected by pressing the ACK key multiple times. 4. After selecting the required Address, press and hold Signal Silence button for 5 sec to confirm the address

157

ADDRESSING LAM Change LAM Address using local LAM buttons 1. Connect LAM to main board or RS485 network and power up system and LAM 2. Press and hold ACK and SIGNAL SILENCE keys for about 5 seconds to put the LAM into addressing Mode 3. When LAM enters into Addressing Mode; green Power LED will be flashing and first LAM LED turned ON 4. The first LED corresponds to address 1. LAM Address can be selected by pressing ACK button multiple times. 5. After selecting the required Address, press and hold Signal Silence button for 5 sec to confirm the address

158

ADDRESSING RDCM Addressing a brand new RDCM 1.Connect RDCM through UI RS485 network and power up system. 2.On Power up RDCM will be in addressing mode, by displaying “Enter New Module Address (1-15):” 3. Enter the required address (1-15) using RDCM Keypad and press “Enter button

”

159

53

ADDRESSING RDCM Change address of RDCM through local Menu 1. Enter 1,2 and 3 using RDCM key pad to enter Into local menu of RDCM. 2. RDCM displays the following options (1) MODULE ADDRESSING (2) CONTRAST ADJUSTMENTS (3) BACKLIGHT SETTINGS (4) MANUFACTURER SERIAL NUMBER 3. Press 1 to select option “MODULE ADDRESSING” 4. RDCM displays “Enter New Module Address (1-15):” 5. Enter the required address (1-15) using RDCM Keypad and press “Enter button

 ” to address the RDCM 160

QUESTIONS?

161

• INTRODUCTION

• INSTALLATION & ASSEMBLY

• WIRING

• HANDS ON EXERCISE

162

54

Kidde DAC School

Configuration software

CONFIGURATION

SOFTWARE

CONFIGURATION SOFTWARE •

PC-based program

Displays & Day/Night/ Annunciators Weekend

EOC

Control Board I/O

Network

•

Expandable configuration

•

Event output EOC

•

New enhanced layout

•

Soft keys

•

Compatible operating systems

IIM Display Strings Site & System Settings Addressable Devices (SLC) Expandable I/O Modules

Co nfi gu To rati on ol

– Windows XP – Windows vista – Windows 7

165

55

WINDOWS TOOL BAR ICONS Print File Save File About

Open File New File

Help Verify Configuration Network Node Map

Send Configuration Receive Configuration

Clear Event Log

Online

Receive Event Log

166

PROJECT DEFINITION Tabs

167

„SLC & EXPANSION MODULE‟ TAB

Click on Add to add an expansion module: -

SLC card R-NAC card Relay card PMU City Tie DACT NIC FOCC

168

56

CONFIGURATION

169

IONIZATION SMOKE DETECTOR

Parameters: Latching / Non-Latching General Alarm List Activation Day / Night Alarm Verification PAS Delay Application Selection Pre-Alarm Threshold Alarm Threshold

170

LOCATION ENTRY BOX

40-Character Device Location

171

57

NEW MONITOR-MODULE TYPES

•

Drill Switch

•

Acknowledge Switch

•

Alarm-Silence Switch

•

Reset Switch

172

ABORT STATIONS

•

Underwriters Laboratories (UL)

•

Reset to Full Delay

•

Freeze and Hold

•

Industrial Risk Insurers (IRI)

173

WATERFLOW

Parameters: Non-Latching Input Activate General Alarm Silenceable

174

58

ADDRESSABLE RELAY (AO)

Parameters: Silenceable • General Alarm Output • Drill Activation • Walk-Test Activation • Sequential Deactivation • Fan Restart

175

REMOTE RELEASE MODULE (RRM) Parameters: Device Address

Release Device Release Circuit Activation Time Non-Power Limited Wiring Dual Solenoid Releasing Release Groups Thermal Cycling

176

„DAY/NIGHT/WEEKEND‟ TAB

Day/Night Settings

Night Settings on Weekends Day Start/Stop

177

59

„ON-BOARD‟-OUTPUTS TAB On-Board Outputs Selection List

178

ACCESS-OUTPUTS BOX Enable/Disable Selection

179

NACS Parameters: 40-Char. Circuit Description General Alarm Output Class A/B Wiring Selection Intelligent NAC Code Pattern Silenceable (with Inhibit and Automatic Periods) Walk Test and Drill Activation Thermal Cycling

180

60

RELEASE CIRCUITS Parameters: 40-Char. Circuit Description

Release Activation Device Release Circuit Actuation Period Non-Power Limited Wiring Dual Solenoid Releasing Thermal Cycling

181

R-NAC CIRCUITS Enable/Disable Selection

182

PROGRAMMABLE RELAYS Parameters: 40-Char. Circuit Description General Alarm Output AC Power Loss Activation Pre-Alarm Condition Activation Supervisory Service Activation Trouble Activation

Thermal Cycling

183

61

„DISPLAYS‟ TAB

Main control unit user interface

Remote Display Control Module Add LED Annunciator Module Add Remote Display Control Module

184

„GLOBAL‟ TAB Central Station

Fire Drill NAC Coded Pattern

Global Timers Nightly Test Start General Alarm Outputs Isolation Macros 1 & 2

185

GLOBAL TIMERS

Parameters: AC Failure Delay (0-180 min or 0-12 hours) AO Sequential Deactivation Timer ( 5-15 seconds) Alarm Verification Timer (60-180 seconds) PAS Investigation Timer (0-180 seconds)

186

62

ISOLATION MACROS

ADD Devices or Circuits

Functional Description

DELETE Devices or Circuits

Isolation Command View Box

CLEAR MACRO

187

SELECTIONS FOR MACROS Device/Circuit Selection Window

188

DEVICE RANGE

Range Start Range End

189

63

MODULE CONFIGURATION

ADDING MODULES

Click to add RDCM/LAM

Click to add expansion module

191

ADDING EXPANSION MODULE

Click on Add to add an expansion module: -

SLC card R-NAC card Relay card PMU City Tie DACT NIC FOCC

192

64

ADDING EXPANSION CARD

1. Click on Add

2. Click to add to expansion card e.g. SLC Card

193

EXPANSION CARD ADDRESSES Tow (2) Important Expansion Card Addresses 1. Physical address: • Identifies the physical address identifies the slot in the expansion card cage Numbering begins with the first slot from the left of first expansion car cage. • Up to 24 expansion cards are supported per control unit • The physical address of the last slot on the forth expansion cage is 24 2. Logical address: identifies • The expansion card number for a particular type of expansion module. e.g., SLC 3, R-NAC 3, Relay 1, etc •

194

ADDING SLC CARD

1. Click on Add

2. Click to add to expansion card e.g. SLC Card

195

65

PHYSICAL ADDRESS OF SLC CARD

Physical address

Expansion card cage

1 2 3……6 • Physical address identifies slot in expansion card cage • Numbering begins with first slot from left of first card cage • Up to 6 cards on card cage & 24 expansion cards per control unit •Physical address of the last slot on the forth expansion cage is 24 196

LOGICAL ADDRESS OF SLC CARD

Logical address Type in Owner Location. e.g., Zone 3

Select SLC wiring class option

Click OK to complete SLC card addition • Logical address identifies the SLC loop number • Onboard SLC loops assigned logical addresses 1 & 2 from factory • Expansion SLC card logical address begins from 3 • Up to 8 SLC loops are supported; 2 onboard and 6 expansion cards.

197

ADDING R-NAC CARD

1. Click on Add

2. Click to add to R-NAC Card

198

66

LOGICAL ADDRESS OF R-NAC CARD

Logical address Type in Owner Location. e.g., Zone 3

Click OK to complete R-NAC card addition

• Logical address identifies the R-NAC expansion card number •Expansion R-NAC card logical address begins from 1 with the first R-NAC card added

199

ADDING RELAY CARD

1. Click on Add

2. Click to add to Relay Card

200

PHYSICAL ADDRESS OF RELAY CARD

Physical address

Expansion card cage

1 2 3……6

• Physical address identifies slot in expansion card cage • Numbering begins with first slot from left of first card cage • Up to 6 cards on card cage & 24 expansion cards per control unit •Physical address of the last slot on the forth expansion cage is 24 201

67

LOGICAL ADDRESS OF RELAY CARD

Logical address Type in Owner Location. e.g., Zone 3

Click OK to complete Relay card addition

• Logical address identifies the Relay expansion card number •Expansion Relay card logical address begins from 1 with the first Relay card added

202

ADDING CITY TIE CARD

1. Click on Add

2. Click to add to Relay Card

203

PHYSICAL ADDRESS OF CITY TIE CARD

Physical address

Expansion card cage

1 2 3……6

• Physical address identifies slot in expansion card cage • Numbering begins with first slot from left of first card cage • Up to 6 cards on card cage & 24 expansion cards per control unit •Physical address of the last slot on the forth expansion cage is 24 204

68

CONFIGURING CITY TIE CARD

Type in Owner Location

Select type of reporting

Click OK to complete configuration

205

ADDING CITY TIE CARD

1. Click on Add

2. Click to add to PMU

206

CONFIGURING NEW PMU Check if PMU will Be charging battery

Type in Owner Location Check to supports Auxiliary 1/2 power output as a resettable circuit. Check if 2 PSU will be connected to PMU Click OK to complete configuration

207

69

ADDING RDCM

Corresponds to the beginning or continuation of addition of RDCMs

Click to add RDCM This should correspond with the total number of RDCMs connected to the control unit

208

CONFIGURING RDCM

• Check the Master box to designate this RDCM the master.

209

ADDING RDCM

Corresponds to the beginning or continuation of addition of LAMs

Click to add LAM

This should correspond with the total number of LAMs connected to the control unit

210

70

CONFIGURE LAM

Type in Owner location Check to enable audible notification Check to enable this LAM component with PSU supervision

211

QUESTIONS?

212

HANDS ON EXERCISE

213

71

Kidde DAC School

Event output control (EOC)

EOC TAB

EOC tab

Click on edit to open text editor

215

EOC TEXT EDITOR Toolbar

Menu

216

72

AGENDA • EOC OPERATORS • EOC EXAMPLES • „C‟ IDENTIFIER • „Q‟ VARIABLE • HANDS ON EXERCISE

217

EVENT OUTPUT CONTROL PROGRAMMING Basic Program Structure Inputs = Outputs Input/condition part

Output/Action part

Syntax Ln:k = U Where n= SLC loop number (same as logical address) k = Initiation device address U= Output

Example: L1:1=SG1 If initiating device with address1 on SLC loop 1 is active then turn on SG1. 218

DESIGNATION OF INITIATING DEVICES

•

All initiating devices specified by the loop number followed by colon followed by the device address, e.g., L1:25 (e.g., AI with address 25 on SLC1) L2:1 (e.g., PHOTO detector with address 1 on SLC 2) L3:105 (e.g., AIM with address 105 on SLC 3) L4:213 (e.g., ION detector with address 213 on SLC 4)

219

73

EOC OUTPUT SYNTAX Onboard NAC, R-NAC and Relay circuits, have output syntax that is the same as FN6000: • SG1, SG2, SG3, SG4 for NACs; • AR1, AR2 for Release; and • RY1, RY2, RY3 for Relays.

Expansion NAC Circuits Syntax

SGr:k Circuit number on expansion card Logical address of R-NAC card Example: SG1:1 indicate NAC1 on R-NAC card1

220

EOC OUTPUT SYNTAX Expansion Release Circuits Syntax

ARr:k Circuit number on expansion card Logical address of R-NAC card Example: AR1:2 indicates release circuit 2 on R-NAC expansion card1 Note: R-NAC circuit must be configured as „Release‟; the default is NAC

221

EOC OUTPUT SYNTAX

Expansion Release Circuits Syntax

RYr:k Circuit number on expansion card Logical address of Relay card For example: RY1:1 indicates relay circuit 1 on relay card 1

222

74

ECO “AND” OPERATOR The “AND” Operator

“*” Example: L1:1*L1:2=SG1 If initiating devices with addresses 1 and 2 on SLC loop 1 are active then turn on SG1.

223

EOC “OR” OPERATOR

The “OR” Operator “+” Example: L1:1+L1:2=SG1 If initiating devices with addresses 1 or 2 on SLC loop 1 are active, then turn on SG1.

224

EOC “THRU” OPERATOR The “THRU” Operator “#” Example: (L1:1#10)=SG1 If any initiating devices with addresses 1 thru 10 on SLC loop 1 is active then turn on SG1.

225

75

BRACKET/PARENTHESIS Brackets specify order of operation “(

)”

Examples: 1.) L1:1*L1:10+L1:15#20=SG1 2.) (L1:1*L1:10)+(L1:15#20)=SG1 3.) L1:1*(L1:10+(L1:15#20))=SG1 Brackets define exact meaning

226

COMMA

Activating Multiple outputs “,” Example: L1:1=SG1,RY1,L1:8 Separate all specified outputs by a comma.

227

EOC “DELAY” OPERATOR The “DELAY” Operator “D” Example: D(L1:1,30)=SG1 When device with address 1 on SLC loop 1 activates, wait 30 seconds and then turn on SG1.

228

76

DELAY OPERATOR CHARACTERISTICS



Delay is specified in seconds



Single delays cannot exceed 3600 seconds



Delays longer than 3600 seconds can be achieved buy using identifiers

229

EOC “GREATER THAN” OPERATOR The “GREATER THAN” Operator “(Input)>1” Example: (L1:1#10)>1=SG1 When more than one initiating device is active from addresses 1 thru 10 on SLC loop 1, turn on SG1. NOTE: Works for up to (>9)

230

EOC “ABORT” OPERATOR “D(Input,Delay,Abort)” Example: D(L1:1,30,L1:10)=AR1 During countdown, if abort with address 10 on SLC loop 1 is activated, execute abort per defined abort type. Abort Characteristics 



Do not use “+”, or “#‟‟ when specifying multiple aborts. Do not assign aborts to an identifier and then sub in the identifier. 231

77

EOC “I” IDENTIFIER “I” Example: (L1:1#10)=I1 When an initiating device from addresses 1 to 10 on SLC loop 1 actives, set I1 and increment I1 on subsequent device activations.

232

IDENTIFIER CHARACTERISTICS









Identifiers must be defined on the right side of the equation before they can be used on the left side. Identifiers must never appear on the right side of the equation after they appear on the left side. Identifiers should only appear once on the right side of the equation. Up to 255 unique identifiers can be used (I1 –I255)

233

SIGNAL CIRCUIT ACTIVATION SPECIFIER “SG1/60” Example: L1:1+L1:2=SG1/60 L1:1*L1:2=SG1:1/120 When initiating device 1 or 2 on SLC loop 1 activates turn on SG1 @ 60BPM. When initiating device 1 and 2 on SLC loop 1 are active, turn on SG1 on R-NAC card 1 @ 120 BPM

234

78

SIGNAL CIRCUIT ACTIVATION SPECIFIER Technique works for: /60 = 60 Beats per minute /120 = 120 Beats per minute /C = On constant /T = Temporal code three

235

EOC “NOT” OPERATOR “N” Example (Input): L1:1*NL1:2=SG1 When initiating device 1 on SLC loop 1 is active and initiating device 2 on SLC loop 1 is not active then turn on SG1

Example (Output): L1:1+L1:2=SG1 L1:1*L1:2=NSG1 When initiating device 1 or 2 on SLC 1 is active then turn off SG1. When initiating devices 1 and 2 are active then turn off SG1.

236

PRE ALARM ADJUSTMENT

“Input=Set-point=Devices to be changed” Example: (L1:1#50) = 0.9 = P(L1:1#50) When any initiating device from 1 thru 50 on SLC loop 1 activates, then change pre-alarm threshold on devices 1 thru 50 to .9 %/FT on SLC loop 1.

237

79

ALARM ADJUSTMENT

“Input=Set-point=Devices to be changed” Example: P(L1:1#50)=1.3=(L1:1#50) When any initiating device from 1 thru 50 on SLC loop 1 goes into pre alarm, then change alarm threshold on devices 1 thru 50 on SLC loop 1 to 1.3 %/FT

238

EOC “TROUBLE” OPERATOR “T(Input)” Example: T(L1:1)=SG1 When device 1 on SLC loop 1 goes into “trouble” then turn on SG1.

239

EOC “PRE-ALARM” OPERATOR “P(Input)” Example: P(L1:1)=SG1 When initiating device 1 on SLC loop 1 goes into PreAlarm then turn on SG1.

240

80

EOC GENERAL TROUBLE “GT” OPERATOR “GT” Example: GT=SG1 When the panel goes into trouble for any reason then activate SG1. Outputs will de-energize when trouble clears

241

GENERAL SUPERVISORY “GS” OPERATOR “GS” Example: GS=SG1 When the panel goes into supervisory for any reason then activate SG1. Outputs will de-energize when supervisory clears

242

PROGRAM COMMENTS

“$” Example: $ Release sequence, data storage area When a character of a line is “$”, the following characters on the line are ignored.

243

81

GENERAL EOC RULES



128 characters per EOC Line



255 EOC Lines

244

• EOC OPERATORS • EOC EXAMPLES • „C‟ IDENTIFIER • „Q‟ VARIABLE • HANDS ON EXERCISE

245

BASIC SUPPRESSION SYSTEM EXAMPLE Consider the following application. Smoke detectors, abort station and manual releases on SLC loop 1

AR1

SD 1

SD 2

SD 3

SG1

SG1

SD 4

SD 5

ABORT 10

SD 6

Manual Release 11

246

82

BASIC SUPPRESSION SYSTEM Sequence of operation: 1.) Horns activate 60/BPM on first detector alarm 2.) Horns change to 120/BPM on more then one detector, (pre-release) 3.) 30 second delay (Detector activation) 4.) 10 second delay (Manual release activation) 5.) Manual release overrides abort 6.) Horns change to steady on release

247

BASIC SUPPRESSION SYSTEM EOC as follows: 1. (L1:1#6)=SG1/60,I1 2. (I1)>1=SG1/120 3. D((I1)>1,30,L1:10)+D(L1:11,10)=SG1/C,AR1

248

BASIC MAINTENANCE BYPASS EXAMPLE Consider the following application with smoke detector 1 and AI2 on SLC loop 1

SD 1 SG1

SG1

Keyed Maintenance Bypass attached to AI 2

83

BASIC MAINTENANCE BYPASS



L1:1 =Smoke detector on SLC loop 1



L1:2 =AI on SLC loop 1 programmed for supervisory trouble and connected to a keyed switch



SG1 = Output to be bypassed

250

BASIC MAINTENANCE BYPASS Sequence: 1.) If detector activates and maintenance bypass is not on, then active horns 2.) If detector activates and maintenance bypass is on, then do not active horns 3.) If maintenance bypass activates and detector is active, then shut off horns

251

BASIC MAINTENANCE BYPASS EOC Example Line 1.)

L1:1*NL1:2=SG1

Checks the condition of the maintenance bypass before activating SG1. Line 2.)

L1:1*L1:2=NSG1

Is only in the program to account for a condition whereby someone forgets to activate the bypass and turns on the bypass after the output is activated.

252

84

• EOC OPERATORS • EOC EXAMPLES • „C‟ IDENTIFIER • „Q‟ VARIABLE • HANDS ON EXERCISE

253

“C” STATE IDENTIFIER •

The “C” identifier is a state condition which can be set when a defined set of conditions are met within the EOC program

•

Once Set, the “C” identifier will remain set until it is told to de-activate with a not C statement or a panel reset is done

•

The “C” identifier can move from either side of the equals sign as needed.

254

“C” STATE IDENTIFIER

The C Identifier IS

POWERFUL !!! 255

85

EXAMPLES USING THE “C” IDENTIFIER Consider the following application

PALM 20 SD 1

SD 2

SD 4

SD5

SD 3

SLC 1

SG1

SG2 SD 6

SLC 2 PALM 21

256

EXAMPLES USING THE “C” IDENTIFIER Application Sequence of Operation 1. If either ORION is in alarm then SG1 is active 2. If both ORION are not active then turn off SG1 3. If a spot smoke detector activates then SG1 comes on and stays on until reset is pressed.

257

EXAMPLES USING THE “C” IDENTIFIER EOC Program: Line 1.)

L1:20+L1:21=SG1

Line 2.)

NL1:20*NL21=NSG1

Line 3.)

L1:1#6=SG1

258

86

EXAMPLES USING THE “C” IDENTIFIER Correct EOC Program: Line 1.)

L1:20+L1:21=SG1

Line 2.)

(NL1:20*NL21)*NC1=NSG1

Line 3.)

L1:1#6=SG1,C1

259

EXAMPLES USING THE “C” IDENTIFIER Consider the following application: Sprinkler Zone 1 = AR1

Sprinkler Zone 2 = AR2

HD 2

HD 1

Sprinkler Zone 3 = AR3

Sprinkler Zone 4 = AR4

HD 3

HD 4

260

EXAMPLES USING THE “C” IDENTIFIER Pipe and pump limitations require: 









If zone 1 is active, Zone 2 can activate but 3 and 4 must be disabled. If zone 2 is active, Zone 1 or 3 can activate but zone 4 must be disabled. If zone 3 is active, Zone 2 or 4 can activate but zone 1 must be disabled. If zone 4 is active, Zone 3 can activate but 1 and 2 must be disabled. No more than 2 zones can ever be active.

261

87

EXAMPLES USING THE “C” IDENTIFIER Example Code: 1.) L1:1*NC3*NC4*NC5=AR1,C1 2.) L1:2*NC4*NC5=AR2,C2 3.) L1:3*NC1*NC5=AR1:1,C3 4.) L1:4*NC1*NC2*NC5=AR1:2,C4 5.) (C1#C4)>1=C5

262

EXAMPLES USING THE “C” IDENTIFIER Consider the following Application: L1:1

= AI connected to a momentary switch

SG1 = SIG circuit

263

EXAMPLES USING THE “C” IDENTIFIER

Application Sequence of Operation: 



After the momentary switch is depressed three times, the signal circuit is activated. (Count to Three)

264

88

EXAMPLES USING THE “C” IDENTIFIER Line 1.) L1:1*NC1*NC2*NC3*NC4= C1 Upon activation of device 1 on SLC loop 1 the states of C1,C2,C3, and C4 are checked. If C1 thru C4 are not active, C1 is set. Line 2.) NL1:1*C1=NC1,C2 When device 1 on SCL loop 1 is released the condition of C1 is checked. It will be active so C1 is shut off and C2 is set Line 3.) L1:1*C2=NC2,C3 When device 1 on SLC loop 1 is pressed the second time, the condition of C2 is checked. It will be active so C2 is shut off and C3 is set

265

EXAMPLES USING THE “C” IDENTIFIER Line 4.) NL1:1*C3=NC3,C4 When device 1 on SLC loop 1 is released the second time, the condition off C3 is checked. It will be active, so C4 is set. Line 5.) L1:1*C4=NC4,SG1 When device 1 on SLC loop 1 is pressed for a third time, the condition of C4 is checked. It will be active, so C4 is reset and SG1 is turned on.

266

EXAMPLES USING THE “C” IDENTIFIER Complete EOC 1.) L1:1*NC1*NC2*NC3*NC4= C1 2.) NL1:1*C1=NC1,C2 3.) L1:1*C2=NC2,C3 4.) NL1:1*C3=NC3,C4 5.) L1:1*C4=NC4,SG1

267

89

EXAMPLES USING THE “C” IDENTIFIER Complete EOC 1.) L1:1*NC1*NC2*NC3*NC4= C1 2.) NL1:1*C1=NC1,C2 3.) L1:1*C2=NC2,C3 4.) NL1:1*C3=NC3,C4 5.) L1:1*C4=NC4,SG1

268

• EOC OPERATORS • EOC EXAMPLES • „C‟ IDENTIFIER • „Q‟ VARIABLE • HANDS ON EXERCISE

269

INCREMENTAL VARIABLE “Q” Example: L1:1=I1 I1=Q1 Q1>4=SG1 If initiating device with address 1 on loop 1 is active set I1. Assign incremental value Q1 to I1 and when I1 becomes true more than 4 times activate SG1.

270

90

„Q‟ IDENTIFIER CHARACTERISTICS







•

Identifiers must be defined on the right side of the equation before they can be used on the left side. Identifiers must never appear on the right side of the equation after they appear on the left side. Identifiers should only appear once on the right side of the equation. Once activated and assigned a non-Zero value, can only be reassigned to its initial Zero value by the subsequent execution of another EOC statement that re-initializes it to Zero via the “NOT” Operator or a successful system reset operation.

271

• EOC OPERATORS • EOC EXAMPLES • „C‟ IDENTIFIER • „Q‟ VARIABLE • LAM OUPUT • HANDS ON EXERCISE

272

LAM OUTPUT SYNTAX Syntax for referencing LAM LEDs

LEDr:k LED number LAM Logical address Example: LED1:1 indicates LED number 1 on LAM module 1

273

91

EOC EXAMPLE WITH LAM OUTPUTS L1:1#5=LED1:1,I1 I1>1=SG1,LED1:2,NLED1:1,I2 D(I2,30)=AR1,SG2,LED1:3,NLED1:2 If any of the initiating devices with addresses 1 through 5 on loop 1 is active turn on LED1 on LAM1 and set I1. If more than 1 initiating device is active, activate SG1, turn on LED2 on LAM1 and turn off LED1 on LAM1, assign I2. If I2 is true, delay 30 seconds and activate onboard RNAC circuit 1, activate SG2, turn on LED3 on LAM1 and turn off LED2 on LAM1 274

QUESTIONS?

275

• EOC OPERATORS • EOC EXAMPLES • „C‟ IDENTIFIER • „Q‟ VARIABLE • LAM OUPUT • HANDS ON EXERCISE

276

92

D&C SCHOOL

NETWORKING

NETWORKING •

Up to 64 nodes

•

Remote configuration upload

•

2,040 addresses each node

•

Node-level access protection

•

130,560 across network

•

•

Robust token-passing, peerto-peer protocol

Network-wide access from single point using ICM

Node 1

Node 2

Node 64 278

278

NETWORK CONNECTIVITY W/ CU CABLE

Ch 1

Ch 2

Ch 1

Node 1

Node 2

•

Backplane module

•

Style 4, 6 & 7

•

Ch 1

Ch 2

1 module per node

Ch 2

Node 3 •

Ch 1

Ch 2

Node 64

2-Conductor twisted shielded cable

•

18 AWG, 4,000 ft

279

279

93

NETWORK CONNECTIVITY W/ OPTIC FIBER Ch 1

Ch 2

Ch 1

2c Cu Cables Per Ch.

Node 1

2 F.O.Cables /channel

Node 2

SerialComm module with Fenwal software

•

External module(s) in wall enclosure

•

24VDC from FACP

•

Style 4 – 1 module per node

•

Style 6 & 7 – 2 modules per node • 8.3/125 um SM Cable: 12 miles Mixed Cu-OF network

•

•

Ch 2

Node 64

62.5/125 um MM cable: 1 Mile

280

280

NETWORKING CARD INSTALLATION

Inserting NIC card into Card cage slot

Network Interface Card (NIC)

281

281

FOCM INSTALLATION

282

282

94

NIC RS485 WIRING DIAGRAM – DUAL CHANNEL

NIC Communications Circuits CH1 – CH2 (J12 – J13) Voltage: Current: Recommended Wire: Max. Wire Length:

Per RS-485 Standard (-7.5 to +12.5 Vdc Max) Per RS-485 Standard (250mA Max short circuit) Twisted, shielded, low-capacitance, fire-alarm wire 4,000 Ft. per twisted pair

Connector (FIBER OPTIC) 2 X ST Connectors

283

FOCM WIRING DIAGRAM – DUAL CHANEL

284

284

NETWORKING CONFIGURATION

95

NETWORK CONFIGURATION

Click on Add to add an expansion module: - SLC card - R-NAC card - Relay card - PMU - City Tie - DACT - NIC - FOCM

286

286

ADDING NIC

1. Click on Add

2. Click to add NIC

287

287

PHYSICAL ADDRESS OF NIC

Physical address

Expansion card cage

1 2 3……6 • The physical address identifies the slot in the expansion card cage • Numbering begins with the first slot from the left of first expansion card cage • up to six (6) expansion card can be added to a card cage and 24 expansion cards are supported per control unit; the physical address of the last slot on the forth expansion cage is 24 288

288

96

NETWORK CONFIGURATION OPTIONS

289

289

NETWORK CONFIGURATION OPTIONS Option

Function

Node Number

Reference local node of networked control units. Up to 64 nodes per network.

Channel 1

Check this box if the network messages will be transmitted over communication channel 1 communication. Checking only Channel 1represents a single-channel network communication configuration. Checking both Channel 1 and Channel 2 represents dual-channel network communication configuration.

Channel 2

Check this box if the network messages will be transmitted over communication channel 2. Checking only Channel 2 represents a single-channel network communication configuration. Checking both Channel 1 and Channel 2 represents dual-channel network communication configuration.

Group Number

Reference the autonomous sub-networks or groups that the local node belongs to. There are 65 possible groupings, numbered 0 to 64.

Time Synch Period

Specify how often the system synchronizes the clock with the other panels in the network.

Network Reset Event

Checking this box enables events from this node to be reset from a remote node.

Network Silent Event

Checking this box enables events from this node to be silenced from a remote node.

Log All Network Events

Checking this box enables events on entire network to logged in local node event log

Process Group 0

Checking this box assign a master node privileges to the local node.

Channel 1 Left Fiber

Check this box if incoming network messages through channel 1 will be transmitted over fiber optic cable

Channel 1 Right Fiber

Check this box if outgoing network messages through channel 1 will be transmitted over fiber optic cable

Channel 2 Left Fiber

Check this box if incoming network messages through channel 2 will be transmitted over fiber optic cable

Channel 2 Right Fiber

Check this box if outgoing network messages through channel 2 will be transmitted over fiber optic cable

290

290

NETWORK ACTIVATION

97

NETWORK ACTIVATION

292

292

NETWORKING ACTIVATION

293

293

NETWORK ACTIVATION

294

294

98

NETWORK EOC PROGRAMMING

NETWORK EOC PROGRAMMING EOC Syntax Fx:Ln:k Where x = node number n = SLC loop number k = Initiating device address Example F1:L1:4+F2:L3:5 = SG1 If initiating device with address 4 on SLC 1 of node 1 is active or initiating device with address 5 on SLC3 of node 2 is active then turn SG1 on.

EOC EXAMPLE Write an EOC for the following sequence of operation 1.

If photo detector with address 3 on SLC1 or ION detector with address 4 on SLC 2, both on node 1, in alarm then turn on SG1 at 60bpm

2.

If ASD with address 5 on SLC 3 on node1 is in alarm then turn SG2 on at 60bpm

3.

If alarm on both 1 and 2 above, then turn on SG1/120 and SG2/120.

4.

Delay 15 seconds and if abort with address 30 on SLC1 of node 1 is not pressed, then activate AR1 and turn on SG1/C and SG2/C.

5.

If either devices with addresses 5 and 6 on SLC 1 and 2 respectively of node 2 is in alarm, and either sequence 1 or 2 above is in alarm, then, delay for 15 seconds and activate AR1 on node 1 and turn on SG1/C and SG2/C on node 1.

99

EXAMPLE EOC L1:3+L2:4=SG1/60,I1 L3:5=SG2/60,I2 I1*I2=SG1/120,SG2/120,I3 D(I3,30,L1:2)=AR2, SG1/C,SG2/C (F1:L2:4+F1:L3:5)*(F2:L1:5+F2:L2:6)=C1 D(C1,15)=AR2, SG1/C,SG2/C

298

QUESTIONS

DETECTION

AND

ALARM SCHOOL

DACT, ICM, BACNET

100

DIGITAL ALARM COMMUNICATOR TRANSMITTER (DACT) •

Transmits system status over phone lines

•

SIA and CID formats supported

•

Transmits: – System Status Normal – AC Failure – Low Battery Voltage – Alarm Per Point – System Supervisory – System Trouble – Ground Fault – NAC Trouble – Degraded operation due to microprocessor failure

INTERNET COMMUNICATION MODULE (ICM) •

Provides Internet connectivity

•

Configuration Program download

•

Network-wide access from single node

•

Automatic email notification

•

Event viewing

•

Modbus TCP/IP communication

Distributor Internet

Corporate Loss Prevention

Protected Site

302

MODBUS

Modbus RTU

•

Configured via RS-232

•

Supports all points on 28 MLIC network nodes – 255 points per loop – Up to 2040 points system – Up to 57,120 points per network

•

•

Can support 64 MLIC network nodes with 3 Modbus nodes Supports additional 50 C variable registers

Modbus TCP/IP

• Configured via ICM • Supports all points on 28 MLIC network nodes   

255 points per loop Up to 2040 points system Up to 57,120 points per network

• Can support 64 MLIC network nodes with 3 Modbus nodes • Supports additional 50 C variable registers

101

BACNET INTERFACE MODULE (BIM)

•

High performance Building Automation multi-protocol gateway

•

BACnet Testing Lab approved

•

Converts panel Modbus data via rs232 to BACnet objects available to clients on TCP/IP

•

Each module can support up 1250 points

•

Up to 2 BIMs can be added to a control unit

304

DACT EXPANSION CARD INSTALLATION

Inserting DACR card into Card cage slot

Digital Alarm Communicator Module (DACT) 305

DACT EXPANSION CARD WIRING

306

102

ICM EXPANSION CARD INSTALLATION

Inserting ICM card into Card cage slot

Internet Communication Module (ICM) 307

ICM WIRING

308

DACT CONFIGURATION

103

DACT CONFIGURATION

Click on Add to add an expansion module:

-

SLC card R-NAC card Relay card PMU City Tie DACT NIC FOCM ICM

310

ADDING DACT

1. Click on Add

2. Click to add NIC

311

PHYSICAL ADDRESS OF DACT

Physical address Expansion card cage

1 2 3……6 • The physical address identifies the slot in the expansion card cage • Numbering begins with the first slot from the left of first expansion card cage • up to six (6) expansion card can be added to a card cage and 24 expansion cards are supported per control unit; the physical address of the last slot on the forth expansion cage is 24 312

104

DACT CONFIGURATION OPTIONS

313

DACT CONFIGURATION OPTIONS Option

Function

Owner Location

Reference location name for DACT module.

Style

Select either local only communicator or network-wide communicator.

Channel 2 Enabled

By selecting this check box, the DACT module will immediately attempt to dial out on the secondary phone line if the primary phone line fails.

Call is Forwarded

By selecting this check box, the DACT module performs a test on both the Primary and Secondary phone lines at least once every 4 hours.

Blind Dialing

By selecting this check box, the DACT module will dial regardless of whether the it detects a dial tone.

Protocol

Two protocols are available from the drop-down list: • SIA DC-05-1999.09 Ademco Contact ID • SIA DC-03-1990.01(R2003.10)

Primary Phone #

Enter the primary phone number. 20 characters are allowed.

Secondary Phone #

Enter the secondary phone number. 20 characters are allowed.

Account Number 1

10 alphanumeric characters are allowed

Country Code

Select United States, Canada, or India

Periodic Test

24 hours, 12 hours, 4 hours. Use the up/down arrows to set the Periodic Test Start (H:M):time. 314

ICM CONFIGURATION

105

ICM IP ADDRESS •

IP (Internet Protocol) address must be configured before internet communication can be established with panel.

•

Default IP address is 0.0.0.0

•

Two IP addressing options: - Automatic IP address - Manual IP address

AUTOMATIC IP ADDRESS •

The ICM default IP address of 0.0.0.0 automatically enables its Dynamic Host Configuration Protocol (DHCP).

•

If a DHCP server exists in the network to which the ICM is being connected it supplies the ICM with an IP address, gateway address, and sub-net mask when the ICM boots up.

•

If DHCP server does not exist, the ICM responds with a diagnostic error; the red Diagnostic light emitting diode (LED) blinks continuously and the green Status LED blinks five times if no DHCP server is present.

•

If no DHCP exist, pursue manual IP address option

MANUAL IP ADDRESS •

The IP address must be configured manually if no DHCP server exists

•

The recommended way to accomplish this is to connect a laptop or PC to the serial port of the ICM

NOTE: ICM DOES NOT HAVE TO BE POWERED FOR THIS OPERATIONS 318

106

MANUAL IP ADDRESSING PROCEDURE After connecting ICM to computer as demonstrated on previous slide, perform the following to manually assign the ICM an IP address via the serial port 1.

Activate a terminal emulation program such as HyperTerminal with communications settings of 9600 baud, 8 bits, no parity, 1 stop bit, and no flow control.

319

MANUAL IP ADDRESSING PROCEDURE 2.

Cycle the ICM's power off, and then back on, to enter Setup (i.e., Configuration) Mode. A self-test begins after power-up, and the red Diagnostic LED starts blinking after which there is only one second to enter three lower case "x" characters.

Note: The easiest way to enter Setup Mode is to hold down the "x" key at the terminal (or emulation program) while powering up the ICM.

3.

Select 0 (Server Configuration) and follow the prompts to access the IP address.

4. Enter the new IP Address, gateway, and subnet (as needed). Note: When configuring the ICM manually, obtain the appropriate IP Address, gateway address, and sub-masks from the local network administrator..

MANUAL IP ADDRESSING PROCEDURE 5. Select 9 to save the configuration and exit Setup Mode; the ICM performs a power reset upon exiting the Setup Mode. 6. Turn off the ICM/Control Unit power. 7. Remove the RS-232 NullModem Adapter and reconnect the RJ11 modular cord as shown 8. After re-connections are completed, re-apply power to the ICM/Control Unit.

107

THE ICM WEB BROWSER •

The ICM's Web server issues web pages and related files when requested by a Web browser.

•

The ICM includes a default page (index.html) that contains a custom Java applet. The Web browser loads and executes the applet when the Web page is requested.

•

The applet provides a graphical user interface for monitoring the control unit.

322

ICM OPERATION The initial screen that appears when the java applet starts

Click on setup to configure ICM

ICM OPERATIONS

Enter 5 recipients email addresses

Enter addresses Source information (Ref to ICM manual)

When done with entries above, click OK

108

REAL TIME EVENT LOG VIEWING •

Upon the occurrence of an unusual system event, automatic email will be sent and a link provided to the panel‟s event log.

•

Clicking the link starts the java applet

•

Clicking on listings in the opens the listings page shown on the next slide

•

Enter password assigned in the previous slide to open real time event long

REAL TIME EVENT VIEWING

THANK YOU

109