ISO 7240-12:2014

INTERNATIONAL ISO
STANDARD 7240-12
Second edition
2014-04-15
Fire detection and alarm systems —
Part 12:
Line type smoke detectors using a
transmitted optical beam
Systèmes de détection d’incendie et d’alarme —
Partie 12: Détecteurs linéaires de fumée utilisant une transmission
par faisceaux lumineux
Reference number
©
ISO 2014
© ISO 2014
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ii © ISO 2014 – All rights reserved

Contents Page
Foreword .v
Introduction .vii
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 2
4 Requirements . 3
4.1 Compliance . 3
4.2 Individual alarm indication . 3
4.3 Connection of ancillary devices . 4
4.4 Monitoring of detachable detectors and connections . 4
4.5 Manufacturer’s adjustments . 4
4.6 On-site adjustment of response threshold value . 4
4.7 Protection of optical components. 4
4.8 Limit of compensation . 5
4.9 Fault signalling . 5
4.10 Software-controlled detectors . 5
5 Test methods . 6
5.1 General . 6
5.2 Reproducibility . 9
5.3 Repeatability .10
5.4 Alignment dependence .10
5.5 Variation of supply parameters .11
5.6 Rapid changes in attenuation .12
5.7 Slow changes in attenuation .12
5.8 Optical path length dependence .13
5.9 Fire sensitivity .13
5.10 Stray light .15
5.11 Dry heat (operational) .16
5.12 Cold (operational) .17
5.13 Damp heat, steady-state (operational).19
5.14 Damp heat, steady-state (endurance) .20
5.15 Vibration, sinusoidal (endurance) .20
5.16 Electromagnetic compatibility (EMC), immunity tests (operational) .21
5.17 Sulfur dioxide, SO , corrosion (endurance) .22
5.18 Impact (operational) .23
6 Test report .24
7 Marking .24
8 Data .25
Annex A (informative) Compensation for detector drift .26
Annex B (normative) Bench for response threshold value measurements .31
Annex C (normative) Fire test room .33
Annex D (normative) Smouldering pyrolysis wood fire (TF2) .35
Annex E (normative) Glowing smouldering cotton fire (TF3) .38
Annex F (normative) Flaming plastics (polyurethane) fire (TF4) .40
Annex G (normative) Flaming liquid (n-heptane) fire (TF5) .42
Annex H (normative) Smoke-measuring instruments .43
Annex I (normative) Apparatus for stray light .46
Annex J (informative) Information concerning the construction of the measuring
ionization chamber .48
iv © ISO 2014 – All rights reserved

Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2. www.iso.org/directives
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of any
patent rights identified during the development of the document will be in the Introduction and/or on
the ISO list of patent declarations received. www.iso.org/patents
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation on the meaning of ISO specific terms and expressions related to conformity
assessment, as well as information about ISO’s adherence to the WTO principles in the Technical Barriers
to Trade (TBT), see the following URL: Foreword - Supplementary information
The committee responsible for this document is ISO/TC 21, Equipment for fire protection and fire fighting,
Subcommittee SC 3, Fire detection and fire alarm systems.
This second edition cancels and replaces the first edition (ISO 7240-12:2006), which has been technically
revised.
ISO 7240 consists of the following parts, under the general title Fire detection and alarm systems:
— Part 1: General and definitions
— Part 2: Control and indicating equipment
— Part 3: Audible alarm devices
— Part 4: Power supply equipment
— Part 5: Point-type heat detectors
— Part 6: Carbon monoxide fire detectors using electro-chemical cells
— Part 7: Point-type smoke detectors using scattered light, transmitted light or ionization
— Part 8: Carbon monoxide fire detectors using an electro-chemical cell in combination with a heat sensor
— Part 9: Test fires for fire detectors [Technical Specification]
— Part 10: Point-type flame detectors
— Part 11: Manual call points
— Part 12: Line type smoke detectors using a transmitted optical beam
— Part 13: Compatibility assessment of system components
— Part 14: Design, installation, commissioning and service of fire detection and fire alarm systems in and
around buildings
— Part 15: Point type fire detectors using scattered light, transmitted light or ionization sensors in
combination with a heat sensor
— Part 16: Sound system control and indicating equipment
— Part 17: Short-circuit isolators
— Part 18: Input/output devices
— Part 19: Design, installation, commissioning and service of sound systems for emergency purposes
— Part 20: Aspirating smoke detectors
— Part 21: Routing equipment
— Part 22: Smoke detection equipment for ducts
— Part 23: Visual alarm devices
— Part 24: Sound-system loudspeakers
— Part 25: Components using radio transmission paths
— Part 27: Point-type fire detectors using a scattered-light, transmitted-light or ionization smoke sensor,
an electrochemical-cell carbon-monoxide sensor and a heat sensor
— Part 28: Fire protection control equipment
A Part 29 dealing with video fire detectors is under preparation.
vi © ISO 2014 – All rights reserved

Introduction
This part of ISO 7240 has been prepared by ISO/TC 21/SC 3, the secretariat of which is held by SA and is
based on ISO 7240-12:2006.
A fire detection and alarm system is required to function satisfactorily not only in the event of fire, but
also during and after exposure to conditions likely to be met in practice, including corrosion, vibration,
direct impact, indirect shock and electromagnetic interference. Specific tests are intended to assess the
performance of the smoke detectors under such conditions.
This part of ISO 7240 is not intended to place any other restrictions on the design and construction of
such detectors.
INTERNATIONAL STANDARD ISO 7240-12:2014(E)
Fire detection and alarm systems —
Part 12:
Line type smoke detectors using a transmitted optical
beam
1 Scope
1.1 This part of ISO 7240 specifies requirements, test methods and performance criteria for line-type
smoke detectors for use in fire detection systems installed in buildings. The detectors consist of at least
a transmitter and a receiver and can include reflector(s), for the detection of smoke by the attenuation
and/or changes in attenuation of an optical beam.
1.2 This part of ISO 7240 does not cover
— line-type smoke detectors designed to operate with separations between opposed components of
less than 1 m;
— line-type smoke detectors whose optical path length is defined or adjusted by an integral mechanical
connection;
— line-type smoke detectors with special characteristics, which cannot be assessed by the test
methods in this part of ISO 7240.
NOTE The term “optical” is used to describe that part of the electromagnetic spectrum produced by the
transmitter to which the receiver is responsive; this is not restricted to visible wavelengths.
2 Normative references
The following documents, in whole or in part, are normatively referenced in this document and are
indispensable for its application. For dated references, only the edition cited applies. For undated
references, the latest edition of the referenced document (including any amendments) applies.
ISO 209, Aluminium and aluminium alloys — Chemical composition
ISO 7240-1, Fire detection and alarm systems — Part 1: General and definitions
IEC 60064, Tungsten filament lamps for domestic and similar general lighting purposes — Performance
requirements
IEC 60068-1, Environmental testing — Part 1: General and guidance
IEC 60068-2-1, Environmental testing — Part 2-1: Tests. Tests A: Cold
IEC 60068-2-2, Environmental testing — Part 2-2: Tests. Tests B: Dry heat
IEC 60068-2-6, Environmental testing — Part 2-6: Tests. Test Fc: Vibration (sinusoidal)
IEC 60068-2-27, Environmental testing — Part 2-27: Tests. Test Ea and guidance: Shock
IEC 60068-2-42, Environmental testing — Part 2-42: Tests. Test Kc: Sulphur dioxide test for contacts and
connections
IEC 60068-2-78, Environmental testing — Part 2-78: Tests. Test Cab: Damp heat, steady state
IEC 60081, Double-capped fluorescent lamps — Performance specifications
EN 50130-4:2011, Alarm systems — Part 4: Electromagnetic compatibility — Product family standard:
Immunity requirements for components of fire, intruder and social alarm systems
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 7240-1 and the following apply.
3.1
attenuation
A
reduction in intensity of the optical beam at the receiver, defined by the equation
I
 
A =10log
10 
I
 
where
I is the received intensity without reduction in intensity;
I is the received intensity after reduction in intensity
Note 1 to entry: The attenuation is expressed in units of decibels (dB).
3.2
opposed component
component [transmitter and receiver or transmitter-receiver and reflector(s)] of the detector whose
position determines the optical path
3.3
optical path length
total distance traversed by the optical beam between the transmitter and the receiver
3.4
receiver
component that receives the optical beam
3.5
response threshold value
C
value of attenuation at the moment an alarm signal is generated
 
n
f
CF=×
 
n
v
 
where
2 © ISO 2014 – All rights reserved

F is the value of attenuation resulting from a beam passing once through a filter, and given by
I
 
the formula 10log ;
10 
I
 
I is the received intensity of the optical beam without reduction through an attenuating
filter;
I is the received intensity of the optical beam after passing once through an attenuating
filter;
n is the number of times the beam passes through the filter;
f
n is the number of times the beam passes through the measured volume
v
Note 1 to entry: The attenuation is expressed in units of decibels (dB).
 n 
f
Note 2 to entry: The inclusion of means that the value of C recorded for a multi–pass arrangement tested
 
n
 v 
by obscuring the beam only once (at the receiver, as recommended in B.1.2) is consistent with a single pass (end-
to-end) arrangement.
3.6
sensitivity adjustment
any adjustment during or after commissioning which leads to a change in the response to fire
3.7
separation
physical distance between the opposed components
3.8
transmitter
component from which the optical beam emanates
4 Requirements
4.1 Compliance
In order to comply with this part of ISO 7240, the detector shall meet the following requirements.
a) Clause 4, which shall be verified by visual inspection or engineering assessment, shall be tested in
accordance with Clause 5 and shall meet the requirements of the tests.
b) Clauses 7 and 8, which shall be verified by visual inspection.
4.2 Individual alarm indication
4.2.1 Each detector shall be provided with an integral red visual indicator by which the individual
detector releasing an alarm can be identified, until the alarm condition is reset. Where other conditions
of the detector can be visually indicated, these shall be clearly distinguishable from the alarm indication,
except when the detector is switched into a service mode. For detachable detectors, the indicator may be
integral with the base or the detector head.
4.2.2 The visual indicator shall be visible from a distance of 6 m in an ambient light intensity up to
500 lx at an angle up to
a) 5° from the vertical axis of the detector when viewed from beneath the detector in any direction
and
b) 45° from the vertical axis of the detector when viewed from beneath the detector in at least one
direction.
4.3 Connection of ancillary devices
The detector may provide for connections to ancillary devices (remote indicators, control relays, etc.),
but open- or short-circuit failures of these connections shall not prevent the correct operation of the
detector.
4.4 Monitoring of detachable detectors and connections
4.4.1 For detachable detectors, a means shall be provided for a remote monitoring system (e.g. the
control and indicating equipment) to detect the removal of the head from the base, in order to give a fault
signal.
4.4.2 If there are cables connecting separate parts of the detector, then a means shall be provided for a
remote monitoring system (e.g. the fire detection control and indicating equipment) to detect a short or
open circuit on those cables, in order to give a fault signal.
4.4.3 If more than one detector can be connected to the transmission path of a remote monitoring
system (e.g. control and indicating equipment), the removal of a head from the base shall not prevent an
alarm signal from another detector connected to the same transmission path.
4.5 Manufacturer’s adjustments
It shall not be possible to change the manufacturer’s settings except by special means (e.g. the use of a
special code or tool) or by breaking or removing a seal.
4.6 On-site adjustment of response threshold value
4.6.1 If there is provision for on-site adjustment of the response threshold value of the detector then
a) for all of the settings at which the manufacturer claims compliance, the detector shall comply with
the requirements of this part of ISO 7240 and access to the adjustment means shall be possible only
by the use of a code or special tool or by removing the detector from its base or mounting;
b) any setting or settings at which the manufacturer does not claim compliance with this part of
ISO 7240 shall be accessible only by the use of a code or special tool, and it shall be clearly marked
on the detector or in the associated data that if these setting or settings are used, the detector does
not comply with this part of ISO 7240.
4.6.2 These adjustments may be carried out at the detector or at the fire detection control and indicating
equipment.
4.7 Protection of optical components
The detector shall be so designed that a sphere of diameter greater than (1,3 ± 0,05) mm cannot pass
into any enclosure containing optical components when the detector is in the operational condition.
NOTE This requirement is intended to restrict the access of insects into the sensitive parts of the detector. It
is known that this requirement is not sufficient to prevent the access of all insects, therefore, it may be necessary
to take other precautions against unwanted alarms due to the entry of small insects.
4 © ISO 2014 – All rights reserved

4.8 Limit of compensation
4.8.1 Compensation may be used to mitigate changes in sensitivity due to the build-up of dust and
other contaminants on the optical surfaces (see Annex A).
4.8.2 The detector shall emit either a fault or alarm signal at the limit of compensation for the effect of
a slowly changing signal response.
4.8.3 Since it is practically impossible to perform tests with very slight increases in attenuation, an
evaluation of the detectors conformity shall be made by analysing the circuits/software and/or by
physical tests and simulations.
4.9 Fault signalling
A fire alarm signal shall not be cancelled by a fault resulting from a rapid change in obscuration (in
accordance with 5.6) or by a result of the limit of compensation being reached (in accordance with 4.8).
4.10 Software-controlled detectors
4.10.1 General
The requirements of 4.10.2, 4.10.3 and 4.10.4 shall be met for detectors that rely on software control in
order to fulfil the requirements of this part of ISO 7240.
4.10.2 Software documentation
4.10.2.1 The manufacturer shall prepare documentation that gives an overview of the software design.
This documentation shall be in sufficient detail for the design to be inspected for compliance with this
part of ISO 7240 and shall include at least the following.
a) Functional description of the main program flow (e.g. as a flow diagram or structogram), including:
1) a brief description of the modules and the functions that they perform,
2) the way in which the modules interact,
3) the overall hierarchy of the program,
4) the way in which the software interacts with the hardware of the detector,
5) the way in which the modules are called, including any interrupt processing.
b) Description of those areas of memory used for the various purposes (e.g. the program, site-specific
data and running data).
c) Designation by which the software and its version can be uniquely identified.
4.10.2.2 The manufacturer shall prepare and maintain detailed design documentation. This shall be
available for inspection in a manner that respects the manufacturers’ rights for confidentiality. . It shall
comprise at least the following.
a) An overview of the whole system configuration, including all software and hardware components;
b) A description of each module of the program, containing at least:
1) the name of the module,
2) a description of the tasks performed,
3) a description of the interfaces, including the type of data transfer, the valid data range and the
checking for valid data.
c) Full source code listings, as hard copy or in machine-readable form (e.g. ASCII-code), including all
global and local variables, constants and labels used, and sufficient comment for the program flow
to be recognized.
d) Details of any software tools used in the design and implementation phase (CASE-Tools, compilers,
etc.).
NOTE This detailed design documentation may be reviewed at the manufacturers’ premises
4.10.3 Software design
In order to ensure the reliability of the detector, the following requirements for software design apply.
a) The software shall have a modular structure.
b) The design of the interfaces for manually and automatically generated data shall not permit invalid
data to cause error in the program operation.
c) The software shall be designed to avoid the occurrence of deadlock of the program flow.
4.10.4 Storage of programs and data
4.10.4.1 The program necessary to comply with this part of ISO 7240 and any preset data, such as
manufacturer’s settings, shall be held in non-volatile memory. Writing to areas of memory containing this
program and data shall be possible only by the use of some special tool or code and shall not be possible
during normal operation of the detector.
4.10.4.2 Site-specific data shall be held in memory which will retain data for at least two weeks without
external power to the detector, unless provision is made for the automatic renewal of such data, following
loss of power, within 1 h of power being restored.
5 Test methods
5.1 General
5.1.1 Atmospheric conditions for tests
5.1.1.1 Unless otherwise stated in a test procedure, carry out the testing after the test specimen has
been allowed to stabilize in the standard atmospheric conditions for testing as specified in IEC 60068-
1 as follows:
— temperature: (15 to 35) °C;
— relative humidity: (25 to 75) %;
— air pressure: (86 to 106) kPa.
5.1.1.2 The temperature and humidity shall be substantially constant for each environmental test
where the standard atmospheric conditions are applied.
6 © ISO 2014 – All rights reserved

5.1.2 Mounting arrangements
Mount the specimen by its normal means of attachment in accordance with the manufacturer’s
instructions. If these instructions describe more than one method of mounting, then the method
considered to be most unfavourable for each test shall be chosen.
5.1.3 Operating conditions for tests
5.1.3.1 If a test method requires a specimen to be operational, then connect the specimen to suitable
supply and monitoring equipment having the characteristics required by the manufacturer’s data. Unless
otherwise specified in the test method, set the supply parameters applied to the specimen within the
manufacturer’s specified range(s) and maintain them substantially constant throughout the tests. The
value chosen for each parameter shall normally be the nominal value, or the mean of the specified range.
If a test procedure requires a specimen to be monitored to detect any alarm or fault signals, then connect
the specimen to any necessary ancillary devices (e.g. through wiring to an end-of-line device for non-
addressable detectors) to allow a fault signal to be recognized.
5.1.3.2 The details of the supply and monitoring equipment and the alarm criteria used shall be given
in the test report (Clause 6).
5.1.4 Tolerances
5.1.4.1 Unless otherwise stated, the tolerances for the environmental test parameters shall be as given
in the basic reference standards for the test (e.g. the relevant part of IEC 60068).
5.1.4.2 If a specific tolerance or deviation limit is not specified in a requirement or test procedure, then
a tolerance of ± 5 % shall be applied.
5.1.5 Measurement of response threshold value
5.1.5.1 General
5.1.5.1.1 Install the specimen, for which the response threshold value is to be measured, on the
measuring bench, conforming to Annex B, in its normal operating position, by its normal means of
attachment in accordance with 5.1.2.
5.1.5.1.2 Connect the specimen to its supply and monitoring equipment in accordance with 5.1.3, and
allow it to stabilize for at least 15 min.
5.1.5.2 Operating conditions
5.1.5.2.1 Assemble the receiver on a rigid support at a longitudinal distance of at least 500 mm from the
transmitter or the transmitter-receiver at the same distance from the reflector (see Figure B.1).
5.1.5.2.2 In the case of opposed components with a separate transmitter and receiver, place a filter
holder as close as possible to the front of the receiver.
5.1.5.2.3 Adjust the filter holder so that the whole beam passes through the filter. Use the filter holder
to mount the filters used during the measurement of response threshold value.
5.1.5.2.4 The height, h, separating the axis of the optical beam above the support shall be 10 times the
diameter (or the vertical dimension) of the optical system of the receiver.
5.1.5.2.5 Carry out adjustment for path length or alignment, if required, in accordance with the
manufacturer’s instructions.
5.1.5.2.6 Unless otherwise stated in a test procedure, measure the response threshold value with
the maximum separation or a simulated maximum separation carried out using means agreed by the
manufacturer.
5.1.5.3 Measurements
5.1.5.3.1 The response threshold value is determined by the value of the lowest value test filter required
to give an alarm within 30 s after introduction in the beam. The minimum resolution for optical density
filters shall be in accordance with Table B.1 (see Annex B).
5.1.5.3.2 Record the response threshold value as C.
5.1.6 Provision for tests
5.1.6.1 Provide the following for testing compliance with this part of ISO 7240:
a) seven detectors;
b) data specified in Clause 8.
5.1.6.2 The specimens submitted shall be representative of the manufacturer’s normal production with
regard to their construction and calibration. This implies that the mean response threshold value of the
seven specimens found in the reproducibility test should also represent the production mean, and that
the limits specified in the reproducibility test should also be applicable to the manufacturer’s production.
5.1.7 Test schedule
Test the specimens in accordance with the test schedule in Table 1. After the reproducibility test,
number the two least sensitive specimens (i.e. those with the highest response thresholds) 6 and 7 and
the others 1 to 5 arbitrarily.
8 © ISO 2014 – All rights reserved

Table 1 — Test schedule
Test Subclause Specimen No.(s)
Reproducibility 5.2 all specimens
Repeatability 5.3 2
Alignment dependence 5.4 1
Variation of supply parameters 5.5 1
Rapid changes in attenuation 5.6 1
Slow changes in attenuation 5.7 1
Optical path length dependence 5.8 1
Fire sensitivity 5.9 6 and 7
Stray light 5.10 6
Dry heat (operational) 5.11 3
Cold (operational) 5.12 3
Damp heat, steady-state (operational) 5.13 2
Damp heat, steady-state (endurance) 5.14 2
Vibration (endurance) 5.15 7
a
Electrostatic discharge (operational) 5.16 4
a
Radiated electromagnetic fields (operational) 5.16 6
a
Conducted disturbances induced by electromagnetic fields (opera- 5.16 6
tional)
a
Fast transient bursts (operational) 5.16 4
a
Slow high-energy voltage surges (operational) 5.16 6
Sulfur dioxide SO corrosion (endurance) 5.17 5
Impact (operational) 5.18 1
a
In the interests of test economy, it is permitted to use the same specimen for more than one EMC test. In that case,
intermediate functional test(s) on the specimen(s) used for more than one test may be deleted, and the functional test
conducted at the end of the sequence of tests. However it should be noted that in the event of a failure, it may not be possible
to identify which test exposure caused the failure (see Clause 4 of EN 50130–4:2011).
5.1.8 Test report
The test results shall be reported in accordance with Clause 6.
5.2 Reproducibility
5.2.1 Object of test
To demonstrate that the sensitivity of the detector does not vary unduly from specimen to specimen.
5.2.2 Test procedure
5.2.2.1 Adjust the specimens to the maximum sensitivity.
5.2.2.2 Measure the response threshold value of each of the specimens in accordance with 5.1.5.
5.2.2.3 Calculate the mean of these response threshold values which shall be designated C .
5.2.2.4 Designate the maximum response threshold value as C and the minimum value as C .
max min
5.2.3 Requirements
5.2.3.1 C shall not be less than 0,4 dB.
min
5.2.3.2 The ratio of the response threshold values C : C shall not be greater than 1,33 and the ratio
max
of the response threshold values C : C shall not be greater than 1,5.
min
5.3 Repeatability
5.3.1 Object of test
To demonstrate that the detector has stable behaviour with respect to its sensitivity even after a number
of alarm conditions.
5.3.2 Test procedure
5.3.2.1 Adjust the specimen to the maximum sensitivity.
5.3.2.2 Mount the specimen in accordance with 5.1.2 and connect it to supply and monitoring equipment
in accordance with 5.1.3.
5.3.2.3 Measure the response threshold value of the specimen to be tested three times in accordance
with 5.1.5. The period between successive determinations shall not be less than 15 min or more than 1 h.
5.3.2.4 Power the specimen without interruption or disturbance to the optical beam, for 7 d.
5.3.2.5 Measure the response threshold value of the specimen once, in accordance with 5.1.5.
5.3.2.6 Designate the maximum response threshold value C and the minimum value C .
max min
5.3.3 Requirements
5.3.3.1 No alarm or fault signals shall be emitted during the 7 d between testing.
5.3.3.2 C shall not be less than 0,4 dB.
min
5.3.3.3 The ratio of the response threshold values C : C shall not be greater than 1,6.
max min
5.4 Alignment dependence
5.4.1 Object of test
To demonstrate that the angular inaccuracies in alignment (within the maximum stated by the
manufacturer) of the detector resulting from installation and/or movement in the structure of a building,
do not affect the operation of the detector.
5.4.2 Test procedure
5.4.2.1 With the agreement of the manufacturer, this test may be carried out outside of the limits of the
standard atmospheric conditions of 5.1.1.
5.4.2.2 Adjust the specimen to the maximum sensitivity
10 © ISO 2014 – All rights reserved

5.4.2.3 Mount the specimen in accordance with 5.1.2 and connect it to supply and monitoring equipment
in accordance with 5.1.3.
5.4.2.4 Subject each opposed component to the following procedures while holding the other component
stationary.
a) Rotate the component in a clockwise direction about a vertical axis at a rate of (0,3 ± 0,05)°/min
up to the maximum angular misalignment declared by the manufacturer in accordance with 8.2 a).
After 2 min in this position, place a filter of value 6 dB in the optical path.
b) Remove the filter, reset the detector and continue the rotation until a fault or alarm signal is emitted.
c) Return the rotated component to its original position, reset the detector and allow it to stabilize.
d) Repeat the procedure described in a), b) and c) but rotate the component in a counter-clockwise
direction.
e) Repeat the procedures described in a), b), c) and d) but rotate the component about a horizontal axis
normal to the beam.
5.4.3 Requirements
5.4.3.1 The specimen shall not emit a fault or an alarm signal while being rotated in the directions
specified within the angular tolerances stated by the manufacturer [see 8.2 a)].
5.4.3.2 The specimen shall emit an alarm signal no more than 30 s after the total introduction of the
filter specified in 5.4.2.2.
5.4.3.3 Record the smallest angle at which a fault or alarm signal is emitted when the component is
rotated beyond the maximum angle declared by the manufacturer in accordance with 8.2 a).
5.5 Variation of supply parameters
5.5.1 Object
To demonstrate that, within the specified range(s) of the supply parameters (e.g. voltage), the sensitivity
of the detector is not unduly dependent on those parameters.
5.5.2 Test procedure
5.5.2.1 Adjust the specimen to the maximum sensitivity.
5.5.2.2 Mount the specimen in accordance with 5.1.2 and connect it to supply and monitoring equipment
in accordance with 5.1.3.
5.5.2.3 Measure the response threshold value of the specimen in accordance with 5.1.5 at the upper
and lower limits of the supply parameter (e.g. voltage) range(s) specified by the manufacturer.
5.5.2.4 Designate the maximum response threshold value as C and the minimum value as C .
max min
5.5.2.5 For some detectors, the only relevant supply parameter may be the DC voltage applied to the
detector. For other types of detectors (e.g. analogue-addressable), signal levels and timing might need to
be considered. If necessary, the manufacturer may be requested to provide suitable supply equipment to
allow the supply parameters to be changed as required.
5.5.3 Requirements
5.5.3.1 C shall not be less than 0,4 dB.
min
5.5.3.2 The ratio of the response threshold values C : C shall not be greater than 1,6.
max min
5.6 Rapid changes in attenuation
5.6.1 Object of test
To demonstrate that the detector produces alarm or fault signals, within an acceptable time, after a
sudden, large and sustained increase in beam attenuation.
5.6.2 Test procedure
5.6.2.1 Adjust the specimen to the minimum sensitivity
5.6.2.2 Mount the specimen in accordance with 5.1.2 and connect it to supply and monitoring equipment
in accordance with 5.1.3.
5.6.2.3 Use the following attenuators:
a) attenuator A: 6 dB,
+3
b) attenuator B: 10 dB
5.6.2.4 Place the attenuator A in the optical path. The time to place attenuator A in the optical path shall
not exceed 1 s. Keep the attenuator A in place for 40 s.
5.6.2.5 Remove attenuator A, reset the detector and place the attenuator B in the optical path. The time
to place attenuator B in the optical path shall not exceed 1 s. Keep the attenuator B in place for 70 s.
5.6.3 Requirements
5.6.3.1 The specimen shall emit an alarm signal not more than 30 s after the total introduction of the
attenuator A between the components.
5.6.3.2 The specimen shall emit a fault or alarm signal not more than 60 s after the total introduction of
the attenuator B between the components.
5.7 Slow changes in attenuation
5.7.1 Object of test
To demonstrate that the detector can detect a slowly developing fire, despite the provision of any
compensation for the effects of contamination of the optical components.
5.7.2 Test procedure
5.7.2.1 Adjust the specimen to the maximum sensitivity.
5.7.2.2 Mount the specimen in accordance with 5.1.2 and connect it to supply and monitoring equipment
in accordance with 5.1.3.
12 © ISO 2014 – All rights reserved

5.7.2.3 Measure the response threshold value of the specimen in accordance with 5.1.5 but change the
attenuator either continuously or in steps in accordance with the minimum attenuator resolution in
Table B.1 (see Annex B), with an average rate of C /4 dB/h where C is the average response threshold
values measured in the reproducibility test.
5.7.2.4 Designate the greater of the response threshold values measured in this test and that measured
for the same specimen in the reproducibility test as C and the lesser as C .
max min
5.7.3 Requirements
5.7.3.1 C shall not be less than 0,4 dB.
min
5.7.3.2 The ratio of the response threshold values C : C shall not be greater than 1,6.
max min
5.8 Optical path length dependence
5.8.1 Object of test
To demonstrate that the response threshold of the detector does not change significantly when it is
tested over the minimum and maximum optical path length stated by the manufacturer.
5.8.2 Test procedure
5.8.2.1 With the agreement of the manufacturer, this test may be carried out outside of the limits of the
standard atmospheric conditions of 5.1.1.
5.8.2.2 Adjust the specimen to the maximum sensitivity.
5.8.2.3 Mount the specimen in accordance with 5.1.2 and connect it to supply and monitoring equipment
in accordance with 5.1.3.
5.8.2.4 Measure the response threshold value in accordance with 5.1.5 at the minimum and maximum
separations in accordance with the manufacturer’s instructions.
5.8.2.5 Designate the greater of the response threshold values measured in this test and that measured
for the same specimen in the reproducibility test as C and the lesser as C .
max min
5.8.3 Requirements
5.8.3.1 C shall not be less than 0,4 dB.
min
5.8.3.2 The ratio of the response threshold values C : C shall not be greater than 1,6.
max min
5.9 Fire sensitivity
5.9.1 Object of test
To demonstrate that the detector has adequate sensitivity to a broad spectrum of smoke types as
required for general application in fire detection systems for buildings.
5.9.2 Test procedure
5.9.2.1 Principle of test
The specimens are mounted in a standard fire test room (see Annex C) and exposed to a series of test
fires designed to produce smoke representative of a wide spectrum of types of smoke and smoke flow
conditions.
5.9.2.2 Test fires
5.9.2.2.1 Subject the specimens to the four test fires TF2 to TF5. The type, quantity and arrangement of
the fuel and the method of ignition are specified in Ann
...