Xtrails VESDA VLI Product Manual

VESDA VLI

Product Guide

June 2012

Document: 18500_A2

Part Number: 29674

VESDA by Xtralis VESDA VLI Product Guide

Intellectual Property and Copyright

This document includes registered and unregistered trademarks. All trademarks displayed are the trademarks of
their respective owners. Your use of this document does not constitute or create a licence or any other right to use
the name and/or trademark and/or label.

This document is subject to copyright owned by Xtralis AG (“Xtralis”). You agree not to copy, communicate to the
public, adapt, distribute, transfer, sell, modify or publish any contents of this document without the express prior
written consent of Xtralis.

Disclaimer

The contents of this document is provided on an “as is” basis. No representation or warranty (either express or
implied) is made as to the completeness, accuracy or reliability of the contents of this document. The manufacturer
reserves the right to change designs or specifications without obligation and without further notice. Except as
otherwise provided, all warranties, express or implied, including without limitation any implied warranties of
merchantability and fitness for a particular purpose are expressly excluded.

General Warning

This product must only be installed, configured and used strictly in accordance with the General Terms and
Conditions, User Manual and product documents available from Xtralis. All proper health and safety precautions
must be taken during the installation, commissioning and maintenance of the product. The system should not be
connected to a power source until all the components have been installed. Proper safety precautions must be taken
during tests and maintenance of the products when these are still connected to the power source. Failure to do so
or tampering with the electronics inside the products can result in an electric shock causing injury or death and may
cause equipment damage. Xtralis is not responsible and cannot be held accountable for any liability that may arise
due to improper use of the equipment and/or failure to take proper precautions. Only persons trained through an
Xtralis accredited training course can install, test and maintain the system.

Liability

You agree to install, configure and use the products strictly in accordance with the User Manual and product
documents available from Xtralis.

Xtralis is not liable to you or any other person for incidental, indirect, or consequential loss, expense or damages of
any kind including without limitation, loss of business, loss of profits or loss of data arising out of your use of the
products. Without limiting this general disclaimer the following specific warnings and disclaimers also apply:

Fitness for Purpose

You agree that you have been provided with a reasonable opportunity to appraise the products and have made
your own independent assessment of the fitness or suitability of the products for your purpose. You acknowledge
that you have not relied on any oral or written information, representation or advice given by or on behalf of Xtralis
or its representatives.

Total Liability

To the fullest extent permitted by law that any limitation or exclusion cannot apply, the total liability of Xtralis in
relation to the products is limited to:

i. in the case of services, the cost of having the services supplied again; or

ii. in the case of goods, the lowest cost of replacing the goods, acquiring equivalent goods or having the goods

repaired.

Indemnification

You agree to fully indemnify and hold Xtralis harmless for any claim, cost, demand or damage (including legal costs
on a full indemnity basis) incurred or which may be incurred arising from your use of the products.

Miscellaneous

If any provision outlined above is found to be invalid or unenforceable by a court of law, such invalidity or
unenforceability will not affect the remainder which will continue in full force and effect. All rights not expressly
granted are reserved.

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VESDA VLI Product Guide VESDA by Xtralis

Scope

The VESDA VLI Product Guide provides a comprehensive description of the VLIdetector and its accessories.

This guide introduces the VLI features, technical specifications and gives an understanding of its components
and their function. You will also find instructions on installing, cabling and powering up the detector.

This guide is for anyone involved with the design, maintenance and purchasing of a VESDA system. It is
assumed that anyone using this product has the knowledge and appropriate certification from local fire and
electrical authorities.

Document Conventions

The following typographic conventions are used in this document:

Convention Description

Bold Used to denote: emphasis. Used for names of menus, menu options,

toolbar buttons

Italics Used to denote: references to other parts of this document or other

documents. Used for the result of an action.

The following icons are used in this document:

Convention Description

Contact Us

The Americas +1 781 740 2223

Asia +852 2916 8894

Australia and New Zealand +61 3 9936 7000

UKand Europe +44 1442 242 330

Middle East +962 6 588 5622

Caution: This icon is used to indicate that there is a danger to

equipment. The danger could be loss of data, physical damage, or
permanent corruption of configuration details.

Warning: This icon is used to indicate that there is a danger of electric
shock. This may lead to death or permanent injury.

Warning: This icon is used to indicate that there is a danger of inhaling
dangerous substances. This may lead to death or permanent injury.

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VESDA by Xtralis VESDA VLI Product Guide

Codes and Standards Information for Air Sampling Smoke Detection

We strongly recommend that this document is read in conjunction with the appropriate local codes and standards
for smoke detection and electrical connections. This document contains generic product information and some
sections may not comply with all local codes and standards. In these cases, the local codes and standards must
take precedence. The information below was correct at time of printing but may now be out of date, check with your
local codes, standards and listings for the current restrictions.

FCC Compliance Statement

This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15
of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a
residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed
and used in accordance with the instruction, may cause harmful interference to radio communications. However,
there is no guarantee that interference will not occur in a particular installation. If this equipment does cause
harmful interference to radio or television reception, the user is encouraged to try to correct the interference by one
or more of the following measures; re-orientate or relocate the receiving antenna, increase the separation between
the equipment and receiver, connect the equipment to a power outlet which is on a different power circuit to the
receiver or consult the dealer or an experienced radio/television technician for help.

FDA

This Xtralis product incorporates a laser device and is classified as a Class 1 laser product that complies with FDA
regulations 21 CFR 1040.10. The laser is housed in a sealed detector chamber and contains no serviceable parts.
The laser emits invisible light and can be hazardous if viewed with the naked eye. Under no circumstances should
the detector chamber be opened.

FM Hazardous Applications

3611 Hazardous Approval Warning: Exposure to some chemicals may degrade the sealing of relays used on the
detector. Relays used on the detector are marked “TX2-5V”, “G6S-2-5V” or “EC2-5NU”.

VESDA detectors must not be connected or disconnected to a PC while the equipment is powered in an FM
Division 2 hazardous (classified) location (defined by FM 3611).

FM Approved Applications

The product must be powered from VPS-100US-120, VPS-100US-220 or VPS-220 only.

AS1603.8

The performance of this product is dependent upon the configuration of the pipe network. Any extensions or
modifications to the pipe network may cause the product to stop working correctly. You must check that ASPIRE2
approves alterations before making any changes. ASPIRE2 is available from your authorized representative.

AS1851.1 2005

Maintenance Standards. Wherever this document and the AS1851.1 differ, AS1851.1 should be followed in
preference to this document.

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VESDA VLI Product Guide VESDA by Xtralis

Regional Regulatory Requirements and Notices

UL

For open area protection the fire alarm threshold (signal) that initiates an evacuation procedure via the Fire
Alarm Panel must not be set less sensitive than 0.625%/ft. The detector can send this signal via the Fire
Alarm Panel Output signal or the Pre-alarm output signal.

Through validation testing, Underwriters Laboratories Inc. has verified that VESDA ECO gas detectors, when
installed within the sample pipe network, present no significant effects on the smoke detection performance of
VESDA. The use of the ASPIRE2 calculation software is required to verify system design performance with
all devices included in the design.

EN 54-20

The product must use a power supply conforming to EN 54-4.

The product is compliant with EN 54-20 sensitivity requirements provided the following conditions are met:

l For a Class A detector, hole sensitivity must be better than 1.5% obscuration/m and transport time less

than 60 seconds

l For a Class B detector, hole sensitivity must be better than 4.5% obscuration/m and transport time less

than 90 seconds

l For a Class C detector, hole sensitivity must be better than 10% obscuration/m and transport time less

than 120 seconds

These limits should be verified using ASPIRE2 during the design of the sampling pipe network.

The product is compliant with EN 54-20 flow monitoring requirements provided the following conditions are
met:

The minor low and minor high flow thresholds should be set at 85% and 115% respectively

Additional information:

VESDA VLI was successfully tested and passed the EN 54-20 fire tests with the following configurations:

l Class C with 64 holes and a Fire-1 setting of 0.15% obscuration/m
l Class B with 28 holes and a Fire 1 setting of 0.15% obscuration/m
l Class A with 24 holes and an Alert setting of 0.06% obscuration/m

Note: These configurations were chosen to illustrate the maximum capability of the VESDA VLI in terms

of number of holes and sensitivity in a clean environment and necessitated the use of holes with a
diameter less than 3mm. As stated in Section 4.1, for industrial applications with high background
levels, hole sizes of less than 3mm should be avoided. Thus, the maximum number of holes may
not be realizable in some applications.

In all applications an ASPIRE2 design must be prepared to meet appropriate EN54-20 sensitivity transport
time targets, taking into consideration all factors including any local codes and standards for maximum
transport times.

Product Listings

l UL
l ULC
l ActivFire
l LPCB
l CE - EMC and CPD
l EN 54-20

Regional approvals listings and regulatory compliance vary between product models. Refer to www.xtralis.com for
the latest product approvals matrix.

Document: 18500_A2

Part Number: 29674

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VESDA by Xtralis VESDA VLI Product Guide

Table of Contents

1 Introduction 3

1.1 Features 3

2 Product Information 5

2.1 Detector Components 5

2.2 How the VLI works 6

2.3 Front Panel 8

2.4 Communication Ports 10

2.5 Specifications 11

2.6 Dimensions 13

2.7 VESDAnet 14

2.8 Accessories 15

3 Installation 17

3.1 Mounting 18

3.2 Wiring 20

3.3 Powering Up 28

3.4 Installation Checklist 29

3.5 Preliminary System Check 30

4 Pipe Network Design 31

4.1 Design Considerations 31

4.2 Installation Considerations 31

4.3 Inlet Pipes 31

4.4 Managing the Exhaust Air 32

5 Configuration 33

5.1 Connecting to a Standalone VESDA VLI Detector 33

5.2 Connecting to a VESDA VLIon VESDAnet 37

5.3 Access Levels 37

5.4 Commands 38

5.5 Configuration Options 40

5.6 Default Settings 48

6 Commissioning 51

6.1 AutoLearn Smoke 51

6.2 AutoLearn Flow 52

6.3 Commissioning Smoke Test 52

7 Maintenance 53

7.1 Set the Detector to Standby 53

7.2 Remove the Front Cover 54

7.3 Replacing the Intelligent Filter 55

7.4 Replacing the Secondary Foam Filter 56

7.5 Replacing the Aspirator 57

7.6 Replacing the Detection Chamber Assembly 58

7.7 Spare Parts 64

8 Troubleshooting 65

8.1 Fault Reporting through Relays 65

8.2 Troubleshooting with Xtralis VSC 65

8.3 Troubleshooting with a Remote Display 66

8.4 Troubleshooting with an LCD Programmer 66

A Commissioning Forms 67

A.1 VLI Detector Commissioning Form 68
A.2 Display/Relay Configuration 69

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A.3 Relay Configuration 69
A.4 VESDAnet Interface Card 69
A.5 ASPIRE2 Data 69
A.6 Smoke Test 70
A.7 Air Sampling Test Results 70

B Glossary 71

Index 73

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VESDAVLI

!

DISABLED

RESET/
DISABLE

1 Introduction

The VESDA VLI is an aspirating smoke detector (ASD) that provides very early warning of fire conditions by
drawing air samples through an air sampling pipe network.

The VLI detector is especially designed to operate in industrial applications under harsh and dirty
environments. It incorporates features that specifically address the common challenges of industrial
installations, including:

l high background levels of airborne particles
l the need for environmental enclosures
l detector longevity
l the need for on-site maintenance

Figure 1-1: VESDA VLI Aspirating Smoke Detector

The detector easily interfaces with fire warning and fire suppression release systems, and can be integrated
into a building management system (BMS).

1.1 Features

The VLI detector contains the following features:

l Area coverage up to 2000m² (21,500ft²)
l Up to four inlet pipes
l Total pipe length of 360m (1200ft)
l Five high intensity status LEDs
l Robust absolute smoke detection
l Patented Intelligent Filter
l Inertial separator (sub sampling probe)
l Lint trap to capture fibrous particles
l Secondary Foam Filter
l Clean air barrier for optics protection
l Referencing (on VESDAnet enabled model)
l AutoLearn™ Smoke and Flow
l Clean Air Zero™
l Air-path monitoring
l Five relays (fire, fault and three configurable) configurable as latching or non-latching
l One (standard) or two GPIs (VESDAnet enabled model)
l Ultrasonic flow sensing
l Xtralis VSC, Xtralis VSM4 and ASPIRE2 software support
l IP54 enclosure

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VESDA VLI Product Guide VESDA by Xtralis

l Easy mounting with steel support bracket
l Modular field replaceable parts for ease of servicing
l Replaceable aspirator, detection chamber and filters
l BACnet over Ethernet
l Local USBconfiguration port
l Easy cable termination access
l Imperial and metric pipe ports
l Rubberized finish to external housing

1.1.1 Intelligent Filter

The Intelligent Filter is fully monitored, fail-safe, and provides consistent sensitivity over the entire life of the
detector. The filter significantly reduces the exposure of the internals of the detector to contaminants in the
incoming air while providing consistent sensitivity to smoke. Refer to Section 2.2 for further information.

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VESDA by Xtralis VESDA VLI Product Guide

A

B

C

D

E

F

G

2 Product Information

2.1 Detector Components

The VLI detector contains a number of field-replaceable components.

Legend

A Front cover E Chamber assembly with tertiary

clean air filter

B Intelligent Filter F Aspirator

C Secondary Foam Filter G Base

D Electrostatic Discharge (ESD)Cover

Refer to Chapter 7 for further information regarding maintenance scheduling and availability of spare parts.

Figure 2-1: Detector components

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VESDA VLI Product Guide VESDA by Xtralis

A
B

D

E

F

G

H

J

K

L

M

I

N

C

2.2 How the VLI works

The VLI detector continually samples air from the protected environment via a sampling pipe network (A).
Upon entering the detector, the air passes four sets of ultrasonic flow sensors (B), then through the mixer
compartment of the Intelligent Filter (C), where it is split between two pathways. One pathway carries the
majority of the air through a HEPAfilter, while the other carries a small proportion of the air through a separate
set of ultrasonic flow sensors (D). The air then recombines in the main aspirator (F).

Legend

A Pipe Inlets

B Ultrasonic Flow Sensors

C Intelligent Filter

D Ultrasonic Flow Sensor

E Manifold

F Main Aspirator

G Sampling Probe

H Secondary Foam Filter

I Chamber Assembly

J Chamber Flow Sensor

K Chamber

L Tertiary Clean Air Filter

M Auto Zero Aspirator

N Exhaust

Figure 2-2: Internal airflow example

Note: The Intelligent Filter loading is constantly monitored using the ultrasonic flow sensors in the

unfiltered path (D). Coupled with the arrangement of the four sets of ultrasonic flow sensors at the
detector air inlets (B), the detector measures the split of the airflow ratio as the filter loading
increases. The detector maintains the sensitivity depending on the flow ratio, thus ensuring
consistent and reliable operation over time.

A portion of recombined air sample is then passed through the sub-sampling probe (inertial separator) and
secondary foam filter (H). Larger dust particles are unable pass through the probe and filter arrangement and
hence are exhausted out of the detector (N). This eliminates nuisance alarms caused by larger dust particles
and extends the life of the detection chamber (K). The tertiary clean air filter (L)provides clean air to form the
clean air barriers within the detection chamber (K), which protects the optical surfaces from contamination.

The presence of smoke in the detection chamber (K) creates light scattering which is detected by the sensor
circuitry. The air sample is measured, and the detector reports smoke levels in line with the sensitivity ratio
determined by the Flow Sensors (B and D). Air is exhausted from the detector and may be vented back into
the protected area (N).

Note: The status of the detector, all alarms, service and fault events, are monitored and logged with time

and date stamps. Status reporting can be transmitted via relay outputs, across VESDAnet
(VESDAnet version only) or BACnet.

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VESDA by Xtralis VESDA VLI Product Guide

2.2.1 Clean Air Zero

Clean Air Zero is a user-initiated feature which is primarily intended to safeguard against nuisance alarms.
This is achieved by introducing clean air into the detection chamber and taking a reference reading. This
reading is then offset against the actual environmental background to maintain consistent absolute smoke
detection.

The user can initiate the Clean Air Zero process using Xtralis VSC. It takes up to 60 seconds to complete,
during which time the detector is offline.

Clean Air Zero Process

When the user initiates the Clean Air Zero process from within the Xtralis VSC software, the following actions
occur:

1. The main aspirator is turned off.

2. The Clean Air Zero aspirator located inside the chamber assembly is turned on. This aspirator pumps
clean air into the Chamber and removes any contaminated air.

3. After a waiting period, a smoke reading is taken with clean air in the chamber. This reading is the new
clean air background value and is used as a reference point against the actual environmental background.

4. The Clean Air Zero aspirator is turned off and the main aspirator is turned back on.

5. An event indicating that the Clean Air Zero process has taken place is added to the event log.

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DISABLED

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2.3 Front Panel

The VLI detector provides the following information and control capability:

l Status LEDs: Alarm, Pre-Alarm, Disabled, Fault and Power.
l Controls: Reset and Disable button.

Figure 2-3: Front Panel Controls and LEDs

Status LEDs

Table 2-1: LED Indicators

LED Description

Alarm The ALARM LED is lit when the Fire1 Alarm threshold is reached.

Pre-Alarm The PRE-ALARM LED blinks when the Alert threshold is reached.

The PRE-ALARM LED is lit when the Action threshold is reached.

Disabled The DISABLEDLED is lit when the detector is disabled.

Fault The FAULT LED is lit when a fault condition is detected.

Refer to Chapter 8 for information on troubleshooting.

Power The POWERLED illuminates when the detector is powered up.

Notes:

l The LEDs are tested during the power up cycle. To manually test the LEDs, run the Lamp Test using

Xtralis VSC.

l Power and Fault LEDs are also present on the main board inside the VLI for when the front panel is

disconnected during installation or maintenance.

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VESDA by Xtralis VESDA VLI Product Guide

RESET / DISABLE Button

Resetting the detector unlatches all latched alarms and faults, returns relays to their normal state and clears
the active event list.

l To reset the detector, press this button once.

Disabling the detector disables all the output relays associated with the detector. The aspirator remains
active.

l To disable the detector, press and hold the button for approximately 2 seconds, until the DISABLED

LEDilluminates.

l To re-enable the unit, press and hold the button for approximately 2 seconds, until the DISABLED

LEDdeactivates.

l While the detector is disabled, any faults may be cleared by pressing this button once.

The button will not operate if:

l the detector is disabled through the GPI function; or
l the RESET / DISABLE button has been locked out in the programming.

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VESDA VLI Product Guide VESDA by Xtralis

2.4 Communication Ports

The majority of user operations are performed using software installed on a computer connected to the
detector via one of the communication ports.

The communication ports are located on the main board inside the detector. It is necessary to remove the front
cover from the detector in order access these ports. Refer to Section 7.2 for the front cover removal
procedure.

USB

The USBport is used for configuration purposes. It allows direct connection between the VLI detector and a
PC or laptop installed with Xtralis VSC.

Refer to Section 3.2.3 for information on connecting the USBlead, and Section 5.1 for information on creating
connection profiles in Xtralis VSC.

Note: The USBport should not be used for continuous monitoring with the Xtralis VSM4 software.

Monitoring should be performed using a connection made via the Ethernet port.

Ethernet

The Ethernet port is used for configuration and/or monitoring purposes. It enables direct or routed TCP/IP
network connection between the detector and a PC or laptop installed with Xtralis VSC, or other BACnet
protocol compatible applications.

Refer to Section 3.2.3 for information on connecting the Ethernetlead, and Section 5.1 for information on
creating connection profiles in Xtralis VSC.

RS485

The RS485 port is present on the VESDAnet Card of the VESDAnet enabled model, and can be used for
configuration of any device on the VESDAnet. It provides connectivity for the handheld LCDProgrammer or a
local PC or laptop via a High Level Interface (HLI). Refer to Section 2.8.2 for further information on the
LCDProgrammer.

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VESDA by Xtralis VESDA VLI Product Guide

2.5 Specifications

Table 2-2: VLI Detector Specifications

Specification Value

Supply Voltage 18 to 30 VDC

Power Consumption @24 VDC l Normal: 9.6W

l Alarm on:10.8W

Current Consumption l Normal: 415mA

l Alarm on: 440mA

Dimensions (WHD) 426.5mm x 316.5mm x 180mm

(16.8 in x 12.5in x 7.1in)

Weight 6.035 Kg (13.3Lbs)

Operating Conditions

(To operate the VESDA VLI detector outside
these parameters please contact your
nearest Xtralis Office)

Temperature:

l Ambient: 0° to 40°C (32° F to 104°F)
l Tested: -10° to 55°C (14°F to 131°F)
l Sampled Air: -20° to 60°C (-4° to 140°F)

Humidity:

l 10-95% RH, non-condensing

Storage Conditions

(Non-operational)

l Battery life: Up to 2 years
l Humidity:Dry (<95%)
l Temperature: 0° to 85°C
l Must not be exposed to sunlight or other radiation sources

Sampling Pipe Network l Maximum length per single straight pipe: 120 m (350 ft)

l Total pipe length: 360 m (1200 ft)
l Pipe Modeling Design Tool:ASPIRE2
l Minimum total airflow:40 l/m
l Minimum airflow per pipe: 20 l/m

Pipe Size l Internal Diameter: 15-21 mm (0.874 inch)

l External Diameter: 25 mm (1.05 inch)

Relays l 5 relays - Fire, Fault, 3 x Configurable.

l Contacts rated 2A @ 30 VDC.
l Programmable to latch or non-latch states
l Programmable 0 - 60 sec delay for each relay

IP Rating IP54 (protection against ingress of dust and water splash)

Mounting Upright or inverted with supplied mounting bracket

Cable Access 4 plastic plugs (2 top, 2 bottom), 25.4mm (1 inch) diameter.

Note: To maintain the IPrating, IP54 compliant cable

glands must be used.

Cable Termination Screw terminal blocks (0.2-2.5 sq mm, 30-12 AWG)

Interfaces l USB (Type 2)

l Ethernet (RJ45)
l RS485 (VESDAnet enabled detectors)

Alarm Range 0.005 to 20.00% obs/m (0.0015 to 6.4% obs/ft.)

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Table 2-2: VLI Detector Specifications (continued...)

Specification Value

Threshold Setting Range l Alert: 0.05%–1.990% obs/m

(0.016% - 0.637% obs/ft)

l Action: 0.1%–1.995% obs/m

(0.032% - 0.638% obs/ft)

l Fire1: 0.15 %–2.0% obs/m

(0.048% - 0.64% obs/ft)

l Fire2: 0.155 %–20.0% obs/m**

(0.05% - 6.4% obs/ft)

** Limited to 12% obs/m (4% obs/ft.) in UL mode

Referencing Reference smoke level source for the VESDAnet enabled

model.

Notes:

Ensure that UL Mode is switched ON to maintain the UL listing.

l UL Mode = ON: Fire2 set to 12% obs/m (4% obs/ft.) to comply with UL268
l UL Mode = OFF: Fire2 threshold can be set up to 20% obs/m (6.4%/ft)

Table 2-3: Key Software Features

Event Log Up to 18,000 events stored on FIFO basis

AutoLearn l Minimum 15 minutes

l Maximum 15 days, 23 hrs, 59 minutes
l Recommended minimum period: 1 day

Thresholds are automatically changed from the previously set
values to the updated values after the AutoLearn process has
completed.

Referencing Adjustment for external ambient conditions

Four Alarm Levels Alert, Action (PRE-ALARM), Fire1 (ALARM) and Fire2

Two Fault Warning Levels Minor Fault and Urgent Fault

Maintenance Aids l Filter and flow monitoring

l Event reporting via VESDAnet, BACnet and event log

Table 2-4: Ordering Information

VESDA VLI Standalone VLI-880

VESDA VLIwith VESDAnet Card VLI-885

VESDA VLIRemote Display with RTC7 VRT-Q00

VESDA VLIRemote Display with RTC0 VRT-T00

LCDProgrammer VRT-100

Hand-held LCD Programmer VHH-100

Note: Refer to Section 7.7 for the spare parts list.

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VESDA by Xtralis VESDA VLI Product Guide

G G G

HFED

I

LK

EJ

I

C

A

B

D E

D

B

C

G

H

F

A

2.6 Dimensions

mm inch

A 180 7.08

B 426.5 16.8

C 316.5 12.46

D 70.2 2.76

E 45 1.77

F 149 5.87

G 34 1.34

H 60.3 2.37

I 26.7 1.05

J 70.2 2.76

K 105 4.13

L 206.3 8.11

Figure 2-4: Front Dimensions

mm inch

A 426.5 16.8

B 316.5 12.46

C 75 2.95

D 88.25 3.47

E 250 9.84

F 96.3 3.8

G 115.2 4.54

H 105 4.13

Figure 2-5: Rear Dimensions

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VESDA VLI Product Guide VESDA by Xtralis

2.7 VESDAnet

VESDAnet is a proprietary communications protocol which is used on a network that connects the VESDA
range of smoke detectors, displays, programmers and remote units and enables them to communicate on a
VESDAnet network.

A VESDAnet network allows:

l configuration and monitoring of devices from a central computer.
l connection to a reference detector.
l connection to additional accessories such as remote displays.

The VESDAnet enabled VLI detector (VLI-885) can be joined to a VESDAnet network, and provides a
connection point on the VESDAnet for a High Level Interface (HLI), which is required to connect a PCor
laptop to the VESDAnet. Alternately, the connection point can be used for a hand-held LCDProgrammer (refer
to Section 2.8.2). The VLI-885 also contains a socket on the VESDAnet card for monitored General Purpose
Input (refer to Section 3.2.7).

Refer to the VESDA Communications Guide for further information on VESDAnet network connectivity.

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VESDA by Xtralis VESDA VLI Product Guide

2.8 Accessories

A range of optional accessories are available to augment the VESDAnet-enabled VLI-885 detector.

2.8.1 Remote Display Module

The Remote Display Module provides real-time indication of the status of a VLI detector and a single zone.

Figure 2-6: Remote Display Module

The unit contains a 20-segment vertical bar graph display, a 2 digit numeric display, an audible sounder, clear
alarm and fault indicators, and can be mounted in a remote mounting box or 19 inch subrack.

l Smoke levels are continuously shown on the bar graph display where each illuminated segment indicates

the current level of detected smoke.

l The top segment of the bar graph indicates the Fire1 smoke threshold level and each segment below that

level represents 1/20 of the Fire1 smoke threshold level.

l The Alert, Action and Fire1 smoke threshold indicators provide a visual representation of the

programmable alarm thresholds, showing how close the smoke level is to triggering the next level of
alarm.

l Fault conditions are indicated by a series of LEDs and an audible tone.
l The numerical readout can show either the current smoke level in %obscuration/m (%obscuration/ft) or

the Fire1 threshold in %obscuration/m (%obscuration/ft).

l Four buttons enable users to reset, isolate or silence the detector and control the mode of the remote

display module. These buttons can be locked out.

2.8.2 LCD Programmer

The VESDA LCD Programmer is used for configuring, commissioning and maintenance of the devices on
VESDAnet. It is connected via VESDAnet and can be mounted at a remote location.

A hand-held model (VHH-100) is also available. This model is connected to the DB15 socket in the VLI-885
detector or other VESDAnet-enabled detectors.

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VESDA VLI Product Guide VESDA by Xtralis

Legend

A LCDDisplay

B Keys

Figure 2-7: Hand-held LCD Programmer

Refer to the LCD Programmer Product Guide for further details.

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3 Installation

The VLI detector is shipped with the following components:

l 1 VLI detector
l 1 Mounting bracket
l 1 Ferrite core for connection using Ethernet cable
l Multilingual Installation Sheet
l 1 End of Line resistor with the VLI-885 detector

Check all components for damage and refer any concerns to your authorized representative.

Depending on the nature of the installation, it may be necessary to procure the following items:

l Screws and inserts for the mounting bracket that are appropriate for the installation location.
l Type A to Type B USBInterface Lead, if configuration of the detector is to be done via the USBinterface.
l Standard Ethernet cable if configuration of the detector is to be done via the Ethernet interface.
l A High Level Interface (HLI), where it is necessary to connect to a VESDA VLI on VESDAnet.

Figure 3-1: Type A to Type B USBInterface Lead

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VESDA VLI Product Guide VESDA by Xtralis

C

D

D

D

D

A

B

B

B

B

3.1 Mounting

The VLI detector can be mounted in an upright or inverted position. Do not mount the detector with a sideways
orientation as shown in Figure 3-2 below.

Figure 3-2: Sideways orientation

Ensure the mounting surface is flat as this allows an air tight seal to be achieved between the sampling pipe
and the tapered air inlet pipes on the detector.

Ensure that there is sufficient clearance to mount the detector (Figure 3-3), noting the location of air sampling
pipes and cable entry points. Due to the rigid nature of the plastic pipe, installation must provide for sufficient
movement in all pipework (air inlet, air exhaust and cable pipes) to allow pipe ends to be easily fitted and
removed.

Legend

A Min. 200 mm (8 in.) below

ceiling level

B Min. 125 mm (5 in.) from a wall

or obstruction

Figure 3-3: Mounting location

Mount the Detector

1. Horizontally align the mounting bracket (A) and place the flat side flush against the surface. Use
appropriate fasteners (B) to secure the bracket.

Legend

A Mounting bracket

B Fasteners

C Locking Mechanism

D Hooks

Figure 3-4: Mounting Bracket

2. Ensure that the locking mechanism (C)is bent outwards, as shown below in Figure 3-5.

3. Place the four slots located at the rear of the detector onto the hooks (D) of the mounting bracket.

4. Slide the unit downwards onto the hooks (D) until the locking mechanism (C) clicks.

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A

B

C

Legend

A Detector

B Mounting bracket

C Locking Mechanism

Figure 3-5: Mounting the detector

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VESDA VLI Product Guide VESDA by Xtralis

3.2 Wiring

The screw type terminals located on electrical terminals within the VLI detector will accept wire sizes from 0.2
mm² to 2.5 mm² (30 – 12 AWG).

Refer to Codes and Standards Information for Air Sampling Smoke Detection on page iii for code specific
requirements.

Refer to the VESDA System Design Manual for cabling details.

Note: The VLI detector is IP54 rated, therefore an IP54 compliant cable gland must be used to maintain

the IP54 rating.

Caution: Electrostatic discharge (ESD) precautions need to be taken prior to removing the front cover

from the detector in order to prevent damage to sensitive electronic components within the VLI.

3.2.1 Cabling Inlets

The VESDA VLIcontains four inlets for power, relay and network cabling, located on the upper and lower
sides of the detector base. The holes have a diameter of 25.4mm (1 inch).

Note: To maintain the specified IPrating, IP54-compliant cable glands must be used.

Figure 3-6: Cabling Inlets

3.2.2 Power Source

There are two sets of power terminals on the main board. Connect to a 24 VDC power supply to the
PWRINsocket, and if required loop out to another detector via the PWROUT socket.

The detector will not operate if the power supply polarity is reversed.

Caution: Operating the detector when DC supply voltage is outside the specified voltage range may

cause damage to internal components. For further information refer to the Product
Specifications on page 11.

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PWR IN

PWR OUT

1

4

2

3

+

+

_

_

Detector1 Detector2 Detector3

Upto8
Detectors

PWRIN

PWR

OUT

+

+

_

_

PWRIN

PWR

OUT

+

+

_

_

PWRIN

PWR

OUT

+

+

_

_

PSU

Figure 3-7: Wire connection details for power terminals

Power to Multiple Detectors

Up to eight detectors may be daisy chained to the same power supply by connecting the PWROUTpower
passthrough socket to the PWRINsocket on each subsequent detector.

Figure 3-8: Multiple Detectors powered by a single power supply

Compliance

It is recommended that the power supply be compliant with local codes and standards required by the regional
authority. For code-specific information, refer to Codes and Standards Information for Air Sampling Smoke
Detection on page iii.

3.2.3 Communication Ports

The front cover must be removed from the VLI in order to access the communication ports. Refer to Section

7.2 for the front cover removal procedure.

Figure 3-9: Location of the USB and Ethernet communication ports

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VESDA VLI Product Guide VESDA by Xtralis

USB

The USB port is used for initial configuration and local maintenance or servicing of the VLI using Xtralis VSC
software. Use the Ethernet port for a permanent network connection to the detector to allow remote
configuration or monitoring.

Install Xtralis VSC prior to connecting the VLIto the PCor Laptop. This ensures that the required USBdrivers
are present.

Note: Refer to the Xtralis VSC documentation for operating system compatibility information.

Ethernet

The Ethernet port is used for permanent network connection to the VLI. An Ethernet lead can be inserted into
the port and routed out beneath the ESD cover and through and of the cable entry ports.

Use a standard Ethernet lead when connecting the VLI to a network switch, router or directly to a PCor
laptop.

Note: For EMC compliance, the Ethernet lead requires a ferrite to be fitted. Refer to Figure 3-10.

Figure 3-10: Ethernet lead with Ferrite

3.2.4 VESDAnet

VESDAnet is a bidirectional data communication network between connected VESDA devices. VESDAnet
connectivity is available on the VESDAnet enabled VLI detector (VLI-885). Refer to Section 2.7 for further
information.

It is recommended that RS 485 (Belden 9841 - 120 Ohm) twisted pair cables be used for including the devices
in the network.

The network cables are terminated at the VESDAnet A and B Terminals on the VESDAnet card. Cabling from
one VESDA device is brought into the detector at one terminal and looped out to another device on VESDAnet
from the other terminal.

Notes:

l Connection between devices should be from A to B. Avoid using A to A or B to B.
l The polarity of the data wires must be maintained throughout the network.

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A+

A-

B-

Shield

Module 1 Module 2 Module 3

Module 5 Module 4

Shield

B+

A+

A-

B-

Shield

Shield

B+

A+

A-

B-

Shield

Shield

B+

A+

A-

B-

Shield

Shield

B+

A+

A-

B-

Shield

Shield

B+

(VLI-885)

Shield

A-

A+

Shield

B-

B+

Figure 3-11: Example closed loop VESDAnet network

The VLI-885 detector is shipped with the VESDAnet A and B terminals looped. Remove the A and B links prior
to connecting the detector to the VESDAnet. If the detector is not to be networked with other devices, then do
not remove the A and B links.

Note: For each VLI-885 detector connected on VESDAnet, ensure that the shield link wire (supplied) is

retained as shown by the dotted line in Figure 3-11. The link wires [A+ to B+] and [A- to B-] (not
shown in the figure but supplied for stand-alone operation) should be removed. On other VESDAnet
devices all the link wires are removed when connected on VESDAnet.

Figure 3-12: Closed loop for standalone detectors with VESDAnet capability

Note: Refer to the VESDA Communications Guide for further information.

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3.2.5 Relays

The relays, located on the main processor card, interface to the Fire Alarm Control Panel (FACP)to
communicate faults, alarms and disabled states.

Fault and Fire1 Relay Terminals

Fault (Trouble) and Fire1 (Alarm) relay terminals are located on the main board inside the detector.

The Fault relay is energized during normal operation while the Fire1 relay is only energized when a Fire1 is
detected. The operation of the relays are summarized in the following table.

Table 3-1: Fault and Fire Relay Operation

FAULT Relay FIRE1 Relay

Normal Operation

(Energized)

Programmable Relays

The three additional relays can be programmed using Xtralis VSC software or the LCD Programmer if the
detector is on a VESDAnet. Refer to the Xtralis VSC Online Help or LCD Programmer Product Guide for
details.

or unpowered state

Fault

Normal Operation

(De-energized)

Fire

3.2.6 Unmonitored General Purpose Input (GPI)

The GPI is a programmable input which can be configured to initiate a number of different actions, including,
by default, a Remote Reset function. Refer to Section 5.5.4 on page 43 for further information.

Notes:

l When the detector is disabled or set to standby via the GPI, the status cannot be changed through the

normal enable / disable functions on the Display Module or the LCD Programmer.

l When the night-time thresholds are invoked via the GPI, the clock settings for day-start and night-start are

overridden.

The GPI requires a voltage supply between 5V and 30 VDC from the connected device in order to operate.
The input is isolated from the system by an opto-coupler device.

3.2.7 Monitored General Purpose Input (GPI) Wiring

Monitored GPI is available on the VLI-885 detector. It includes the same functions as the unmonitored GPI,
with power supply monitoring as the default setting.

With monitored GPI, the detector monitors the GPIfor open or short circuit faults when the GPI function is set
to any value.

When the GPI function parameter is set to Mains OK, the detector indicates an external equipment fault
condition by monitoring the line impedance. A 2K7 End of Line (EOL) resistor is supplied with the product and
must be assembled in parallel with the device to be monitored.

The EOL resistor provides a known termination to the external equipment, this allows the VLI detector to
identify open or short circuits.

Note: When monitored GPI is set to Inverted Reset, GPI ON/OFF senses changes. A short circuit sets

GPI OFF and EOL sets GPI ON.

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Normally Closed (NC)

Common (C)

Normally Open (NO)

FIRE

Normally Closed (NC)
Normally Open (NO)

Common (C)FAULT

Unmonitored GPI
(Set to reset)

Detector

(NC)
Reset (C)
(NO)

Input
Short = Fire
Open = Fault

To next detector

or End of Line resistor (EOL)

Fire Panel (FACP)

Monitored GPI (VLI-885 only)
(Set to reset)

(NC)
Reset (C)
(NO)

EOL

+

-

+

-

5-30VDC

PSU

Normally Closed (NC)

(NO)

Common (C)

Normally Open

FIRE

Normally Closed (NC)
Normally Open (NO)

Common (C)CONFIGURABLE

Normally Closed (NC)
Normally Open (NO)

Common (C)FAULT

Detector

Fire Input
Short = Fire
Open = Wiring Fault

3 Inputs 1 Output Loop Module

To FACP

To Next Detector

Pre Alarm
Short = Fire
Open = Wiring Fault

Fault Input
Short = Detector Fault
Open = Wiring Fault

EOL*

EOL*

EOL*

*EOL: End of Line Resistor

Unmonitored GPI
(Set to reset)

(NC)
Reset (C)
(NO)

Monitored GPI (VLI-885 only)
(Set to reset)

(NC)
Reset (C)
(NO)

EOL

+

-

+

-

5-30VDC

PSU

3.2.8 Typical Wiring to Fire Alarm Control Panel (FACP)

The diagram below shows the correct way to wire VESDA detectors to a conventional fire alarm control panel
(FACP). It also shows where an End Of Line (EOL) resistor is correctly installed.

3.2.9 Typical Wiring to Address Loop Module

This wiring example is for wiring VESDA detectors to a typical Input/Output Loop module 3 inputs 1 output.

Note: These are example drawings. Refer to the appropriate product manual for the exact wiring details of

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Figure 3-13: Typical wiring to a fire panel with EOL

the third party equipment.

Figure 3-14: Input/Output Loop Module with EOL

VESDA VLI Product Guide VESDA by Xtralis

3.2.10 Typical Wiring for Monitored GPI for PSU Monitoring
(VLI-885only)

The diagram below shows the correct way to configure power supply monitoring with a VLI-885 detector. It
also shows where an End Of Line (EOL) resistor is correctly installed.

Legend

A End of Line Resistor (2.7k)

B External device (1 to N)

C GPI Pin 1

D GPI Pin 2

Figure 3-15: Power Supply Connection Diagram

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3.2.11 Specify Backup Battery

In the event of a mains power supply disruption, the VLI detector runs on a backup battery. The size of the
battery is determined by:

l local codes and standards
l the total power required by the system
l back up time required
l allowance for reduction in capacity with age
l expected temperature variations

Note: It is recommended that batteries be inspected and changed as per manufacturer’s specifications or

as per local codes and standards.

To facilitate the calculation of the backup battery size, a Battery Calculation Sheet is included below.

Table 3-2: Calculating the size of backup battery

Equipment Normal loads@ 24 V DC Full alarm load @ 24 V DC

Load mA Qty Total Load mA Qty Total

Detector 415 440

Remote Display 60 110

Remote Programmer 50

(backlight off)

Hand-held Programmer 50

(backlight off)

80

(backlight on)

70

(backlight on)

System Relay Module 60 105

Other 24V Loads Total

mA

X X

Standby Hours Alarm Hours

=

Standby Capacity Alarm Capacity

Total Capacity =
Standby + Alarm

Divided by 1000 for
Standby Capacity

Multiply by battery
factor X1.25

Total
mA

Note: If the GPI is set to Mains OK, the aspirator speed will be maintained for one hour after the loss of

mains power, after which the aspirator speed will be limited to the minimum speed (speed setting 1)
to conserve power.

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3.3 Powering Up

After installing the detector it is necessary to power up the system. The power up sequence lasts
approximately 15 seconds.

The VLI detector does not have a power switch i.e it is an "always on" device which is activated by applying
powered cabling to the power input terminal on the main board (Figure 3-7). This process must only be
performed by Xtralis accredited personnel.

If the system fails to power up, check all power wires are secured to their terminals and that the polarity is
correct.

On power up:

l The Power LED illuminates and the detector runs a series of self-diagnostic tests.
l If there is a fault, the Fault LED illuminates. To identify the fault, check the Active Event List for the

detector using the Xtralis VSC software.

l The aspirator starts up and air may be felt flowing out of the exhaust port.

It is normal for the detector to display troubles immediately after the first power up. Reset the detector by
pressing the reset button on the front of the unit. This will unlatch the relays and turn off the Fault LED. Any
remaining faults will cause the Fault LED to illuminate again. Proceed with the preliminary system check.

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3.4 Installation Checklist

Site Name

Address

Detector Serial Number(s) and Date of
Manufacture

Name of Installer

Signature

Date

Perform the following checks listed below to ensure that all the necessary items are completed before handing
over to a commissioning engineer.

Installation Checks Yes No

Were the detector and the mounting bracket intact in the box?

Is the detector securely locked onto its mounting bracket?

Are the sampling air pipes firmly connected to the air inlet ports? Ensure
that the pipes are NOT glued.

Have the power wires been connected to the correct terminals on the
detector?

If required, has the end of line resistor been connected?

Have the alarm and fault signaling wires been terminated to the correct
terminals of the detector?

Has the plug at the exhaust port been removed? Ensure that the exhaust
pipe (if fitted) is NOTglued.

Has the front cover been fitted correctly?

Is the air sampling pipework installed and checked as per the site plans?

Are the VESDAnet terminals looped back on a standalone VESDAnet
enabled detector? Refer to Section 3.2.4.

Is the Intelligent Filter installed and its lever locked down?

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3.5 Preliminary System Check

A preliminary system check is required after installing the VLI detector, before it is commissioned for use. The
check can be conducted by connecting to the detector using the Xtralis VSC software. The preliminary
systems check includes:

l Configuring the "pipes in use" setting. This option can be found in the Airflow settings tab of the VLI

configuration dialog in Xtralis VSC.

l Normalizing the air flow. This command can be found in the Device menu in Xtralis VSC. All detectors out

of the factory must be normalized.

l Conducting a basic pass/fail smoke test.

For details on the preliminary systems check, refer to the Commissioning Guide section of the
VESDASystem Design Manual.

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4 Pipe Network Design

The Pipe Network should be designed by trained personnel, and verified using the ASPIRE2 software.

4.1 Design Considerations

The following points should be considered when designing a pipe network for the VLI detector:

l At all times the detector requires a minimum total airflow of 40 liters per minute, and a minimum of 20 liters

per minute per pipe. It is possible that over a period of time sampling holes may block due to
environmental conditions which may result in reduced airflow, hence it is highly recommended that
detector and pipe flows be set to 20% higher than required minimums i.e. set detector flow to minimum 50
liters per minute and a minimum of 25 liters per minute pipe flow.

l It is preferred to use at least two pipes in the design (use pipe inlets 2 and 3) with a flow rate of at least 25

ltr/min per pipe, and detector flow rate at least 50 ltr/min. Verify the design using the ASPIRE2 software.
If required, use higher aspirator speed setting to meet these limits.

l Similarly, for single pipe installations, the pipe flow rate should be at least 50 liters per minute. Verify the

design using the ASPIRE2 software. If required, use higher aspirator speed setting to meet this limit.

l Avoid using exhaust pipes unless there is substantial pressure differential where exhaust pipe needs to

be go back to the sampling area, keep exhaust pipe length minimum. Refer to Section 4.4. for further
information.

l VESDA VLI is specifically designed to cater for industrial applications where high background levels

exist. It is recommended that minimum hole sizes of 3mm shall be used for these applications. Certain
industrial applications will require the facility to conveniently blow out (Back Flush) the pipe network
during maintenance regimes. Refer to Xtralis document 20016, Pipe Network Back Flush.

Refer to the VESDA Pipe Network Design Guide for best design practices.

4.2 Installation Considerations

The following points should be considered when installing sampling pipe:

l Minimize flexing in sampling pipes by supporting the pipe every 1.5m (5ft) or less, or at a distance

described in local codes and standards.

l Evenly arrange the sampling pipe network over return air grilles.
l Sampling pipe fits firmly into the tapered detector port, DO NOT glue this connection.
l Allow sufficient movement at the detector to permit pipe removal for maintenance.
l Keep the exhaust pipe as short as possible to minimize airflow resistance in the pipe.
l Pipe ends must be made smooth for bonding.
l Sampling holes must be drilled in line and perpendicular to the pipe.
l Sample holes must be clear of rough edges and debris.
l Pipes are free of debris.
l All joints must be bonded except the endcaps and pipes entering the detector.

Notes:

l Sampling holes should face into the direction of airflow, or point downwards in static airflow situations.
l Keep the sampling holes evenly spaced.
l Counter-sunk holes are recommended for harsh environments.
l For code-specific information, see Codes and Standards Information for Air Sampling Smoke Detection

on page iii.

Refer to the Pipe Network Installation Guide for best installation practices.

4.3 Inlet Pipes

The VLI detector supports up to four sampling pipes.

The air inlet ports in the pipe inlet manifold are tapered such that they accommodate both 25 mm (1 in) or IPS
¾ inch outer diameter pipes.

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1 2 3

4

Each air inlet port allows maximum insertion of the sampling pipe to a depth of 15 mm. (0.60 in). This prevents
the sampling pipes from damaging the flow sensors. While connecting the detector to the pipe network:

l Ensure a minimum length of 500mm (20in) of straight pipe before terminating the pipes at the air inlet ports

of the detector.

l Square off and de-burr the end of the sampling air pipes, ensuring the pipes are free from debris.
l Determine the Air Inlet Ports to be used. Refer to Table 4-1 below for details.
l Remove the plugs from only those Air Inlet Ports intended for use.
l Insert the pipes into the pipe inlet(s) ensuring a firm fit.

Note: DO NOT glue the inlet pipes to the pipe inlet manifold.

When configuring the detector ensure that the correct pipes in use are selected:

Table 4-1: Preferred use of pipe inlet ports

No. of Pipes Preferred Pipe Inlet Port to use

Pipe 1 Pipe 2 Pipe 3 Pipe 4

1 Inlet 2 or 3 Inlet 2 or 3

2

3 Inlet 1 or 4 Inlet 1 or 4

4

Figure 4-1: Pipe inlet port numbering

For code-specific information, refer to Codes and Standards Information for Air Sampling Smoke Detection on
page iii.

4.4 Managing the Exhaust Air

Air is expelled from the detector via the exhaust port at the bottom of the unit enclosure.

The air exhaust port is tapered to accomodate standard pipes of OD 25 mm (ID 21 mm) or IPS ¾ inch and to
provide an airtight seal. Remove the exhaust port plug and if required, connect an outlet pipe to the exhaust
manifold. DO NOT glue this pipe to the exhaust manifold as this will void the warranty.

Where the detector is located outside the protected environment, it may be necessary to return the exhaust air
to the same environment. For example, where pressure differences exceed 50 Pa, or where hazardous
substances are present inside the protected environmenet. Return air pipes need to be as short as possible to
minimize the effect of airflow impedance in the return air pipe network.

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5 Configuration

The VLIdetector is configured using Xtralis VSCsoftware installed on a direct or network connected PC.

The following information is provided in this chapter:

l how to connect to a standalone detector
l how to connect to a detector on an Ethernet network
l how to connect to a detector on a VESDAnet
l access levels
l commands
l configuration options
l relay options
l GPI functions
l default settings

5.1 Connecting to a Standalone VESDA VLI Detector

Once physical connectivity has been established (refer to Section 3.2.3), the Xtralis VSC software can
connect to the VLI detector using one of a range of communication protocols. Connection methods must be
defined and saved for future use within the Connection Manager in Xtralis VSC.

To define a connection to a standalone VLI detector connected via USBor Ethernet, follow this procedure:

1. Select Connection | Manager from the menu system.
The Connection Manager dialog is displayed.

Figure 5-1: Connection Manager

2. Select Add.
The Add Connection dialog is displayed.

Figure 5-2: Add Connection

3. Select the BACnet connection option, then select Next.

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5.1.1 Creating a USB Connection

1. Open the VLI detector and connect the USBcable from the USB socket on the main board inside to a
PCor laptop located near the detector with the Xtralis VSCsoftware installed. Refer to Chapter 7 for
further information on opening the detector.

2. Follow the steps in Section 5.1.

3. Select BACnet from the Add Connection dialog box (Figure 5-2).

4. Select USB, then select Next (Figure 5-3).

Figure 5-3: Select USB

5. Select the detector type from the list of available detectors, then select Next (Figure 5-4).

Figure 5-4: Select Device

6. Accept the pre-generated BACnet Device ID number, then select Next (Figure 5-5).

Figure 5-5: Enter a BACnet ID

7. Enter a unique name for the Connection or accept the pre-generated name, then select Finish (Figure 5-6).

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Figure 5-6: Enter a Connection Name

5.1.2 Creating an Ethernet (BACnet/IP) Connection

Notes:

l If a number of detectors are networked via Ethernet, it is recommended that they be connected to a

dedicated Ethernet switch and then the switch is connected further up in the network with adequate
security measures to limit access only to authorized personnel.

l The VLI is not secured. It is responsibility of the enterprise using VLI detectors to protect them on an

Ethernet network for use by authorised personnel only.

1. Follow the steps in Section 5.1.

2. Select BACnet from the Add Connection dialog box (Figure 5-2).

3. Select Ethernet (BACnet/IP), then select Next (Figure 5-7).

Figure 5-7: Select Ethernet (BACnet/IP)

4. Enter a unique IP address, then select Next. If the detector is being connected to a corporate or dedicated
network, this address may need to be provided by the network administrator (Figure 5-8).

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Note: The factory default IPAddress for the VLI is 169.254.1.100. This allows direct connection

between a PCor Laptop and the VLI using a standard Ethernet lead. To change the IPaddress
it is necessary to connect to the VLI using a USB connection and use Xtralis VSC to edit the
network settings for the detector.

Figure 5-8: Enter IP Address

5. Enter a unique BACnet Device ID, then select Next (Figure 5-9).

Figure 5-9: Enter BACnet Device ID

6. Enter a unique name for the Connection, then select Finish.

Figure 5-10: Enter Connection Name

Note: For specific information relating to network configuration, refer to the VESDA Communications

Guide.

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5.2 Connecting to a VESDA VLIon VESDAnet

The following is required in order to access a VLI-885 via VESDAnet:

l the VESDAnet is physically connected, as described in Section 3.2.4.
l a High Level Interface (HLI) must be connected between the PCor Laptop with Xtralis VSC and an

RS485 port in one of the devices on the VESDAnet.

l a connection to the VESDAnet has been defined in the Xtralis VSC connection manager. See below for

the procedure to do this.

Note: Refer to the VESDACommunications Guide for detailed information on VESDAnet.

Define to a new VESDAnet Connection

1. Follow the steps in Section 5.1.

2. Select VESDAnet from the Add Connection dialog box (Figure 5-2).

3. Select the COM port associated with the High Level Interface (HLI) connected to your PCor Laptop and
click on the Next button.

4. Enter the name you want to identify the connection with in the Name field and click on the Finish button.

Access the VESDA VLI

1. Connect to the VESDAnet in Xtralis VSC using Connection Manager. The software automatically polls
the VESDAnet for devices and lists them in the VESDAnet device list, or marks them active if they were
manually added..

5.3 Access Levels

When first accessing the VLI detector via Xtralis VSC or LCDProgrammer, user functionality is limited. For
additional privileges, the user must log in to the detector using a four digit PINcode. In Xtralis VSC, select
Logon from the Connection menu and enter the PIN.

Table 5-1: User Access Levels

User Level Access Level Functional Authorization

USR Low This is the USER or the OPERATOR level. The user can view

the event log and change the date and time. They can also
perform selected zone control functions.

ADM High At the ADMINISTRATOR level access is available to most

functions. These include setting alarm thresholds, normalizing
air flows, reset filter, and defining the relay configuration.

DST Absolute The DISTRIBUTOR level allows unlimited access to all the

system commands and parameters.

The default PIN for each level of user is set at the factory. The distributor has access to the PINs for each
level. PIN numbers are disclosed to authorized personnel attending accredited training courses.

After logging in the user has the option to change the default PIN. To guard against unauthorized access, if
someone enters an incorrect PIN number three times they will not be allowed another attempt for ten minutes.

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5.4 Commands

The following commands are able to be issued to the detector from the Device menu in the Xtralis VSC
software:

Table 5-2: Detector Commands

Command Description Execute From

Detector Xtralis VSC

Disable The Disable command disables all the

output relays associated with the detector.
The aspirator remains active.

Enable The Enable command enables all of the

output relays associated with the detector.

Go to Standby The Go to Standby command deactivates

the aspirator and stops all signaling.

End Standby The End Standby command is available

when the detector is in Standby mode.
Restarts the aspirator and resumes all
signaling.

Reset The Reset command unlatches all latched

alarms and faults, and returns relays to their
normal state. Clears the active event list.

Reset does not enable a disabled detector
or reactivate a detector that is in Standby
mode.

Start Air Flow Normalization Starts the air flow normalization process for

the selected detector.

The normalization process determines the
reference flow rate.

The detector can be in normal or disabled
mode, but not standby mode.

The aspirator remains on throughout the
normalization process and no fault is
reported unless the process fails to
successfully complete.

The normalizing status may be observed on
the "detailed status" tab in the Xtralis VSC
software.

Start AutoLearn Flow In Xtralis VSC you will be prompted to set

the period of time that the environment is
monitored to allow the system to decide
what flow thresholds are most appropriate.

When the AutoLearn has finished, the
levels are overwritten.

Cancel AutoLearn Flow Cancel the AutoLearn Flow process.

Flow thresholds will remain at levels set
prior to commencing AutoLearn Flow.

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Table 5-2: Detector Commands (continued...)

Command Description Execute From

Detector Xtralis VSC

Start AutoLearn Smoke In Xtralis VSC you will be prompted to set

the period of time that the environment is
monitored to allow the system to decide
what smoke thresholds are most
appropriate.

When the AutoLearn has finished, the
levels are overwritten.

Cancel AutoLearn Smoke Cancel the AutoLearn Smoke process.

Smoke thresholds will remain at levels set
prior to commencing AutoLearn Smoke.

Return to Factory Defaults Restores the configuration of the detector

to the initial factory default values.

Set System Date and Time Set the detector date and time.

Start Major Fault Test Generate a major fault on the detector and

de-energizes the fault relay for 2 minutes.

Start Minor Fault Test Generate a minor fault on the detector and

de-energizes the fault relay for 2 minutes.

Start Alarm Test Simulate full scale smoke level and initiates

all alarm activity.

Alarm relays will energize unless the
detector is disabled.

Start Airflow Fault Test Test the air flow sensing system by

shutting down the aspirator.

Start Relay Test Test the available relays by activating and

deactivating as required.

Start Lamp Test Cycle through each lamp on the detector

display panel.

Clean Air Zero Chamber Validate clean air reading to ensure

absolute detection and safeguard against
nuisance alarms.

Note: This command will shut down

the aspirator for up to a minute.

Reset Intelligent Filter Life Reset the Intelligent Filter status

information. Execute this command after
installing a replacement Intelligent Filter.

Reset Secondary Filter Life Reset the Secondary Foam Filter status

information. Execute this command after
installing a replacement Secondary Foam
Filter.

Reset Aspirator Life Reset the smoke hours for the aspirator.

Execute this command after installing a
replacement aspirator.

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5.5 Configuration Options

The VESDA VLI device dialogue provides a range of configuration options. These settings are stored in the
onboard memory of the detector, therefore any change made using Xtralis VSC which can be viewed on a
VESDAnet will be visible on a programmer, and vice versa.

The following sections provide detector configuration based on using the Xtralis VSC software. Information
on using the LCDProgrammer is contained in the LCDProgrammer Product Guide.

5.5.1 General Options

General options include some basic identification and Ethernet connectivity information for the detector.

Figure 5-11: General Options

The General configuration options are as follows:

Location

A description of the physical location of the device.

Serial Number

The serial number of the device. This is factory set and cannot be changed.

Address

This field is contains a unique BACnet address. It is based on the serial number and should not be changed.

IP Address

The IP address of the detector, for use with Ethernet connections. This address must be used when creating a
connection profile for the detector in Xtralis VSC.

The default IPaddress is 169.254.1.100. This allows direct connection between a PC or Laptop and the
VESDA VLI using a standard Ethernet lead.

Prior to connecting the detector to a router or other gateway device, the default address must be changed to
an address in the range used by the router. This can be done by connecting to the detector via USBor via
Ethernet with a standard Ethernet lead.

Subnet Mask

The subnet mask for the device and broker addresses.

Default Gateway

The IPaddress of the router or other gateway device that is servicing the network.

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5.5.2 Smoke Threshold Options

Smoke Threshold options provide the mechanism to set the smoke obscuration trigger point for each alarm
level, and the ability to assign day or night thresholds to cater for different levels of activity in the protected
area during these times.

Refer to Section 5.6 for the default settings.

Figure 5-12: Smoke Threshold Options

The Smoke Threshold configuration options are as follows:

Apply UL Limits

If checked, the fire threshold will be limited to ensure that the detector is UL compliant. Ensure that when
Apply UL limits is checked, Fire2 is set to the UL limit by exiting and then going back to the Smoke
Thresholds options.

Day Thresholds

The settings for day time smoke thresholds. The threshold and the delay are used together to decide when to
trigger the alarm condition.

Night Thresholds

The settings for night time smoke thresholds. The threshold and the delay are used together to decide when to
trigger the alarm condition.

Delay

The length of time between the alarm threshold being reached and the relay operation.

l Cumulative Delay: If checked, the delay period for alarms is set to cumulative.
l Instant Fire: If checked, the time delays are ignored when the smoke level increases rapidly.

Significant Smoke Change

The smoke change level at which an event is recorded in the Event Log. The VLIis designed for harsh
environments, so it is recommended that the Significant Smoke Change value is set to 0.05 %/m (0.015 %/ft)
or half the value of the Alert level, whichever is greater.

Changeover

l Work Days: Select which days use both day and night thresholds. Night time thresholds are used if a day

is not selected.

l Day / Night Changeover Time: The settings for the timing of the threshold changeover.
l Holidays: The settings used to define a holiday period. Use the dropdown calendars to choose the start

and end times of the holiday (or break) period. Night time thresholds are used during the holiday period.

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5.5.3 Airflow Options

Airflow options provide the ability to set:

l limits for what the detector considers to be normal airflow behavior for the sampling pipe network
l which pipe inlets are being used
l aspirator speed

These settings should be confirmed in the ASPIRE2 design of the sampling pipe network.

Refer to Section 5.6 for the default settings.

Figure 5-13: Airflow Options

The Airflow configuration options are as follows:

Air Flow

The air flow conditions, as a percentage of the normalized air flow, that will cause a fault to be reported. If the
installation site flow conditions vary significantly, it is recommended that the Major High and Major Low
parameters are set closer to their limits.

l Major High: The level of air flow considered to be so far above normal as to require urgent attention.
l Minor High: The level of air flow considered to be above normal but not urgent.
l Minor Low: The level of air flow considered to be below normal but not urgent.
l Major Low: The level of air flow considered to be so far below normal as to require urgent attention.

Significant Flow Change

The amount of airflow change at which an event is recorded in the event log.

Delay

The length of time between the air flow fault threshold being reached and the relay operation.

Pipes in Use

The pipes that are actually being used. Refer to Section 4.3 on page 31 for further information.

Aspirator Speed

The speed of the aspirator.

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5.5.4 Input / Output Options

Input / Output options provide the ability to control the behavior of the General GPI and latching behavior of the
fault and alarm relays.

The unmonitored GPI can be configured to initiate a number of different actions - including, by default, a
Remote Reset function.

Figure 5-14: Input / Output Options

The Input / Output configuration options are as follows:

General Purpose Input (GPI)

The GPI is a remote input device for the detector that can be programmed to perform one of several functions.
Refer to Table 5-3 below for a description of the individual selections.

l Detector GPI Function (Unmonitored): Supported by VLI-880 and VLI-885.
l VESDAnet Card GPI Function (Monitored): Supported by VLI-885.

Latching

l If Fault is checked, the fault relay is energized during normal operation. This means that should the

detector suffer a power failure, the relay will go to the non-energized fault condition. This is the
recommended setting.

l If Alarm is checked, the alarm relay is energized during normal operation. This means that should the

detector suffer a power failure, the relay will go to the non-energized alarm condition. This is NOT the
recommended setting.

Button Lockout

If checked, the Reset / Disable button on the front of the detector is disabled.

Table 5-3: Unmonitored GPI Operation

Function State Change

External Reset Detector Reset on a 0 VDC to 5 VDC

rising edge.

Mains OK The detector monitors the state of the

external power supply and responds to the
following conditions.

l Mains OK ≥ 5 VDC at this terminal.
l Mains Fail ≤ 2 VDC at this terminal.

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Table 5-3: Unmonitored GPI Operation (continued...)

Function State Change

Standby Mode The detector is disabled and the aspirator

switched OFF when ≥ 5 VDC is at this
terminal.

Note: No Alarms can be generated in

this state.

Disable The detector disables when the voltage

rises above 5 VDC and is enabled when
the voltage falls below 5 VDC.

Use Night-time
Threshold

The detector switches over from day-time
to night-time thresholds when ≥ 5 VDC is
at these terminals.

Reset + Disable While power is applied to the GPI the

detector is disabled. In addition, the
disconnection or connection of power to
the GPI resets the unit.

l ≥ 5 VDC detector disables.
l ≤ 2 VDC detector reset.

Inverted Reset

(VLI-885 only)

The detector is reset on falling edge 5
VDC to 0 VDC.

Notes:

l The signal voltage into the GPI terminals must be between 5 to 30 VDC.
l When the detector is disabled, enabled or set to standby as a GPI function, the status cannot be changed

through the normal enable / disable / standby functions of the Display Module or the LCD Programmer.

l When the night-time threshold is configured as a GPI function, it overrides the clock settings for day-start

and night-start.

When using the standby or remote disable options it is recommended that all displays on VESDAnet are
configured to have the Isolate button locked out. When programming the display through the LCD Programmer
choose Isolate Disabled from the Button Lockout menu.

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5.5.5 Relay Options

Relay options provide the ability to determine which alarm or fault conditions the programmable relays
respond to.

Figure 5-15: Relay Options

The Alarm relay is permanently assigned to Fire1, while the Fault Relay is permanently assigned to all fault
and other non-alarm conditions, with the exception of Minor Fault.

Three additional relays, CFG1, CFG2 and CFG3, are fully configurable. For example, CFG1 could be
configured to Alert, Fire2 or Minor Fault.

The normal state of the programmable relays can be set using checkbox in the Normally Energized row for a
relay where:

l checked means the relay is energized.
l unchecked means the relay is de-energized.

Table 5-4: Relay assignments and conditions to change state

Relay Default State changes Latch

Alarm Fire1 (Alarm) Energizes when an alarm is initiated. Unlatched

Fault Fault De-energizes when a fault is detected. Latched

CFG 1,2,3 n/a Configurable Configurable

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5.5.6 Communications Options

Communications options are available for the VESDAnet-enabled VLI-885 detector. They provide the ability to
control network data transmission behavior.

Refer to Section 5.6 for the default settings.

Figure 5-16: VESDAnet Communications Options

The Communications configuration options are as follows:

Preferred Port

The preferred VESDAnet port to be used to transmit network data from this device. The non-preferred port is
used if for some reason transmissions on the preferred port fail.

For best performance in large networks, this setting should be randomly distributed between connected
devices.

Loop Open Ended on This Device

If checked, the network has been wired so no connection will be terminated on this port.

If the detector is the last on an open-ended loop, i.e. the non-preferred port is not connected, this should be
checked.

Status Update Interval

The interval between status events for the selected detector within its zone.

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5.5.7 Referencing Options

Referencing is a technique used to reduce false alarms.

The VLIrequires VESDAnet connectivity to separate detector located outside of the protected area, which is
used to take readings of the background level of smoke and pollutants outside of the protected area. These
readings are then referenced to the readings from the detectors in the protected area. This allows the
detectors inside the protected area to determine if a rise in smoke levels is due to background pollution or a
problem inside the protected area.

Refer to Section 5.6 for the default settings.

Figure 5-17: Referencing Options

The Referencing configuration options are as follows:

l Referencing Enabled: If checked, referencing is enabled.
l Detector: The name of the detector or system which provides the reference signal. Select from other

detectors on the VESDAnet.

l Delay: The length of time between the external smoke rise and the internal subtraction of the smoke rise.
l Dilution Factor: The percentage of the reference signal to be subtracted from the internal detector signal.

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5.6 Default Settings

Table 5-5: Default Settings

Parameter Default Values Range Access

Minimum Maximum

Event Log - Events

l Smoke Level Enabled n/a n/a Adm

l Alarms Enabled n/a n/a Adm

l Faults Enabled n/a n/a Adm

l User Action Enabled n/a n/a Adm

Thresholds

Level

l Alert 0.2% obs/m

(0.064% obs/ft)

l Action

(Pre-Alarm)

l Fire1

(Alarm)

l Fire2 2.0% obs/m

0.3% obs/m

(0.096% obs/ft)

0.4% obs/m

(0.128% obs/ft)

(0.64% obs/ft)

0.05% obs/m

(0.016% obs/ft)

0.1% obs/m

(0.032% obs/ft)

0.15% obs/m

(0.048% obs/ft)

0.155% obs/m

(0.05% obs/ft)

1.990% obs/m

(0.637% obs/ft)

1.995% obs/m

(0.638% obs/ft)

2.0% obs/m

(0.64% obs/ft)

20.0% obs/m

(6.4% obs/ft**)

Adm

Adm

Adm

Adm

Alarm Delays 10 Seconds 0 Seconds 60 Seconds Adm

Delay Times Simultaneous Simultaneous Cumulative Adm

Instant Fire Disabled Enabled Disabled Adm

Change-over Times:

l Day
l Night

Weekend Saturday & Sunday Adjust to suit

l 07:00:00
l 19:00:00

Two Seconds 11:59:58 Adm

environment

Adjust to suit
environment

Adm

Holidays

l First Day
l Last Day

l 1-Jan-90
l 1-Jan-90

Adjust to suit
environment

Adjust to suit
environment

Adm

Smoke Change:

l Change by:
l Min. Interval

AutoLearn 14 days

l 0.02% obs/m

(0.006% obs/ft.)

l 2 seconds

0 hours
0 minutes

l 0.02% obs/m

(0.006%obs/ft.)

l 2 seconds

0 days
0 hours
15 minutes

l 0.2% obs/m

(0.064% obs/ft.)

l 10 seconds

15 days
23 hours
59 minutes

Adm

Adm

Air flow Thresholds:

l High Urgent
l High Minor
l Low Minor
l Low Urgent
l Delay

Secondary Filter

l 150%
l 130%
l 70%
l 50%
l 0 seconds

l 105%
l 105%
l 25%
l 25%
l 0 seconds

l 200%
l 200%
l 95%
l 95%
l 60 seconds

Adm

1460 days (4 years) 1 Day 3655 days (10 years) Adm

Service Interval

ULVersion On Selectable Selectable Adm

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Table 5-5: Default Settings (continued...)

Parameter Default Values Range Access

Minimum Maximum

Level

VESDAnet enabled detectors

Reference detector:

l Reference
l Dilution Delay

l 100%
l 2 minutes

l 1%
l 0 minutes

Detector Comms:

l Preferred Port
l Open - ended

l A
l None

l n/a
l n/a

VESDAnet Comms:

l Health Check
l Network Delay

** In default "UL mode", maximum sensitivity is limited to 4%/ft

l 45 seconds
l 15 seconds

l 40 seconds
l 10 seconds

l 100%
l 15 minutes

l n/a
l n/a

l 60 seconds
l 45 seconds

Adm

DST

DST

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6 Commissioning

The VLI has been designed to simplify commissioning processes. The AutoLearn function allows the unit to
assess its environment and setup appropriate alarm and flow thresholds.

The detector is programmed using Xtralis VSCsoftware or LCDProgrammer via VESDAnet.

Once the VLI detector has been commissioned, it will report alarms and faults according to the parameters
defined during installation.

Note: Detectors should be commissioned with a smoke test.

Prior to commissioning the detector:

1. Check that the pipe network is clean and correctly fitted with all joints correctly seated and sealed (except
the endcaps and the pipe which enters the detector which must not be glued). Ensure that the relevant
pipes are selected as in use in Xtralis VSC.

2. Check that the power is connected and on. Let the detector run for around 15 minutes, ensuring that the
pipe flow rates comply with the minimum requirements listed in Section 4.1. Ignore the faults during this
time. Reset the detector after 15 minutes of operation.

3. Normalize the airflow. This takes approximately 10 minutes. The pipe flow rates should now be close to
the ASPIRE2 predictions.

4. Reset the detector after normalization. It should now be running without faults, providing the flow rates are
maintained as indicated in Section 4.1.

It is important that the protected environment is working under normal operating conditions when operating the
AutoLearn processes.

For code-specific information, see Codes and Standards Information for Air Sampling Smoke Detection on
page iii.

6.1 AutoLearn Smoke

AutoLearn Smoke is initiated by using Xtralis VSC or the LCDProgrammer.

During the AutoLearn Smoke process, the detector determines the average smoke and peak smoke
obscuration levels and sets suitable alarm thresholds for the operating environment. This process will
minimize nuisance alarms due to normal environmental background variations.

During the learning cycle, if an alarm condition occurs, AutoLearn will not complete its cycle. In this situation
the user must restart the AutoLearn process. If AutoLearn is halted, the alarm thresholds will be left at the
previous settings.

Conditions experienced during learning are assumed to be representative of normal operating conditions.

The AutoLearn Smoke learning times range from above 15 minutes to 16 days, with the default being set to 14
days.

If AutoLearn is running during the changeover period from Day to Night Thresholds, make sure that AutoLearn
runs for at least an hour in both the Day and Night periods.

Table 6-1: AutoLearn Smoke range

Alarm Level AutoLearn Smoke Range

Alert 0.05%–1.990% obs/m (0.016% - 0.637% obs/ft)

Action (Pre-Alarm) 0.1%–1.995% obs/m (0.032% - 0.638% obs/ft)

Fire1 (Alarm) 0.15 %–2.0% obs/m (0.048% - 0.64% obs/ft)

Fire2 0.155 %–20.0% obs/m (0.05% - 6.4% obs/ft)

For code-specific information, see Codes and Standards Information for Air Sampling Smoke Detection on
page iii.

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6.2 AutoLearn Flow

AutoLearn Flow process is initiated within Xtralis VSC.

During the AutoLearn Flow process, the detector determines the average and peak air flow levels monitored
over time and sets suitable air flow thresholds that will not give rise to nuisance flow faults due to normal flow
variations. The system will normalize the flow and then monitor the flow trend to set the flow fault thresholds.

During the learning cycle, if a flow fault is reached, AutoLearn will not complete its cycle. In this situation the
user must restart the AutoLearn process. If AutoLearn is halted, the flow thresholds will be left at the previous
settings.

Conditions experienced during learning are assumed to be representative of normal operating conditions.

The AutoLearn Flow learning times range from 15 minutes to 16 days, with the default being set to 14 days.

6.3 Commissioning Smoke Test

It is recommended that a smoke test be carried out to verify the integrity of the pipe network, to demonstrate
that the system is working and to measure the transport time to the detector.

This test involves introducing a smoke sample at the furthest sampling hole and then measuring the time
taken for the smoke to travel to the detector. Results are logged and compared to subsequent tests to note
variations of the system.

Refer to the VESDA Commissioning Guide for details of the commissioning smoke test.

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7 Maintenance

To maintain the VLIdetector at its peak performance level, the recommended maintenance schedule shown in
Table 7-1 below should be followed.

Table 7-1: Recommended maintenance schedule for the VLI detector

Maintenance Check Quarterly Six

Annual Biennial Quadrennial

Monthly

Power Supply and Battery

Check Pipe Network

Pipe Integrity Smoke Test

Check Pipe Flow

Clean Sampling Point

Flush Pipe Network

Replace Intelligent Filter

Replace Secondary Foam
Filter

Notes:

l The above maintenance steps are preventative maintenance. The VLI detector is intelligent and will

therefore raise appropriate faults when a part requires replacement.

l The recommended Intelligent Filter and Secondary Filter replacement intervals are based on average

background level of 0.05%/m (0.015%/ft). Lower average background levels result in less frequent
replacement and higher background levels may necessitate more frequent replacement.

l Maintenance can be conducted by the original installer or an authorized distributor or service contractor.
l The required frequency of maintenance checks may vary depending upon local codes and standards and

the environment of the installation.

Caution: While the detector or zone is disabled, no fire warnings will be annunciated by the detector. Prior

to any maintenance or testing:

l Inform appropriate supervising authority about the risk associated with isolating a detector

or zone.

l Check to see if the detector is also being used by a third party.
l Ensure that any ancillary devices dependent on the detector are isolated before work

commences.

7.1 Set the Detector to Standby

Setting the VLI to Standby mode deactivates the aspirator and stops all signaling.

To set the detector to Standby mode, select Go to Standby from the Device menu. The Disabled LED will
blink and the aspirator will turn off.

To re-activate the unit, select End Standby from the Device menu.

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1

7.2 Remove the Front Cover

Several maintenance functions require that the front cover be removed from the VLI detector in order to
perform them. The front cover is held on by four captive screws. It may be removed by turning the screws
counter-clockwise.

Caution: Electrostatic discharge (ESD)precautions need to be taken prior to removing the front cover

from the detector in order to prevent damage to sensitive electrical components within the VLI
detector.

Remove the Front Cover

The front cover is held on by four captive screws and a tether. It may be removed by turning the screws
counter-clockwise.

Figure 7-1: Front cover removal

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A

B

C

4x

A

D

B

7.3 Replacing the Intelligent Filter

The detector constantly monitors the difference between the flow of filtered and un-filtered air into the
manifold. The flow of filtered air decreases when compared to that of un-filtered air as dirt and other particles
accumulate in the Intelligent Filter. Although it is recommended to replace the Intelligent Filter every two
years, environmental conditions dictate the actual frequency of Intelligent Filter replacement.

The detector reports a fault condition that requires replacement of the Intelligent Filter when the flow of filtered
air falls below the minimum threshold when compared to the flow of un-filtered air.

Remove the Intelligent Filter

1. Set the detector to Standby mode. Refer to Section 7.1 for further information.

2. Remove the front cover. Refer to Section 7.2 for further information.

3. Unclip the Intelligent Filter (A) by pulling the locking lever outward (B).

4. Remove the Intelligent Filter.

Figure 7-2: Intelligent Filter Removal

Reinstall the Intelligent Filter

1. Position the Intelligent Filter inside the detector, aligning the locking tabs (A) to the slots (B).

2. Push the locking lever in the direction of arrow (C) until it clicks into the locked position and the Intelligent
Filter Present Switch (D) is actuated.

3. Execute the "Reset Intelligent Filter Life" command using Xtralis VSC. Refer to Section 5.4 for further
information on this command.

Caution: Do not reinstall a used filter.

Figure 7-3: Intelligent Filter Installation

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A

B

7.4 Replacing the Secondary Foam Filter

To maintain the operational integrity of the detector, it is recommended that the Secondary Foam Filter be
replaced every 4 years, or when a filter fault occurs. It may be necessary to replace the filter more often where
the detector is installed in environments that experience high levels of contamination.

Remove the Secondary Foam Filter

1. Set the detector to Standby mode. Refer to Section 7.1 for further information.

2. Remove the front cover. Refer to Section 7.2 for further information.

3. Remove two secondary foam filter screws (A).

4. Remove the secondary foam filter (B).

Figure 7-4: Secondary Foam Filter Replacement

Reinstall the Secondary Foam Filter

To reinstall the Secondary Foam Filter, follow the removal procedure in reverse order and execute the "Reset
Secondary Filter Life" command in Xtralis VSC.

Caution: Do not reinstall a used filter.

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B

A

C

7.5 Replacing the Aspirator

Ensure the area surrounding the aspirator is clear of dirt and debris prior to replacement.

Care must be taken during aspirator replacement. The aspirator must be correctly seated; this is essential to
ensure gaskets are not damaged or dislodged from the underside of the aspirator.

Remove the Aspirator

1. Set the detector to Standby mode. Refer to Section 7.1 on page 53 for further information.

2. Remove the front cover. Refer to Section 7.2 on page 54 for further information.

3. Power down the detector by removing the 24V input. Refer to Section 3.2.2 on page 20 for further
information.

4. Remove the Intelligent Filter (Figure 7-5). Refer to Section 7.3 on page 55 for further information.

Figure 7-5: Intelligent Filter Removal

5. Remove the three Aspirator screws (A) and the two screws on the exhaust port (B).

6. Remove the Aspirator (C).

Figure 7-6: Aspirator Replacement

7. Flip the aspirator and disconnect the Aspirator cable.

Reinstall the replacement Aspirator

1. Ensure that the 24V input is still disconnected.

2. Connect the aspirator cable.

3. Install the new aspirator (C), the three aspirator screws (A) and the two screws on the exhaust port (B).

4. Reinstall the Intelligent Filter. Refer to Section 7.3 on page 55 for further information.

5. Power up the detector by reattaching the 24V supply.

6. Wait approximately 10 minutes to ensure that the detector does not report any fault conditions.

7. Perform a smoke test and ensure detector response is as per commissioning data.

8. If the replacement aspirator is brand new, execute the "Reset Aspirator Life" command in Xtralis VSC.

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7.6 Replacing the Detection Chamber Assembly

Notes:

l It is important to precisely follow the sequence below in order to avoid kinking the tubes
l Remove the longer tube near the secondary filter first, followed by the shorter tube near the aspirator.

Requirements

l Philips head screwdriver
l 10mm spanner or flat-blade screwdriver

Remove the Detection Chamber Assembly

1. Set the detector to Standby mode. Refer to Section 7.1 on page 53 for further information.

2. Remove the front cover. Refer to Section 7.2 on page 54 for further information.

3. Power down the detector by removing the 24V input. Refer to Section 3.2.2 on page 20 for further
information.

4. Remove the Intelligent Filter (Figure 7-7). Refer to Section 7.3 on page 55 for further information.

Figure 7-7: Intelligent Filter Removal

5. Remove the two screws (A) holding the chamber (Figure 7-8).

Figure 7-8: Remove Chamber Mounting Screws

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6. Use a 10mm spanner or a large flat bladed screwdriver to press down on the black ring near the secondary
filter (B) whilst simultaneously using the other hand to remove long tube (Figure 7-9).

Figure 7-9: Remove Long Tube

7. Repeat the step above on the black ring (C) near the aspirator to remove the shorter tube (Figure 7-10).

Figure 7-10: Remove Short Tube

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8. Gently remove the Chamber. To prevent the tube from kinking, lift the chamber while removing the tube
(Figure 7-11).

Figure 7-11: Lift Chamber

9. Unlock the connection arms and disconnect the ribbon cable from the main board (Figure 7-12).

Figure 7-12: Disconnect Ribbon Cable

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Install a new Chamber Assembly

1. Ensure that the 24V input is still disconnected.

2. Plug the ribbon cable from the chamber into the main board (Figure 7-12). Ensure that the cable connector
is fully in and arms are locked.

3. Fold the ribbon cable under the chamber and hook it on the tabs provided (Figure 7-13).

Figure 7-13: Ribbon Cable Hooks

4. Insert chamber in slots but hold the chamber 20mm from bottom (Figure 7-14).

Figure 7-14: Insert Chamber

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5. Insert the short tube into the Cartsick connector under the fan and lower the chamber while inserting
(Figure 7-15).

Figure 7-15: Lift Chamber

6. Insert the short tube until the white tape touches the black ring on the Carstick connector (Figure 7-16).

Figure 7-16: Insert Short Tube

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7. Insert the long tube near the Secondary Foam Filter Carstick connector and lower the chamber whilst
inserting (Figure 7-17).

Figure 7-17: Insert Long Tube

8. Insert the long tube until the white tape touches the Carstick connector.

Figure 7-18: Complete Long Tube Insertion

9. Insert the two chamber screws (Figure 7-8).

10. Reinstall the Intelligent Filter. Refer to Section 7.3 on page 55 for further information.

11. Power up the detector by reconnecting the 24 Volt input.

12. Wait approximately 10 minutes to ensure that the detector does not report any fault conditions.

13. Perform a smoke test and ensure detector response is as per commissioning data.

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7.7 Spare Parts

Gray-colored internal components such as the Intelligent Filter, Secondary Foam Filter, Detection Chamber
and Aspirator are field-replaceable.

Table 7-2: Suggested spare parts stock

Part No. Description

VSP-030 VLI Intelligent Filter

VSP-031 VLI Secondary Foam Filter

VSP-032 VLI Aspirator

VSP-033 VLI Chamber Assembly

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8 Troubleshooting

If the VLIdetector identifies a fault condition, the Fault LED on the front of the detector illuminates and an
event containing details of the condition is written to the active event list.

Tools such as the LCD Programmer or the Xtralis VSCsoftware must be used to obtain specific information
on the event to enable further investigation and correction of the fault. The Xtralis VSC Online Help contains
descriptions of each fault and recommended corrective actions.

8.1 Fault Reporting through Relays

VESDA devices are often interfaced with Fire Alarm Control Panels (FACPs) or building management
systems (BMS) via relays. In such instances the fault relays signal a fault condition to the FACP or the BMS.
It would be necessary to use an LCD Programmer or Xtralis VSC software to further investigate the fault.

8.2 Troubleshooting with Xtralis VSC

The Xtralis VSCsoftware displays faults in the active event list as they occur. The list displays the date and
time of the fault, the serial number of the device on which the fault has occurred, the zone number, fault
number, and a description of the fault.

For detailed information about a fault, access the device tree menu, highlight the device, and select device
information. This will display the details of the fault.

The fault is removed from the active event list once the it is cleared.

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8.3 Troubleshooting with a Remote Display

If a Remote Display unit is connected to the detector, the specific fault type will be indicated on the Remote
Display. The fault types shown on the display are listed below in Table 8-1.

Table 8-1: Fault Types indicated by the Remote Display

Fault Type Description

Urgent A serious fault requiring immediate attention.

System A fault affecting the network.

Zone A Zone fault in the display module.

Power If the monitored GPI Function is used, and this LED is lit it indicates

a fault in the power supply,

Network A communications fault on VESDAnet.

Airflow Higher or lower than acceptable levels of air flow through the inlet

pipe.

Filter An air filter requires changing.

Note: It is normal for a new system to indicate airflow faults. These are rectified as part of the setup and

commissioning process.

8.4 Troubleshooting with an LCD Programmer

The LCD Programmer reports individual device faults. The faults are reported in the status screen and are
clearly identified with a “F” icon against the fault. Details of the faults can be interrogated through the “status”
option of the respective device.

For further details please refer to the LCD Programmer Product Guide.

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A Commissioning Forms

This is the main commissioning form for each customer site.

Table A-1: VESDA commissioning form

Customer Name

Site Address

Installer (Name & Contact)

Commissioner (Name &Contact)

Checks Date:

1. Wiring Checked

2. Detector Diagnostics

3. Display Diagnostics

4. Test Relay

1.

2.

3.

4.

Client Representative Name

1. Test witnessed by:

Hand Over Documents

1. Copy of this form

2. ASPIRE2 Installation Data Pack

3. ASPIRE2 Bill of Materials

4. Commissioning form or printout from Xtralis VSC
or Xtralis VSM4 for each detector

5. Commissioning form or printout from Xtralis VSC
or Xtralis VSM4 for each display module

6. Smoke test results

7. Forms required for compliance with local codes
and standards

Customer's Signature

Commissioner's Signature

Date:

Date:

Date:

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A.1 VLI Detector Commissioning Form

For all VESDAnet systems, highlight the device, the zone or VESDAnet then select File > Print to file.

Table A-2: VLI Detector commissioning form

Address (Zone)

VESDA Zone Name

Module Type VLI-

Firmware Version

Card Inserted VESDAnet Interface Card or None

Alarm Thresholds Significant

Smoke

Day Action

(Pre-Alarm)

Fire1
(Alarm)

Day/Night Changeover Enable /

Disable

Day starts: Dilution%

Night starts: Delay

Night Action

(Pre-Alarm)

Fire1
(Alarm)

Delay Action

(Pre-Alarm)

Fire1
(Alarm)

Instant Fire Enable /

disable

Secondary
Foam Filter

Reference
Detector

Flow
Threshold

Service
Period:

Address
Zone:

(seconds)

High Major%

High Minor%

Low Minor%

Low Major%

Delay
(seconds)
Networked

Flow
Averaging
Period (sec)
Networked

Airflow

Raw Flow L/min

% Flow %

Maximum
Transport
Time
observed

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VESDA by Xtralis VESDA VLI Product Guide

A.2 Display/Relay Configuration

Table A-3: Display/Relay Configuration commissioning form

Button Lockout Enabled/Disabled

Smoke Test

Reset

Disable

AutoLearn Smoke

AutoLearn Flow

Relays Connected Yes/No

GPIConnected Yes/No

GPIFunction

A.3 Relay Configuration

Table A-4: Relay Configuration commissioning form

Relay 1 2 3 4 5 Start-up Latching

Fault

Fire

Configurable

Configurable

Configurable

D= Normally De-energized; E= Normally Energized

A.4 VESDAnet Interface Card

Table A-5: VESDAnet Interface Card commissioning form

VESDAnet Card Installed Yes/No

Card Serial Number

Preferred Port Port A/Port B

Loop Open Ended on this card Yes/No

A.5 ASPIRE2 Data

Table A-6: ASPIRE2 Data commissioning form

Group 1 Group 2 Group 3 Group 4

Aggregate Sensitivity

Balance

Suction Pressure (least)

Endcap Sensitivity Factor

Pipe Flow Rate (L/min)

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A.6 Smoke Test

Table A-7: Smoke Test commissioning form

Test Results

Test Method

Type of Smoke

Test Date

A.7 Air Sampling Test Results

Table A-8: Air Sampling Test results commissioning form

Pipe 1 Pipe 2 Pipe 3 Pipe 4

Transport Time from
End Cap Hole

Test 1 Initial Response

Action (Pre-Alarm)

Fire1 (Alarm)

Peak Smoke

Test 2 Initial Response

Action (Pre-Alarm)

Fire1 (Alarm)

Peak Smoke

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B Glossary

Table B-1: Glossary

Term Description

A Aspirator Impeller type fan used to draw sampled air into the detector.

AutoLearn Smoke A feature which allows the detector to learn its environment

(background pollution, differences between day and night
operations within the facility etc) in order to set appropriate
alarm thresholds for that environment.

AutoLearn Flow A feature which allows the detector to learn its environment

(airflow patterns, differences between day and night
operations within the facility etc) in order to set appropriate
airflow thresholds for that environment.

B BACnet The data communications protocol used on the USBand

Ethernet ports.

C Capillary Tubes Flexible tubes attached to the sampling pipe network for

sampling specific areas or objects away from the sampling
pipe.

Commissioning The process of making a smoke detection system

operational.

D Disable Disables the alarm relay outputs from actuating and

indicates a fault. This is previously referred to as Isolate.

E Event Log All VESDA detectors provide internal data logging of events

which have occurred in the protected zone.

F Fire This indicates a serious situation and may lead to automatic

generation of a fire alarm.

Fire Alarm ControlPanel (FACP) A panel which all fire detection products report their status

to.

G General Purpose Input (GPI)

Unmonitored

General Purpose Input (GPI) Monitored An input to a detector which is monitored for open or short

H High Airflow Environment Where there are 10 or more air exchanges per hour.

High Level Interface (HLI) A communications interface between a VESDA device and

O Obscuration The reduction in light transmission per meter or per foot due

An input to a detector which can be used to place the
detector in a certain condition. Applying a voltage between
5V and 30VDC triggers the selected condition.

circuits. It can be used to monitor the power supply.

other pieces of equipment using VESDAnet or another
communications protocol.

to the presence of particulates.

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Table B-1: Glossary (continued...)

Term Description

R Referencing Referencing is a technique used to reduce false alarms. It

requires VESDAnet.

A separate detector takes readings of the background level
of smoke and pollutants outside of the protected area. These
readings are then referenced to the readings from the
detectors in the protected area. This allows the internal
detectors to determine if a rise in smoke levels is due to
background pollution or a problem inside the protected area.

Relay A device on a detector which allows external equipment to

be hard wired to it and be triggered when various conditions
occur (example, sounding a siren at Alert threshold).

S Sampling Network The pipe network constructed to allow the VESDA detector

to draw air for sampling.

Sensitivity Degree of response (i.e. activation of alarm condition) of a

detector. A high sensitivity denotes response to a lower
concentration of smoke than a low sensitivity.

Z Zone A defined area within the protected premises from which an

alarm signal can be received.

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Index

A

access level

ADM 37

DST 37

USR 37

accessories 15

display module 15, 24

programmer 15, 24, 27, 30, 37, 44, 51, 65-66

remote display 65

action 8, 12, 15

aggregate sensitivity 69

alarm 8, 15

range 11

alert 8, 12, 15

area coverage 3

aspirator 5-6, 57, 64, 71

Clean Air Zero aspirator 7

AutoLearn 12, 48, 51, 69

AutoLearn Flow 52, 71

AutoLearn Smoke 51, 71

B

BACnet 3, 6, 10, 12, 34-35, 71

battery 27

button

disable 8

lockout 44, 69

reset 8

relay configuration 69

smoke test 70

VESDAnet interface card 69

clean air 6-7

Clean Air Zero 7

event 7

commands

cancel AutoLearn flow 38

cancel AutoLearn smoke 39

Clean Air Zero 39

disable 38

enable 38

fault test 39

flow test 39

lamp test 39

normalize air flow 38

relay test 39

reset 38

reset aspirator 39

reset intelligent filter 39

reset secondary foam filter 39, 56

return to factory defaults 39

smoke test 39

standby 38

start AutoLearn flow 38

start AutoLearn smoke 39

commissioning 51, 71

smoke test 52

connection 33

add 34

C

cable entry point 18

capillary tubes 71

chamber assembly 58, 64

checklist

air sampling results 70

commissioning 67

display/relay configuration 69

installation 29

modelling 69

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ethernet 35

VESDAnet 37

D

detector

remove front cover 54

replace aspirator 57

replace chamber assembly 58

replace intelligent filter 55

replace secondary foam filter 56

dimensions 11, 13

VESDA VLI Product Guide VESDA by Xtralis

disable 8, 71

display module 15, 24

E

EOL resistor 17, 24-25

ESD 20, 54, 58

Ethernet 10

event log 3, 12, 71

exhaust 6, 18, 31-32

expansion card 3, 14

F

FACP 24-25, 65, 71

fault 8, 12, 15, 24, 48

airflow 65

filter 65

network 65

power 65

H

HLI 71

I

intelligent filter 3-6, 29, 55, 64

IP54 3, 11

isolate 15, 44, 69

L

LED

alarm 8

fault 8

power 8

pre-alarm 8

M

maintenance

check pipe flow 53

system 65

urgent 65

zone 65

filter 48

intelligent filter 5-6, 29, 39, 55, 64

secondary foam 5-6, 29, 39, 56, 64

tertiary clean air 5-6

fire1 8, 12, 15, 48

fire2 8, 12, 48

front panel 8

G

GPI 3, 24, 27, 65, 69, 71

external reset 43

inverted reset 43

isolate 43

mains OK 43

monitored 24, 27, 71

power supply voltage 24, 43

check pipe network 53

clean sampling point 53

filter inspection 53

flush pipe network 53

pipe integrity smoke test 53

power supply 53

mounting

bracket 17

location 18

locking mechanism 18

orientation 18

screws 17

N

normalize airflow 30, 52

O

obscuration 71

P

reset + isolate 43

standby mode 43

unmonitored 24, 43, 71

use night-time threshold 43

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PIN code 37

pipe

diameter 31

endcap 31, 51, 69

VESDA by Xtralis VESDA VLI Product Guide

inlet pipes 31

inlet ports 31

installation 31

mounting 18

network 3, 6, 11, 31, 71

network design 31-32

network testing 52

size 11

pipe flow rate 69

port

Ethernet 10

RS485 10

USB 10

power 8

battery 27

consumption 11

GPI supply voltage 24

supply 20

specifications 11

alarm range 11

dimensions 11

weight 11

standby 53, 55-58

suction pressure 69

supply voltage 11

T

TCP/IP 10

temperature 11

threshold

action 8, 11-12, 15, 48, 51

alert 8, 11-12, 15, 48, 51

fire1 8, 11-12, 15, 24, 48, 51

fire2 8, 11-12, 48, 51

troubleshooting 65

U

voltage range 20

wiring 20

power source 20

power supply 20

monitoring 24

power up 28

pre-alarm 8

programmer 15, 24, 27, 30, 44, 51, 65-66

R

referencing 12, 49, 71

relays 11, 24-25, 65, 69, 71

fault 24, 69

fire 24, 69

remote display 65

reset 8, 15, 43, 69

RS485 10

USB 10, 34

interface lead 17

V

VESDAnet 14-15, 22, 24, 37, 44, 68, 71

polarity 22

W

weight 11

wiring 20

address loop module 25

FACP 25

power 20

VESDAnet 22

Z

zone 71

S

sensitivity 71

settings 48

default 48

silence 15

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