Evaluation Guideline
Contents
1. Nr Subject FEC HUB AMS 1 Introduction X i 1 1 General X X 1 2 Scope X A 13 Definitions and abbreviations X j 1 4 Requirements and determination methods X ig bf 1 4 1 Requirements X ig 14 2 Determination methods X ji 1 5 Acceptance of research reports provided by the X supplier 1 6 Declaration of quality K 8 1 7 Transition provision X 7 7 2 Performance requirements and determination K methods 2 1 General X j i 2 2 Requirements X j 2 2 1 Performance requirement extinguishing X j performance aerosol 2 2 1 1 Extinguishing object EN 2 class A solid X F a 2 2 1 2 Extinguishing object EN 2 class A solid plastics K is 2 2 1 3 Extinguishing object EN2 class A solid multi K ii Si layer wood with without plastics 2 2 1 4 Extinguishing object EN2 class B liquid K 2 2 1 5 Extinguishing object EN2 class C gas K j i 2 2 1 6 Extinguishing object EN 2 class F fats and oils X 2 2 2 Performance requirement solidity and ignition K E a SFE 2 2 3 Performance requirement solidity and self K i combustion SFE 2 2 4 Performance requirement full ignition outflow X A n SFE electric of the fire extinguishing component 2 2 5 Performance requirement suspension system fire X extinguishing component 2 2 6 Thermal aging of the SFE and electrical igniter K a 3 Product requirements and determination X 7 5 methods 3 1 General K z 3 2 Structure and accessories of the extinguishing X i component2. 0 9 MALFUNCTION Low 0 9 0 9 Table 5 Modem priorities Optional requirement When applying the FEC as a standalone component it is required that the communication equipment meets the requirements as stated in prEN 54 13 2001 EN 54 18 2003 and EN 54 21 2004 This communication equipment is usually provided by the alarm receiving station 2 5 3 Housing The housing of the AMS must meet the following performance requirements B The requirements in appendix 14 apply B The housing must have at least IP class 30 complying with IEC 60529 2001 B It must be possible to attach the AMS appropriately to walls and ceilings of the protected room The housing and fixing materials must be able to carry 5 x their own weight with a minimum of 5 kg Evaluation Guideline BRL K21014 04 Kiwa N V 26 June15 2009 3 Product requirements 3 1 General These chapters describe the requirements that the products must meet For components only certified normalized or specified materials may be applied 3 1 1 Certified products The following components must be applied as certified sub product during assembly of the end product Directive Subject Evaluation Guideline K23001 03 for product Aerosol extinguishing components and quality or UL 2775 2008 or CEN TR 15276 1 for product Table 6 Certified products If the supplier manufacturer submits reports by test institutions or labor
3. 22 Appendix 15 Test fires for detection and extinguishing General For finding a reference for practical requirements in relation to the detection of fire the detection components of the fire extinguishing components are tested comparable to NEN2535 1996 for the following fire sizes TF 9 reference gas 30 ppm TF 10 print with five resistors TF 4 polyurethane mats TF 7 methylated spirit TF 1 beech wood crib DNWDDDW The tests are carried out minimally in a test cabinet as shown in figure 15 on the next page The test cabinet has a transparent window in the middle of the door so the test carried out inside the test cabinet can be observed visually The cabinet itself contains normal electrical components like cable conduits and relays with sufficient room between the cabinet door and the electrical components to enable heat propulsion The test cabinet is provided with a ventilator with the following specifications air speed with filter 15 m3 h 50 Hz and 18 m3 h 60 Hz temperature range 10 C 55 C This ventilator Rittal 3321 107 is placed at the bottom of the test cabinet and will blow air into the test cabinet At the upper side of the test cabinet an air grid is placed Rittal 3321 800 with the same diameter as the ventilator for outflow of air and other gases The result of the tests determines the standard projection for fire detection and fire extinguishing Appendix 16 shows an example of a standard
4. BRL K21014 04 June15 2009 A test sequence has been made to reduce the amount of samples and 5 samples 3 samples 1 sample 3 samples Cold Ingress protection TEC 60068 2 1 IEC 60529 Sulphur dioxide Damp heat 16 hours 1 day TEC 60068 2 42 steady state 21 days TEC 60068 2 78 21 days Dry heat IEC 60068 2 2 16 hours Damp heat cyclic TEC 60068 2 90 24 hours 1 sample 1 sample 3 samples Free fall test Hammer test Vibration sinusoidal TEC 60068 2 32 TEC 60068 2 75 TEC 60068 2 6 24 hours 24 hours 24 hours Shock TEC 60068 2 27 24 hours to reduce the total test time The following test sequence has been made Figure 11 Test plan environmental tests FEC The total number of samples will be 12 The total lead time is 23 days For each test a detailed description has been made and presented in the following paragraphs The test setup is shown in the figure below jan D T ep lt Situation A only the FEC is tested Situation B the entire communication is tested Figure12 Test setup environmental tests Evaluation Guideline BRL K21014 04 Kiwa N V 72 June15 2009 Test Test situation Test A Cold Test B Dry heat Test Fc Vibration sinusoidal endurance Test Ea Shock Test Db Damp heat cyclic Test Ed Free fall Test Kc Sulphur dioxide test for contacts and connections Test Eh Hammer tests Test C
5. 7 16 6 Explosive atmosphere actuation test K F 7 16 7 Requirements X z bih 7 17 Heat exposure test X ii ii 7 17 1 Object of the test K is ii 7 17 2 Test procedure K i 7 17 3 Requirements K 7 18 Explosive atmosphere test X 4 7 18 1 Object of the test X 7 ig 7 18 2 Test procedure K 7 18 3 Requirements K ig ig Annex A normative Extinguishing factor coverage test K F procedure e Not within scope this has been settled elsewhere in the directive Evaluation Guideline Kiwa N V 57 BRL K21014 04 June15 2009 11 Appendix 4 Cross reference EN 54 2 Nr Subject FEC HUB AMS FEC Standalone 1 Scope s a 2 Normative references K i K K 3 Definitions and abbreviations K X X 4 General requirements X X X 5 General requirements for indications X i X X 5 1 Display of functional conditions X X X 5 2 Display of indications X X X 5 3 Indications on alphanumeric displays ii X 5 4 Indications on the supply of power K K K 5 5 Audible indications K X X 5 6 Additional indications X K K 6 The guiescent condition K X X 7 The fire alarm condition X i K K 7 1 Reception and processing of fire signals K K K 7 2 Indication of the fire alarm condition K K K 7 3 Indication of the zones in alarm K i X X 7 4 Audib
6. 4 5 Requirements for software controlled devices K K K 5 Tests K ig X X 5 1 General X K K 5 2 Performance and variation in supply parameters X K K 5 3 Dry heat K K K 5 4 Cold X X X 5 5 Damp heat cyclic X X X 5 6 Damp heat steady state X K K 5 7 Sulphur dioxide corrosion K ii K K 5 8 Shock K X X 5 9 Impact X K K 5 10 Vibration sinusoidal operational K K K 5 11 Vibration sinusoidal endurance K K K 5 12 Electromagnetic Compatibility EMC Immunity X X X tests Not within scope this has been settled elsewhere in the directive Evaluation Guideline BRL K21014 04 Kiwa N V 68 June15 2009 19 Appendix 12 Cross reference EN 54 21 Nr Subject FEC HUB AMS FEC Standalone 1 Scope i x X 2 Normative references i X i 3 Terms and definitions is K 4 General requirements s ii K 7 4 1 General X J 4 2 Compliance 3 i X 5 Functional requirements i ig K al 6 Alarm transmission and fault warning x X systems requirements 7 Design requirements 3 X 7 1 General requirements and manufacturers K ii declarations 7 2 Documentation i ii K 7 7 3 Mechanical design reguirements ih K Z 7 4 Electrical and other design requirements x 3 X 7 5 Integrity of transmission paths id K 7 6 Accessibility of indications and controls z X 7 7 I
7. been recorded 1 4 1 Requirements Functional requirements essential requirements made upon the product so that the product can be used safely by the user and is functional for its intended purpose Performance requirements in measurements or figures detailed requirements that are specified to certain functional properties of the part of the building component fire extinguishing component and that contain an obtainable limit value which can be calculated or measured unambiguously Product requirements in measurements or figures detailed requirements that are specified to certain identifiable properties of products applied in the building component fire extinguishing component and that contain an obtainable limit value which can be calculated or measured unambiguously Process requirements concrete requirements which the process must meet if necessary including the relevant conditions and boundary conditions under which the process must take place 1 4 2 Determination methods Pre certifications tests the test to determine whether all requirements from the Evaluation Guideline have been met Inspection tests the test performed after granting of the certificate to determine whether the certified processes and actions taken continuously meet the requirements from the Evaluation Guideline In the test matrix chapter 5 is summarized which tests will be performed by Kiwa during pre certification and during inspection and with w
8. 15 Explanation The CO determination alone is not used for extinguishing 2 3 5 Radio connection for the FEC The radio connections and system requirements must meet the relevant directives as per the applying CE marking guidelines and EN 54 25 Deviations and supplementary requirements are B The fire extinguishing component must communicate on a licence free frequency band ISM frequency for which wireless communication for alarm purposes is permitted B Atleast every 5 minutes status reports containing a o power supply conditions CO value temperature operational status of the fire extinguishing component must be exchanged between FEC HUB AMS HUB and the AMS B Each FEC must be provided with a radio connection B The FEC must be provided with an antenna accomplishing a radio connection Explanation 1 Even when the FEC is connected to another FEC through a serial bus connection all FEC s must be provided with an antenna Explanation 2 If the FEC is used as a standalone component it is possible that the radio connection as mentioned in chapter 2 3 5 is not used Evaluation Guideline BRL K21014 04 Kiwa N V 21 June15 2009 2 3 6 Housing for the FEC The housing of the fire extinguishing component must meet the following performance requirements B The housing must remain intact during an extinguishing to enable a complete outflow of the aerosol The requirements in appendix 14 apply B B Th
9. 3 10 Dry heat endurance X 8 3 11 Cold X X X 8 3 12 Damp heat cyclic X X X 8 3 13 Damp heat steady state operational X X X 8 3 14 Damp heat steady state endurance X X X 8 3 15 SO gt corrosion endurance X X X 8 3 16 Shock X X X 8 3 17 Impact X X X 8 3 18 Vibration sinusoidal operational X X X 8 3 19 Vibration sinusoidal endurance X X X 8 3 20 Electromagnetic Compatibility EMC Immunity tests X X X Appendix A Method for verification of the compatibility X X X Appendix B Test configuration by using radio frequency shielded X X X test equipment Evaluation Guideline Kiwa N V 65 BRL K21014 04 June15 2009 Nr Subject FEC HUB AMS Appendix Clauses addressing the provisions of the EU K K K ZA Construction Products Directive 89 106 ECC Not within scope this has been settled elsewhere in the directive Explanation If the FEC is used as a standalone component it is possible that the radio connection as mentioned in chapter 2 3 5 is not used Evaluation Guideline Kiwa N V 66 BRL K21014 04 June15 2009 17 Appendix 10 Cross reference EN 54 13 Nr Subject FEC HUB AMS FEC Standalone 1 Scope X X X 2 Normative references K i K K 3 Terms definitions and abbreviations K i X X 3 1 Definitions X i X X 3 2 Abbreviations X 3 X X 4 Requirements X g X
10. 3 3 Product requirements and determination methods X J 3 3 1 Installation and user manual X i 3 3 2 Packaging preservation storage identification K j 2 3 4 Certification mark X 7 id 4 Quality system requirements K ii 4 1 General K 7 4 2 Custodian of the quality system K 7 4 2 1 Requirements to other verification personnel K is 43 Internal guality control guality plan K 5 4 4 Procedures and working instructions K f 5 4 5 Other requirements to the quality system K ji 4 6 Storage and treatment X id ji 4 7 Entrance control SFE X i i 4 8 Process control production charge K 5 4 8 1 Activation and ejection mechanism X 4 8 2 Chemical stability extinguishing agent X x 5 Summary of test and inspections K i J 5 1 Test matrix K j 7 5 1 1 Changes in design X i a 5 2 Inspections of the quality system K is 2 Evaluation Guideline Kiwa N V 52 BRL K21014 04 June15 2009 Nr Subject FEC HUB AMS 6 Requirements to certification institutions K t i 6 1 General X i id 6 2 Certification personnel K il 6 2 1 Qualification requirements K 7 fi 6 3 Frequency of external inspections audits K is 7 List of documents stated K i 7 1 Public law regulations X 4 a 7 2 Directives normative documents X F Appendix 1 Testimonial with product certificate K ig i Appendix 2 IQC scheme K d Not within scope this has been settled elsewhere in the
11. 78 Damp heat steady state FEC and HUB 79 Damp heat cyclic FEC and HUB 80 Sulphur dioxide test for contacts and connections FEC and HUB 81 Hammer test FEC and HUB 82 Degrees of protection provided by enclosures IP Code FEC and HUB 83 Environmental Reliability tests AMS 85 Cold AMS 87 Vibration sinusoidal AMS 88 Hammer test AMS 89 Damp heat steady state AMS 90 Degrees of protection provided by enclosures IP Code AMS 91 Appendix 15 Test fires for detection and extinguishing 92 General 92 TF 9 Evaluation of reference framework CO sensor detection 94 TF 10 Test fire with five resistors detection 94 Test fires for detection and extinguishing 96 Appendix 16 Points of attention for use informative 100 Introduction 100 Projection detail design 100 Evaluation Guideline BRL K21014 04 Kiwa N V 6 June15 2009 Evaluation Guideline BRL K21014 04 Kiwa N V a ia June15 2009 1 Introduction 1 1 General The requirements mentioned in this Evaluation Guideline BRL are operated by Kiwa when handling a request or upkeep for the Kiwa product certificate EN 45011 for aerosol fire extinguishing systems for fire protection in enclosed compartments containing electrical components hereafter indicated as aerosol fire extinguishing system The granted declaration of quality is indicated as Kiwa product certificate During execution of certification activities Kiwa is tied to the requirements recorded in the chapt
12. A sinusoidal vibration simulates a single vibration Single vibrations are applicable to continuous rotating equipment This test method is very commonly used Amount of samples The test should be executed with 3 samples one sample for each direction One sample will be tracked during the test The other two samples will be tested measured before and after the test Procedure The sinusoidal vibration test shall be executed in accordance with IEC 60068 2 6 Test Fc Vibration sinusoidal The following level shall be used during the test 10 150 Hz 5 m s 3 axes 20sweep axes 1dB octave Inspections measurements The following parameters shall be tested measured before the test all samples LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DNDDDD WwW The following parameters should be tested measured during the vibration 1 sample B Serial communication to AMS HUB The following parameters should be tested after the test LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DNDDNDDADW Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable LEDs and display test still working Button test still
13. B Knows the concept display and power in dB B Knows the concept signal quality B Knows the concept and properties of transmission lines B Knows the functioning of antennas B Knows the concept polarisation B Knows the attenuation of the different buildings B Knows the influence of external interferences on radio links General knowledge of Radio Network Analyser B Knows the functioning of the Radio Network Analyser B Is able to carry out radio frequency RF measurements B Knows how to interpret the Radio Network Analyser in the correct way General knowledge of aerosol extinguishing system B Knows the structure of the aerosol extinguishing system B Knows the fields of application of the aerosol extinguishing system B Knows the functioning and structure of the alarm management system with radio interface Knows the functioning and structure of the signal repeater Knows the functioning and structure of the fire extinguishing component B Knows the levels of alarm and error messages B Knows the different authorisation levels DW Evaluation Guideline BRL K21014 04 Kiwa N V 32 June15 2009 B Knows the safety and environmental precautions to be heeded during design installation acceptance use and maintenance of an aerosol extinguishing system General knowledge of design detailed design installation putting into operation acceptance and maintenance of aerosol extinguishing systems Design B Knows the concept and imp
14. Radio communication B Bus communication B Ignition B CO measurement B Temperature measurement The following parameters should be tested measured at a low temperature during 16 hours 1 sample B Radio communication B CO measurement B Temperature measurement The following parameters should be tested measured after 16 hours The parameters should be tested at a low temperature 5 samples B Radio communication B Bus communication B Ignition B COmeasurement B Temperature measurement Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working Evaluation Guideline BRL K21014 04 Kiwa N V 74 June15 2009 Bus communication still working Ignition still working CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed DDD 21 3 Dry heat FEC and HUB Purpose This test is carried out for determining the effects on electrical and mechanical characteristics at high temperatures Visual analysis at high temperatures in combination with measurement of different functional parameters during the test shall give information about the robustness of the design Functional parameters like CO concentration and
15. This test fire is suited for testing the CO sensors In this test a printed circuit board with five resistors is electrically overloaded by a mains power supply device Fire material An epoxy printed circuit board for test purposes with the dimensions 100mm X 20mm On this board five metal film resistors are fixed each of 10 Q 0 6 W parallel switched The resistors must be measured beforehand for their real impedance Based on their real impedance sets of resistors must be selected of which the impedance are as close together as possible Equipment A stabilized mains power supply device 230 V mains power 8 Volt 20 Ampere and an adjustable output voltage Test cabinet as per figures 15 and 22 1 5 reference thermo couples Test setup The printed circuit board with the five resistors is laid in a box of non inflammable material with dimensions of approx 100mm x 100mm x 50mm The isolating board with the printed circuit board is placed at the bottom of the test cabinet Evaluation Guideline BRL K21014 04 Kiwa N V 94 June15 2009 The fire extinguishing components will be placed at the top of the cabinet to the sides with due observance of the specific requirements of the aerosol fire extinguishing components regarding outflow dimensions Around the fire extinguishing components reference thermo couples will be placed which will measure the temperature in the test cabinet Figure 15 Drawing with thermo couples
16. X 4 1 Compliance X X X 4 2 Basic system design X K K 43 Networked systems K X X 4 3 1 General requirements X X X 4 3 2 Specific requirements for hierarchical systems 7 44 Components K X X 4 5 Transmission path s X X X 4 6 Input and output devices linked to a fire X i X X protection system 4 7 Documentation X X X 5 Assessment methods and tests X j X X 5 1 General requirements X j X X 5 2 General test requirements X x K K 5 3 Functional test for compatibility K K K 5 4 Functional test for connectability K K K 5 5 Electromagnetic compatibility tests K K K Appendix Functions of fire detection and alarm K i X X A systems Appendix Methods for theoretical analysis X X X B Appendix Test report X X X C Appendix Classification of functions of a fire detection X ka K K D and alarm system Not within scope this has been settled elsewhere in the directive Evaluation Guideline BRL K21014 04 Kiwa N V 67 June15 2009 18 Appendix 11 Cross reference EN 54 18 Nr Subject FEC HUB AMS FEC Standalone 1 Scope and field of application 4 id 2 References K d K K 3 Definitions and abbreviations K 4 K K 3 1 Definitions K X X 3 2 Abbreviations X ii K K 4 Requirements K K K 4 1 Compliance K 2 X X 4 2 Monitoring of detachable devices i ii d gt 43 Marking and data K i K K 4 4 Documentation K K K
17. alarm systems 1999 Part 2 Control and indicating equipment including correction document NEN EN 54 4 Fire detection and fire alarm systems 1999 Part 4 Power supply equipment including correction document NEN EN 54 5 Fire detection and fire alarm systems 2001 Part 5 Thermal alarm devices Point detectors PrNEN EN 54 Fire detection and fire alarm systems 2001 13 Part 13 Compatibility of system components PrNEN EN 54 Fire detection and fire alarm systems 2003 18 Part 18 Input output devices PrNEN EN 54 Fire detection and fire alarm systems 2004 21 Part 21 Alarm transmission and fault warning routing equipment NEN EN 54 25 Fire detection and fire alarm systems 2008 Part 25 Components using radio links and system requirements NEN EN Fixed fire fighting systems Components for gas extinguishing systems 2003 12094 1 Part 1 Requirements and test methods for electrical automatic control and delay devices TEC 60068 1 1 Basic Environmental testing procedures 1998 Part 1 general and 1998 A1 1992 guidance TEC 60068 2 1 Environmental testing Part 2 1 Tests Tests A Cold including 1990 correction document TEC 60068 2 2 Basic environmental testing procedures Part 2 2 1974 Dry Heat d including correction document IEC 60068 2 6 Environmental testing Part 2 6 Tests Tests A Fc Vibration 1996 sinusoidal including correction document TEC 60068 2 27 Environmental testing Part 2 2
18. and should read AUTOMATIC FIRE EXTINGUISHING SYSTEM in case of fire or alarm do not panic close door s and alert expert assistance If special measures are necessary for preservation those must be stated in the working instructions and on the identification label of the packaging The identification on the housing and or packaging must clearly state the following issues Housing Packaging Indication x Qualification on the FEC based on EN2 x Name certified supplier Address and telephone number certified supplier Model type number Number of pieces gt x lt pad bad Pad gt lt gt lt Building year date of production CE number institution in question x gt lt gt lt Land of production pad Pas Compulsory information based on R amp TTE EMC and LVD directives Table 8 Identification housing and or packaging 3 7 Certification mark The certified products must be provided with the following icon stating NL K21014 NL K21014 Evaluation Guideline BRL K21014 04 Kiwa N V 30 June15 2009 4 4 1 4 2 4 3 4 3 1 Quality system requirements General These chapters describe the requirements that the certified supplier s quality system must meet Custodian of the quality system Within the certified supplier s organisation structure a functionary must be appointed who is charged with custody over the certified
19. as SMS devices PLC etcetera B Decentralized intelligence within this guideline this means that BRL K21014 04 June15 2009 Evaluation Guideline Kiwa N V 9 the detection extinguishing component is able to determine by itself free from the central processor whether to initiate signalling and or driving actions like for example extinguishing B Detection component Component for monitoring and guarding the object B Differential alarm device A device initiating an alarm when the degree of change of the measured phenomenon in relation to time exceeds a fixed value during a certain amount of time B DTMF codes Dual Tone Multi Frequency codes These tones are sent by the telephone to the network for remote control of answering machines buzzers etc EGL Evaluation Guideline Dutch BRL EMC Electromagnetic Compatibility European directives Faraday s Cage the name for a cage shaped construction of electric conductive material like copper or iron which ensures that electromagnetic radiation cannot penetrate into the cage Reception of radio signals is not possible inside a Faraday s Cage B Fire alarm equipment Alarm unit not integrated in the AMS used for indicating a fire alarm e g acoustic or optical signalling devices and not meant for evacuation alarm B Fire extinguishing component FEC The provisional designation for the aerosol fire extinguishing system including all the different component
20. attenuation of the different buildings B Can explain the influence of external interferences on radio links General knowledge of Radio Network Analyser B Can explain the functioning of the Radio Network Analyser B Is able to carry out radio frequency RF measurements B Knows how to interpret the Radio Network Analyser in the correct way General knowledge of aerosol extinguishing system B Can explain the structure of the aerosol extinguishing system B Can name the fields of application of the aerosol extinguishing system B Can explain the functioning and structure of the alarm management system with radio interface B Can explain the functioning and structure of the signal repeater Can explain the functioning and structure of the fire extinguishing component Can name the levels of alarm and error messages Can name the different authorisation levels Can name the safety and environmental precautions to be heeded during design installation acceptance use and maintenance of an aerosol extinguishing system DDD General knowledge of design detailed design installation putting into operation acceptance and maintenance of aerosol extinguishing systems Design B Is able to draw up a Program of Requirements B Is able to carry out frequency measurements Detailed design B Isable to draw up a an installation plan B Is able to calculate the amount of extinguishing agent needed for a compartment B Is able to apply the right projection
21. be caused by aggressive chemicals such as salt chloride sulphur dioxide hydrogen dioxide nitrogen oxide etc This test is carried out on devices which are normally protected against water like PCB s Amount of samples The test should be executed with 3 samples The samples will be tested measured before and after the test Procedure The corrosion mixed gas test shall be executed in accordance with IEC 60068 2 42 Test Kc Sulphur dioxide test for contacts and connections The following levels shall be used during the test 25 C 2 C 93 RH 3 25 5 vol ppm 21 days Inspections measurements The following parameters shall be tested measured before the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DNDDnDDW The following parameters should be tested measured after the test all samples B Radio communication B Bus communication B Ignition Evaluation Guideline BRL K21014 04 Kiwa N V 81 June15 2009 21 10 B CO measurement B Temperature measurement Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working mea
22. coverage and minimum height test X j arrangement procedure 50 4 Maximum height test arrangement procedure X h f 51 Distribution Verification Extinguishing Test with X ii e Automatic Extinguisher Unit 51 1 General X i 51 2 Test enclosure X 51 3 Maximum area coverage minimum height and K si maximum volume test arrangement procedure 51 4 Maximum height and maximum volume test X 4 arrangement procedure 52 Automatic Extinguisher Unit Automatic Operation X ii id Extinguishing Tests 52 1 General X 52 2 Test enclosures X x i 52 3 Test arrangement procedure X i 53 Elastomeric Parts Test i f 54 Stress Corrosion Cracking Test for Brass Parts ig is 55 Aging Test Condensed Aerosol Generator X H i 56 Aging Tests Plastic Materials X E ii 56 1 Air oven aging test K x i 56 2 Light and water test X i 57 Nameplate Exposure Tests X ii jd 58 Nameplate Adhesion Test K 59 Nameplate Abrasion Test K 9 60 Locking Device And Tamper ilndicator Test j i f Manufacturing and Production Tests i k 61 General X i 61 1 General X 61 2 Aerosol forming compound K i S 61 3 Electrical initiators X ii iji 61 4 Hydrostatic pressure test shells for pneumatic X ii control assemblies 61 5 Gauge calibration test for pneumatic control z assemblies 61 6 Leakage test for pneumatic control assemblies i Markings K 62 General X s Instructions X si ki 63 General K i i 64 Owner s Manual X A 65 Design Installation Operati
23. directive Evaluation Guideline Kiwa N V 53 BRL K21014 04 June15 2009 Appendix 3B Cross reference UL 2775 Nr Subject FEC HUB AMS Introduction i a 1 Scope X 2 Components K ji ii 3 Units of Measurement K hi 7 4 Undated References X 2 g 5 Glossary X ig Construction i 6 General X 7 7 Electrically Operated Alarms K a 2 8 Controls and Indicators X 9 Pneumatic Control Assembly Pressure Vessels j 10 Pressure Relief devices for Pneumatic Control k iii assemblies 11 Gaskets and O Rings 3 A 12 Pressure Gauges for Pneumatic Control Assemblies 13 Puncturing Mechanisms bl i 3 14 Electrically Operated Devices s 15 Condensed Aerosol Extinguishing Agents X j 16 Pneumatic Control Gases j ii 17 Polymeric Materials and Non metallic parts K s 18 Anti Recoil Devices 19 Pressure Switches s Performance si i 20 General X ii j 21 Discharge Test X j 22 Temperature Measurement Test X i if 23 Mounting Device Test K id 3 24 Rough Usage Test X ai i 25 Vibration Test X i 26 Pyrotechnic Reaction Containment Test X i ii 27 Fire Exposure Test K ii ki 28 High Humidity Test K i 29 Moist Hydrogen Sulphide Air Mixture Corrosion K 7 j Test 30 Moist carbon Dioxide Sulphur Dioxide Air Mixture X jih Corro
24. lt 95 RH Air pressure 86 to 106kPa 86 to 106kPa 86 to 106kPa no condensation The hardware is supposed to operate up to 60 C The system parts must have been developed according to IEC 60721 3 1 and IEC 60721 3 2 and must have been tested according to IEC 60721 4 1 and IEC 60721 4 2 in order to be able to be stored and transported without changing its properties or lifetime The system consists of products which must meet public law regulations including the Low Voltage Directive LVD 2006 95 EG the Radio amp Telecommunication Terminal Equipment Directive R amp TTE 1999 5 EG the Electromagnetic Compatibility Directive EMC 89 336 EEG gt 2004 108 EG the Construction Products Directive CPD 89 106 EG The products in the system are evaluated according to Kiwa guideline BRL K21014 The guideline incorporates parts the following standards The exact relation between the guideline and the standards is reflected in the annexes of the BRL Relevant standards are BRL K21014 04 June15 2009 Evaluation Guideline Kiwa N V 47 Standard number Standard title Year BRL K23001 03 Autonomous stationary extinguishing systems based on dry aerosols 2005 ISO 2859 1 Sampling procedures for sampling attributes part 1 sampling schemes indexed by 1999 expectance quality limit AQL for lot by lot i
25. maximum 3 meters that guarantees maintaining of functionality for at least 30 minutes during a fire The AMS must in compliance be provided with at least five potential free switch contacts 24 Volt 1 Ampere for communication with other systems o The AMS must be provided with a serial port for connection to a computer for installation and maintenance activities o The AMS must check the aerosol fire extinguishing system at least every 15 minutes power supply conditions radio communication status reports CO value and etcetera The check on reports must be defined in the supplier s user manual o The AMS must be provided with acoustic and optical indicators see paragraph 2 5 1 1 B The power supply of the AMS must meet the requirements stated in EN 54 4 1997 AC 1999 and EN 54 4 1997 A1 2002 o The AMS must be connected to a primary power supply 110 V 260 V 50 Hz 60 Hz In case of a fault warning in the power supply the secondary emergency power supply must be able to feed the AMS for at least 24 hours of which at least 30 minutes in alarm status The primary power supply and the secondary power supply of the AMS HUB must be obtained from the AMS Explanation If faults in the power supply are automatically notified within 30 minutes to a fault warning receiving station that is manned 24 hours a day and if a maintenance agreement as per NEN 2654 1 has been concluded with the fire detection company and this company gua
26. shall be used during the test t40 C 2 C 93 RH 3 21 days Inspections measurements The following parameters shall be tested measured before the test all samples LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DNDDNDDDADW The following parameters should be tested measured at day 21 with the high humidity still in the climate chamber The samples should be taken out of the climate chamber one by one The following parameters should be tested within 10 minutes LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays The samples will be placed back inside the chamber to finish the complete 21 days DWDDNDDD DW Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B LEDs and display test still working B Button test still working B Buzzer test still working B Serial communication to AMS HUB still working Evaluation Guideline BRL K21014 04 Kiwa N V 90 June15 2009 B Modem communication still working B Switching of relays still working 21 17 Degrees of protection provided by enclosures IP Code AMS Purpose The purpose of this method is to determine the ingress of solid
27. the item bank During the exam a supervisor of Kiwa Certification and Inspections will be present The certificate has a validity of 3 years conformably to NEN EN ISO TEC 17024 4 4 4 Item bank The item bank must contain at least four different questions for each end term 4 4 5 Maintaining competence To keep the certificate valid the certificate owner must have designed installed accepted and maintained at least ten aerosol extinguishing systems during the certification period with a minimum of two per year The certificate owner must register this in the log book supplied together with the certificate The year period goes in effect from the moment of obtaining the personal certificate date of issue Each project in which a certificate owner is or has been involved must be recorded in the log book supplied If the certificate owner does not reach the yearly minimum number of projects the validity of the certificate expires In order to be considered for a renewal of the personal certificate the applicant Evaluation Guideline BRL K21014 04 Kiwa N V 35 June15 2009 must prove by successfully passing the exam again to be still in command of the knowledge required 4 4 6 Keeping up knowledge The supplier of the certified products will keep the certificate owners informed about the latest developments by means of a periodical newsletter at least once a year Within a month after reception of the newsletter technic
28. will be tested measured before and after the test Procedure The low temperature test shall be executed in accordance with IEC 60068 2 1 Test A Cold The following level shall be used during the test OC 2 C during 16 hours Inspections measurements The following parameters shall be tested measured before the test all samples LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DWDDDDA WwW The following parameters should be tested measured at a low temperature during 16 hours 1 sample B Serial communication to AMS HUB The following parameters should be tested measured after 16 hours The parameters should be tested at a low temperature LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DWDDDDA DW Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B LEDs and display test still working B Button test still working B Buzzer test still working Evaluation Guideline BRL K21014 04 Kiwa N V 87 June15 2009 B Serial communication to AMS HUB still working B Modem communication still working B Switching of relays still working 21 14 Vibration sinusoidal AMS Purpose
29. z 3 Terms and definitions X X X 4 System requirements X X X 4 1 General X X X 4 2 Compatibility X X X 43 Radio links i 4 3 1 Immunity to attenuation X X X 4 3 2 Alarm signal integrity X X X 4 3 3 Identification of the transmitter X X X 4 3 4 Immunity to interference X X X 4 3 5 Failure in periodic communication X X X 4 3 6 Antenna X X X 5 Components requirements X X X 5 1 General X X X 5 2 Power supply equipment lt K 5 3 Environmental test requirements X X X 6 Documentation X X X 7 Marking K K K 8 Test K K K 8 1 General X X X 8 2 System tests X X X 8 2 1 Test schedule for system tests X X X 8 2 2 Test for immunity to attenuation X X X 8 2 3 Test for alarm signal integrity X X X 8 2 4 Test for identification X X X 8 2 5 Test for the quality of the receiver X X X 8 2 6 Test of compatibility within systems of the same system X X X supplier 8 2 7 Test of compatibility with other band users X X X 8 2 8 Test for the detection of a failure of periodic X X X communication on a link 8 2 8 Test of the antenna X X X 8 3 Component tests X X X 8 3 1 General X X X 8 3 2 Test schedule for components tests X X X 8 3 3 Verification of the service life of the non rechargeable X X X power source s 8 3 4 Test for the low power condition fault signal X X X 8 3 5 Test for polarity reversal X X X 8 3 6 Repeatability tests X X X 8 3 7 Reproducibility test X X X 8 3 8 Variation of supply parameters X X X 8 3 9 Dry heat operational X X X 8
30. 7 AC 1999 and EN 54 4 1997 A1 2002 See appendix 5 Housing IEC 60068 2 1 IEC 60068 2 2 IEC 60068 2 6 IEC See appendix 14 60068 2 27 IEC 60068 2 30 IEC 60068 2 32 IEC 60068 2 42 IEC 60068 2 56 IEC 60068 2 75 IEC 60068 2 78 and IEC 60529 Table 2 System structure in relation to national and international directives Evaluation Guideline Kiwa N V 16 BRL K21014 04 June15 2009 2 3 Performance requirements of the components Below the performance requirements for the various components of the fire extinguishing component are stated supplementary to and or deviating from appendices 1 to 16 2 3 1 General The FEC must be able to function at a temperature from 10 C to 45 C and an air humidity of maximum 95 no condensation Explanation see the remarks below table 1 in this document 2 3 2 Aerosol fire extinguishing component a The aerosol fire extinguishing component must meet the requirements stated in the Evaluation Guideline BRL K23001 03 2005 for product and quality or UL 2775 2008 or CEN TR 15276 1 for product See further appendix 3A 3B or 3C 2 3 3 Fire alarm extinguishing device b The Fire alarm extinguishing device must meet the requirements stated in the EN 54 2 1998 and EN 54 2 Design A1 2004 See further appendix 5 Deviating and supplementary requirements are B The fire alarm extinguishing device must be provided with a serial port for a connection to a computer b
31. 7 Tests Tests Ea Shock 1987 TEC 60068 2 30 Environmental testing Part 2 30 Tests Tests Db Damp heat cyclic 1980 IEC 60068 2 32 Environmental testing Part 2 32 Tests Tests Ed Free Fall 1993 Evaluation Guideline Kiwa N V BRL K21014 04 43 June15 2009 TEC 60068 2 42 Environmental testing Part 2 42 Test methods Tests Kc Sulphur dioxide test for contacts and connections 2002 TEC 60068 2 75 Environmental testing Part 2 75 Tests Tests Eh Hammer Test 1997 IEC 60068 2 78 Environmental testing Part 2 78 Tests Tests Cab Damp Heat steady 2001 state IEC 61340 5 2 Electrostatics Part 5 2 Protection of electronic devices from 2001 electrostatic phenomena User guide EN 2 Fire classes 1994 Evaluation Guideline Kiwa N V BRL K21014 04 44 June15 2009 o kiwa p Partner for progress Appendix 1 model product certificate Number 12345 Replaces Issue Date Product certificate Aerosol fire extinguishing systems for fire protection in enclosed compartments containing electrical components Based on pre certification tests as well as periodic inspections by Kiwa the products manufactured by Certificate owner specified in this certificate and marked with the KQ mark as indicated under Marking may on delivery be relied upon to comply with the Kiwa Evaluation Guideline K21014 Kiwa N V ing B Meekma Director Ce
32. B Ignition B CO measurement B Temperature measurement Evaluation Guideline BRL K21014 04 Kiwa N V 76 June15 2009 Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed 21 5 Shock FEC and HUB Purpose A shock test is performed to provide a degree of confidence that devices can physically and functionally withstand the relatively infrequent non repetitive shocks encountered in handling transportation and service environments Amount of samples The test should be executed with 3 samples For each direction one sample One sample will be tracked during the test The other two samples will be tested measured before and after the test Procedure The shock test shall be executed in accordance with IEC 60068 2 27 Test Ea Shock The following levels shall be used during the test Half sine 6ms 10x 100 20M m s M mass of device Inspections measurements The following parameters shall be tested measured before the test all samples Radio communication Bus communic
33. Equipment 1999 Directive 89 336 EEG Electromagnetic Compatibility Directive 1989 2004 108 EG Electromagnetic Compatibility Directive 2004 89 106 EG Construction Products Directive 1998 Evaluation Guideline BRL K21014 04 Kiwa N V 42 June15 2009 7 2 Directive normative documents Norm number Title directive Year BRL K23001 03 Autonomous stationary extinguishing systems based on dry aerosols 2005 UL 2775 Outline of investigation for fixed condensed aerosol extinguishing units 2008 issue no 1 CEN TR 15276 Fixed fire fighting systems Condensed aerosol extinguishing 2008 1 systems Part 1 Requirements and test methods for components ISO 2859 1 Sampling procedures for sampling attributes part 1 sampling 1999 schemes indexed by expectance quality limit AQL for lot by lot inspection NEN 3011 Safety colours and safety signs 1986 NEN 5509 User manuals Content structure formulation and presentation 1998 CEI TEC 62079 Preparation of instructions structuring content and presentation 2001 TEC 60529 Consolidated Edition Degrees of protection provided by enclosures 2001 IP Code Applies to the classification of degrees of protection provided by enclosures for electrical equipment with a rated voltage not exceeding 72 5 kV Has the status of a basic safety publication in accordance with IEC Guide 104 NEN EN 54 2 Fire detection and fire
34. FEO FEC P Production D Development T Test Figure 9 Software identification The figure below shows how the traceability of the specifications is guaranteed EN NEN Pen ey A re a Directives 1 System naa ra ak so a YA System test specification 4 Verification EGL 21014 1 1 1 1 Architecture 7777777777 System integration test i AMS HUB FEC Integration Integration Integration 1 Specification Design _ test test test Design and 7 7 implementation rs Test and l beet se integration Module Tests E I i Implementation A Traceability gt B Requirements traceable from document A to B Figure 10 Traceability of the specifications Evaluation Guideline BRL K21014 04 Kiwa N V 29 June15 2009 The traceability of the components in the system is assessed individually during the module tests 3 6 Packaging preservation storage identification The packaging must be appropriate for its use which is at least transport with a container for road ship and air freight Furthermore packaging must reckon with transport of aerosol components The packaging must contain stickers that offer a safety instruction for the system s use The stickers must be attached to the outside and inside of the object to be protected
35. IEC 60529 2 Signal repeater HUB Radio connections and system The product must meet the relevant requirements as See appendix 9 requirements per the applying CE marking directives and EN54 25 2008 Power supply EN 54 4 1997 AC 1999 and EN 54 4 1997 A1 2002 See appendix 5 Housing IEC 60068 2 1 IEC 60068 2 2 IEC 60068 2 6 IEC See appendix 14 60068 2 27 IEC 60068 2 30 TEC 60068 2 32 IEC 60068 2 42 IEC 60068 2 56 IEC 60068 2 75 IEC 60068 2 78 and IEC 60529 3 Alarm Management System AMS with radio interface AMS HUB Fire alarm extinguishing device EN 54 2 1998 and EN 54 2 Design A1 2004 See appendix 4 and 14 Power supply EN 54 4 1997 AC 1999 and EN 54 4 1997 A1 2002 See appendix 5 System requirements and compatibility prEN 54 13 2001 See appendix 10 assessment Requirements and test methods for EN 54 18 2003 See appendix 11 input and output devices for use of transmission paths of fire alarm systems Alarm transmission and fault warning EN 54 21 2004 See appendix 12 routing equipment Explanation This is not a compulsory element in the AMS usually this element is provided by the alarm station Housing TEC 60068 2 1 IEC 60068 2 6 IEC 60068 2 27 IEC See appendix 14 60068 2 75 IEC 60068 2 78 and IEC 60529 3a Radio interface AMS HUB Radio connections and system The product must meet the relevant requirements as See appendix 9 requirements per the applying CE marking directives and EN54 25 2008 Power supply EN 54 4 199
36. IRE ALARM LED 100ms step Buzzer KHz Sweep 5 5 5 5 5 5 EXTINGUISHING LED 100ms step Buzzer KHz Sweep Continuous signal sweep 4KHz 5KHz 1 sec duration sweep EXTINGUISHING LED 100ms step SILENT Buzzer KHz Sweep disabled Table 4 LED Buzzer behaviour Evaluation Guideline BRL K21014 04 Kiwa N V 25 June15 2009 2 5 2 Communication B System requirements and compatibility assessment must meet the requirements as stated in prEN 54 13 2001 B Requirements and test methods for input and output devices for use of transmission paths of fire alarm systems must meet the requirements as stated in EN 54 18 2003 B Optional requirement The following requirement is not compulsory but if you do want to apply routing equipment for notification in the AMS the routing equipment for alarm and fault warning must meet the requirements stated in EN 54 21 2004 Deviations from this are The AMS must be provided with a telephone dialler in compliance with requirements from the R amp TTE directive to notify alerts fire alarms and malfunctions to a telephone number and it must be able to forward these by DTMF codes dual tone The modem must be able to call for each status alert fire alarm malfunction five pre programmed telephone numbers Table 5 shows an overview of the possibilities Event Priority Telephone numbers DTMF codes 1 4 backup ALARM High 0 9 0 9 ALERT Medium 0 9
37. Inward control components Components supplied by third parties must meet the requirements stated in chapter 3 3 1 3 3 2 and 3 3 3 This must be registered by the certified supplier The system s composition must have been determined during type testing and should be registered by Kiwa and the certified supplier Each delivery of semi finished products should contain delivery certificates or specifications by the certified suppliers proving that the composition is still according to the same specifications The quality of the sub products is established by means of a statistic process control based on a previously determined sampling with an accepted quality level as per ISO2859 1 This should be determined based on risk inventory and evaluation The minimal sample size should be inspection level S2 and accepted quality level AQL 6 5 4 6 2 Inprocess production controles The visual controls on solder joints should take place as per IPC A 610 version D Acceptability of Electronic Assemblies IPC Association connection electronics industries The quality level required is class 2 The printed circuit boards should be evaluated as per IPC A 600 revision D class 2 The working instructions should give insight in the processing of the coating finish and polarity of the components as well as cleaning of the components and the print The quality of the sub products is established by means of a statistic process control based on a previou
38. N AFTER FIRE ALARM EXTINGUISINGING Figure 4 FEC Indicator Buzzer status behaviour Evaluation Guideline BRL K21014 04 Kiwa N V 19 June15 2009 2 3 4 The optical and acoustic indicators must show a pattern as stated in figure 5 Status LED Buzzer behaviour SAFE LED 100ms step 5 minutes Buzzer KHz Silent Sweep SUSPEND LED 100ms step Buzzer KHz Silent Sweep ERROR LED 100ms step Buzzer KHz 5 5 Sweep ALERT LED 100ms step Buzzer KHz 5 5 5 5 Sweep FIRE ALARM LED 100ms step See Figure 6 Buzzer KHz See Figure 6 Sweep EXTINGUISHING LED 100ms step Buzzer KHz 4 4 Sweep FACTORY LED 100ms step Delivery Buzzer KHz Silent Sweep FACTORY LED 100ms step Red Green Yellow Testing Buzzer KHz pattern repeated Sweep FACTORY LED 100ms step Error Buzzer KHz Silent Sweep Figure 5 FEC Indicator behaviour The figure below shows the behaviour of the optical and acoustic indicators at the moment that the FEC starts giving an optical and acoustic signal for the extinguishing ete f i i H Buzzer AAA Ara Paws 4KHz time in seconds Figure 6 Optical and acoustic signal for extinguishing Detection component c The detection component must meet
39. NEN 2535 1996 APPLICATION AND USE Full title The full title of this evaluation guideline is the Kiwa product certificate for aerosol fire extinguishing systems with wireless communication to an alarm management system for fire protection in enclosed compartments containing electrical components maximum 1500 Volts DC and 1000 Volts AC Product aim The aerosol fire extinguishing system should monitor the environment to be protected for fire phenomena by detecting these and then communicate with other equipment within the system with the purpose to alarm in an initial phase of fire notify a receiving station for fire alarms extinguish in the fire phase and control during a set period The application is primarily meant for objects that cannot be entered by humans and fall under the definition un enterable room More specifically the objective is as follows Early detection with wireless fire alarm system with detection based on CO and AT Tmax for fire sizes as stated in appendix 15 The extinguishing system should prevent an expansion of the fire outside the cabinet during the standing time of the extinguishing agent Evaluation Guideline BRL K21014 04 Kiwa N V 46 June15 2009 The aerosol fire extinguishing system is aimed for application in compartments such as e Switch cabinets e Computers Meter boxes Starting point in this is a standard projection see appendices 15 and 16 for detection and for exting
40. Seconds After inspection time 300 Seconds Outflow SFE Direction and homogeneity Visual Weight extinguishing component for Before and after the extinguishing Grams Activation According to the supplier s system Table 15 Conditions real life test Supplemental registrations during the test in seconds e The time of ignition The time the activation of the fire extinguishing components started e e The end time of the activation of the aerosol e The time at which the flames are extinguished During the fire period sufficient ventilation should take place and the oxygen level inside the test room should be kept level under atmospheric conditions BRL K21014 04 June15 2009 Evaluation Guideline Kiwa N V 99 23 Appendix 16 Points of attention for use informative 23 1 Introduction For a correct application of the product it is important to understand that the system s detection principal is designed and tested based on a certain projection The projection is described below It is important to carefully follow these projection rules in order to achieve the detection performance requirements in practice as well 23 2 Projection detail design The number of fire extinguishing components FEC needed for a specific object also determines the projection i e the position and direction in which the FEC s must be mounted When applying 1 FEC it will be placed in the middle of the object o
41. ab Damp heat steady state gt S gt ed od ed hi Degrees of protection provided by enclosures IP Code Table 14 Test situation environmental tests Evaluation Guideline BRL K21014 04 Kiwa N V 73 June15 2009 21 2 Cold FEC and HUB Purpose This test is carried out for determining the effects on electrical and mechanical characteristics at low temperatures Visual analysis at low temperatures in combination with measurement of different functional parameters during the test shall give information about the robustness of the design Surge current functional parameters like CO concentration and temperature and functions like ignition radio communication and bus communication that would show the deleterious effects due to exposure to low ambient temperatures will be measured Amount of samples The test should be executed with 5 samples One sample will be tracked during the test The other four samples will be tested measured before and after the test Procedure The low temperature test shall be executed in accordance with TEC 60068 2 1 Test A Cold The following level shall be used during the test 10C 2 C during 16 hours The FEC and HUB will be connected to an external power supply due to the fact that the battery can not supply enough power at low temperatures lt 0 C Inspections measurements The following parameters shall be tested measured before the test all samples B
42. al bulletin manual adjustments the certificate owner must record in his log book that he has received the documents in question comprehended the information it contained and that he will act upon any instructions given If the certificate owner omits this the validity of the certificate expires If validity expires it must be recorded into the log book In order to be considered for a renewal of the personal certificate the applicant must prove by successfully passing the exam again to be still in command of the knowledge required 4 5 Internal quality control quality plan The certified supplier must have an internal quality control scheme IQC scheme which he applies During the pre certification tests this scheme must be functional for at least 3 months In this IQC scheme it must be proven e what aspects are checked by the certified supplier with what methods these inspections are carried out how often these inspections are carried out in what way the inspection results are recorded and kept This IQC scheme should be at least an equivalent derivative of the blank model presented in the appendix with the following additions For all components drawings and part list should be available Changes in these documents may only be made after written consent by the certification institution The certified supplier should have a complete overview with all component specifications and if available component certificate compone
43. and placement of the fire extinguishing components FE Amount One printed circuit board with five resistors 10 Q 0 6 W parallel switched Test procedure Before testing the product must be conditioned and synchronized Connect the printed circuit board to the adjustable output of the mains power supply device and set the output voltage to 5 Volt at 2 5A Then gradually increase the voltage in 60 seconds to 7 5 Volt as per the table below Time in seconds Voltage in Volts 0 5 10 5 42 20 5 84 30 6 26 40 6 68 50 7 10 60 7 5 The test procedure is carried out with the ventilator present Reaction time Within 120 seconds the alert alarm of the fire extinguishing component should be activated Evaluation Guideline BRL K21014 04 Kiwa N V 95 June15 2009 22 4 Test fires for detection and extinguishing General During this test fire a reproducible blazing fire is produced by igniting the test fires TF4 TF7 and TF1 During this test fire the system compatibility the detection and the extinguishing of the aerosol fire extinguishing system is tested and evaluated Fire material TF4 Flexible polyurethane mats with uniform cell structure and a density of 17 kg m3 to 20 kg m3 without fire delaying additions dimensions 100 mm x 100 mm x 20 mm The mats are piled on top of each other 9 pieces in formation 3 x 3 x 3 on clean aluminium foil Physical and chemical properties of
44. ated spirit with a gas lighter o Ignite the methylated spirit for the beech wood crib with a gas lighter B Close the door of the test cabinet immediately after ignition this is the test s starting moment The cabinet s ventilator should be active when closing the door The test procedure takes place with the ventilator present as per 22 1 B The fire cell should burn for at least 30 seconds CO detection and driving of the thermal alarm device should have occurred before this time expired B At the conclusion of the activation of the extinguishing agent the cabinet should remain closed for at least 5 minutes B During this period the cell should be monitored for active fire phenomena and spontaneous combustion phenomena this will take place based on the temperature measurements near the fire cell B After this period the cell should be checked visually for active fire phenomena and spontaneous combustion phenomena outside the test cabinet without the presence of extinguishing agent B Fire phenomena should be expressed in the report The loss of weight and the temperature after extinguishing are leading B Spontaneous combustion phenomena should have a form of visual fire Just smoke is not categorised as such During the test simultaneously another test will be carried out regarding the interbus communication During the real life test an FEC outside the test cabinet will be connected by means of the interbus to an FEC undergoing t
45. ation Ignition CO measurement Temperature measurement DWDDDW The following parameters should be tested measured during the shock 1 sample B Radio communication B CO measurement B Temperature measurement The following parameters should be tested measured after the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement PRPP Evaluation Guideline BRL K21014 04 Kiwa N V 77 June15 2009 Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed 21 6 Free fall Drop test FEC and HUB Purpose Drop tests are performed to A Provide a degree of confidence that devices can physically and functionally withstand the relatively infrequent non repetitive drops encountered in handling transportation and service environments B Determine the device fragility level in order that housing and or packaging may be designed to protect the device Amount of samples The test should be executed with 3 samples Procedure The
46. atories as prove that the requirements from the directive s are met it must be proven that these reports are drawn up by an institution that meets the applicable accredited directives namely B NEN EN ISO IEC 17025 for laboratories B NEN EN 45011 for certification institutions certifying products The institution is supposed to meet the requirements when an accreditation certificate can be submitted that has been granted by the Dutch Council for Accreditation RvA or an accreditation institution with which the RvA has concluded a mutual acceptance agreement This accreditation should relate to the tests required for this Evaluation Guideline If no accreditation certificate can be submitted the certification institution itself will verify whether the accreditation directives have been met or else carry out or have carried out the tests in question The certified supplier has all the afore mentioned certificates of these products available in a components file with an up to date overview This file must be checked yearly by the certified supplier The afore mentioned components must be checked visually for material and or packaging specifications 3 1 2 Normalized products without product control mark These materials must be checked for these specifications based on a declaration by the manufacturer as well as the visual check of material and or packaging specifications Evaluation Guideline BRL K21014 04 Kiwa N V 27 J
47. cabling must be provided with maintenance of functionality during fire for at least 30 minutes Figure 3 shows a protocol of a reliable connection event FIRE ALARM Start 10 sec Timer ALARM level detected Start 10 sec Timer ALERT Generate event FIRE ALARM ALARM level Slave detected ERROR FIRE ALARM FIRE ALARM Generate event FIRE ALARM ji Every 2 seconds LONG BUTTON PUSH Generate byent FIRE ALARM SUSPEND event SUSPEND Slave PUSH BUTTON 10 sec Timer Master Bd Generate event over SUSPEND Every 5 seconds EXTINGUISHING Generate event SUSPEND Figure 3 Example protocol Evaluation Guideline Kiwa N V 18 BRL K21014 04 June15 2009 2 3 3 1 Operational statuses Figures 4 and 5 show the behaviour of operational statuses and the optical and acoustic indicators of the FEC 7 PPOWER SUPPLY ON IN FACTORY e POWER SUPPLY PUSH BUTTON LONG ON PUSH BUTTON LONG SUSPEND PUSH BUTTON LONG ALERT SAFE ERROR PUSH BUTTON LONG PUSH BUTTON LONG ERROR Yellow ALERT FIRE ALARM PIREALARM Start interruption TIMER Start interruption TIMER L FIRE ALARM Red Start interruption TIMER Interruption TIMER concluded EXTINGUISHING ACTIVATED FIRE ALARM EXTINGUISHING Red POWER SUPPLY O
48. drop free fall test shall be executed in accordance with IEC 60068 2 32 Test Ed Free fall The following levels shall be used during the test 2m 6 sides 4 corners 2 times for each side and corner The device will be dropped from 2 meter height on all 6 sides and 4 corners The total sequence of 6 drops and 4 corners will be repeated after the first 10 drops A total amount of 20 drops will be executed Inspections measurements The following parameters shall be tested measured before the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement WARANA The following parameters should be tested measured after the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DNDDnDDW Evaluation Guideline BRL K21014 04 Kiwa N V 78 June15 2009 Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed 21 7 Damp heat steady state FEC and HUB Purpose This test i
49. e following test sequence has been made 2 samples Cold TEC 60068 2 1 16 hours Vibration sinusoidal TEC 60068 2 6 24 hours Impact IEC 817 24 hours Damp heat IEC 60068 2 78 21 days Ingress protection TEC 60529 1 day Figure 13 Test schedule environmental tests AMS Evaluation Guideline Kiwa N V 85 BRL K21014 04 June15 2009 The total amount of samples will be 2 The total lead time will be 25 days For each test a detailed description has been made which will be presented in the following paragraphs lt gt FEC AMS AMS HUB Situation A only the AMS will be tested Figure 14 Test setup environmental tests AMS Evaluation Guideline BRL K21014 04 Kiwa N V 86 June15 2009 21 13 Cold AMS Purpose This test is carried out for determining the effects on electrical and mechanical characteristics at low temperatures Visual analysis at low temperatures in combination with measurement of different functional parameters during the test shall give information about the robustness of the design Surge current functional parameters like CO concentration and temperature and functions like ignition radio communication and bus communication that would show the deleterious effects due to exposure to low ambient temperatures will be measured Amount of samples The test should be executed with 2 samples One sample will be tracked during the test The other sample
50. e housing must have at least IP class 30 as per IEC 60529 2001 B The colour of the housing containing the aerosol fire extinguishing component must be red RAL 3000 product requirement 2 3 7 Attaching It must be possible to attach the fire extinguishing component appropriately to walls and ceilings of the protected room The housing and fixing materials must be able to carry 5 x their own weight with a minimum of 5 kg 2 4 Performance requirements signal repeater HUB and radio interface AMS HUB Below the performance requirements for the various components of the signal repeater are stated supplementary to and or deviating from appendices 1 t m 16 2 4 1 General B The HUB must be able to function at a temperature from 10 C to 60 C and an air humidity of maximum 95 no condensation B HUB and AMS HUB must be able to indicate the statuses mentioned below HUB e POWER SUPPLYON IN FACTORY FACTORY Yellow Green SAFE 1 COMMUNICATION NO ERROR and 2 ROUTE AVAILABLE COMM ROUTES and or AVAILABLE ERROR Yellow NO COMMUNICATION ROUTE AVAILABLE AVAILABLE OFFLINE POWER SUPPLY ON COMMUNICATION ROUTE PUSH BUTTON LONG 2 COMMUNICATION ROUTES AVAILABLE f 1 COMMUNICATION ROUTE AVAILABLE or J ERROR NO COMMUNICATION ROUTE AVAILABLE AMS HUB POWER SUPPLY ON RADIO TELEGRAM RECEIVED The AMS HUB is not provided with a buzzer Fi
51. e subcontractor and the certified installation mechanic DNDnDDADW The supplier should settle this with his subcontractor based on contractual agreements The subcontractor should always be registered at Kiwa prior to commencing the activities 4 10 Legal liability The certified supplier should have a valid liability insurance of at least 1 25 million EURO and should be registered at the Chamber of Commerce 4 11 Storage and treatment The aerosol fire extinguishing system should be transported and treated dry and free of weather influences with a storage temperature and maximum air humidity as specified by the certified supplier The electronics should be packaged conformably to IEC 61340 5 2 Electrostatics Part 5 2 Protection of electronic devices from electrostatic phenomena User guide in a packaging preventing negative influence of electrostatic discharge Storage and treatment must be done in such a way that damaging of the product is prevented Evaluation Guideline BRL K21014 04 Kiwa N V 38 June15 2009 5 Summary of tests and inspections This chapter offers a summary of the activities to be carried out during certification namely B Pre certification tests B Inspection test of performance requirements and product requirements B Inspection of the quality management system For each activity the frequency of the inspection tests by Kiwa is stated as well 5 1 Inspection matrix De
52. ead free 3 3 Manual The product is exclusively supplied to customers who are qualified by the supplier In this qualification it must be settled that the customer has received and understood the installation and user manual The manual for design installation acceptance use and maintenance must meet the requirements stated in NEN 5509 1998 and CEI IEC 62079 2001 Furthermore the manual must offer compulsory information based on the R amp TTE EMC and LVD directives 3 4 Quality structure In a risk inventory and evaluation as stated in chapter 4 5 1 the supplier must determine which sub products are categorized as certified products normalized products without product control mark and non normalized products For all sub products documentation must be available BRL K21014 04 June15 2009 Evaluation Guideline Kiwa N V 28 3 5 Software identification The supplier must ensure that the FEC HUB and AMS contain the correct software configuration To identify the software an unique software identification must be specified in the FEC HUB AMS HUB and AMS The version control must be guaranteed by the supplier The figure below shows the software identification lt status gt SW lt prod_name gt R lt Vmajor gt lt Vminor gt J J J 2 digits BCD smaller version number 2 digits BCD larger version number 3 characters abbreviation product name BAS AMS BHU AMS_HUB HUB HUB
53. ed within 10 minutes Radio communication Bus communication Ignition CO measurement Temperature measurement DNDDnDDAW Evaluation Guideline BRL K21014 04 Kiwa N V 79 June15 2009 B The samples will be placed back inside the chamber to finish the complete 21 days Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed 21 8 Damp heat cyclic FEC and HUB Purpose The purpose of this method is to determine the resistance of material to the effects of a warm humid atmosphere Amount of samples The test should be executed with 3 samples One sample will be tracked during the test The other two samples will be tested measured before and after the test Procedure The temperature change test shall be executed in accordance IEC 60068 2 30 Test Db and guidance Damp heat cyclic The following level shall be used during the test B 25 C 3 C gt 95 RH during 3 hours followed by B 40 C 2 C 93 RH 3 during 3 hours B 2cycles B Temperature change of 3 C min tem
54. ent The aerosol fire extinguishing system is aimed to be applied in compartments such as those mentioned below i e object protection B Switch cabinets B Computers B Meter boxes Starting point is a standard projection see appendix 15 for detection and extinguishing It is a pre engineered system The system s installation must be described in the supplier s manual The supplier should train the users through a course in design installation acceptance use and follow up For an integral safety concept the course should be applied in combination with this Evaluation Guideline Evaluation Guideline BRL K21014 04 Kiwa N V 8 June15 2009 Explanation If the detection system does not function the system shall be activated by means of a thermal cord If this thermal cord refuses activation takes place based on the aerosols own activation temperature The values must be declared in the product certificate of the aerosol extinguishing agent as per guideline K23001 Additionally the product certificate must give insight in dimensioning of the system The aerosol fire extinguishing system should function in an indoor environment meeting the following conditional requirements Conditions FEC HUB AMS Operative Temperature 10 C to 45 C 10 C to 60 C 10 C to 60 C Air humidity lt 95 RH lt 95 RH lt 95 RH Air pressure 86 to 106kPa 86 to 106kPa 86 to 106kPa Sto
55. er Requirements to certification institutions The fourth version of this Evaluation Guideline incorporates UL2775 and CEN TR 15276 1 These changes have no implementation requirement It gives the certified company s the possibility to operate world wide This evaluation guideline replaces the BRL K21014 03 on March 15 2009 1 2 Scope The full title of this Evaluation Guideline is the Kiwa product certificate for aerosol fire extinguishing systems with wireless communication to an alarm management system for fire protection in enclosed compartments containing electrical components maximum 1500 Volt DC and 1000 Volt AC Aim of the product The aerosol fire extinguishing system must monitor the environment to be protected for fire phenomena This is done by detecting these fire phenomena and then communicates with other equipment within the system The purpose is to alarm in an initial phase of fire to notify a fire alarm station to extinguish in the fire phase and to control during a set time Its application is primarily meant for objects that cannot be entered by humans and come under the definition non enterable room More specifically its purpose is as follows Early detection with wireless fire alarm system with detection based on CO and AT Tmax for fire sizes as stated in appendix 15 The extinguishing system should prevent an expansion of the fire outside the cabinet during the standing time of the extinguishing ag
56. er s manual The supplier should train the users through a course in design installation acceptance use and follow up For an integral safety concept the course should be applied in combination with this Evaluation Guideline The maximum combined number of fire extinguishing components FEC and signal repeaters HUB within one system is 511 Within a system configuration the transmission path between a fire extinguishing component and the alarm management system is limited to a maximum of 32 signal repeaters HUB The system has to communicate on a licence free frequency band ISM frequency for which wireless communication for alarm purposes is permitted The aerosol fire extinguishing system should be constructed in such a way that the radio connection as transmission path is carried out redundantly The system consists of products which must meet public law regulations including e the Low Voltage Directive LVD 2006 95 EG e the Radio amp Telecommunication Terminal Equipment Directive R amp TTE 1999 5 EG e the Electromagnetic Compatibility Directive EMC 89 336 EEG resp 2004 108 EG e the Construction Products Directive CPD 89 106 EG Evaluation Guideline BRL K21014 04 Kiwa N V Sali June15 2009 In the appendices is stated which parts of the directives apply and which parts are excluded The chapters 2 3 2 4 en 2 5 state supplementary requirements regarding the directives mentioned in order to achieve a well func
57. ery fire class stated by the supplier concerning the certification inspection The tests are carried out for the aerosol which the supplier wants to have certified During these tests the design formula used by the supplier for projection of the aerosol extinguishing components is verified The formula used by the supplier should demonstrate that the following has been taken into account e the dimensions of the room containing the object to be extinguished as well as the specific mutual dimension proportions length width and height the aerosol s diffusion factor the amount of extinguishing agent in terms of grams extinguishing agent per m3 room The test is carried out in an all but closed room see figure 15 and 22 1 Doors must be closed The room may contain a limited amount of ventilation grids Any forced ventilation in the room must be disabled by a control before the extinguishing takes place During the test the arithmetical translation of the amount of grams per volume unit must be taken literally for this will be leading for the value declared in the certificate There may not be any physical obstructions inside the room During testing of the extinguishing performance and of the design formula for the amount of extinguishing agent necessary no additional safety factors 1 3 which are required by European and NFPA directives for projection may be applied Furthermore the design formula should take into accoun
58. es are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed 21 4 Vibration sinusoidal FEC and HUB Purpose A sinusoidal vibration simulates a single vibration Single vibrations are applicable to continuous rotating equipment This test method is very commonly used Amount of samples The test should be executed with 3 samples one sample for each direction One sample will be tracked during the test The other two samples will be tested measured before and after the test Procedure The sinusoidal vibration test shall be executed in accordance with IEC 60068 2 6 Test Fc Vibration sinusoidal The following level shall be used during the test 10 150 Hz 5 m s 3 axes 20sweep axes 1dB octave Inspections measurements The following parameters shall be tested measured before the test all samples B Radio communication B Bus communication B Ignition B CO measurement B Temperature measurement The following parameters should be tested measured during the vibration 1 sample B Radio communication B CO measurement B Temperature measurement The following parameters should be tested measured after the test all samples B Radio communication B Bus communication
59. figure 16 with due observance of the specific requirements of the aerosol fire extinguishing components regarding outflow dimensions Test procedure Before testing the product must be conditioned and synchronized Evaluation Guideline BRL K21014 04 Kiwa N V 96 June15 2009 The FEC AMS HUB and the fire extinguishing or detection components should be conditioned and synchronized before use The supplier s products are tested for system compatibility detection and extinguishing Furthermore is tested whether driving of the potential free contact for disabling the ventilator is functioning effectively Based on the detection the product should notify the alarming communication and necessary recordings to the AMS The specifications as stated in the supplier s user manual serve as starting point in this Extinguishing should take place as per EN2 class A solids and class B liquids The following boundary conditions apply B The standard fire extinguishing agent SFE should for class A meet the requirements as stated in EGL K23001 B The fire cells consist of fire material TF4 TF7 and TF1 B The fire cell should be placed on the right side on the floor of the cabinet B Above the fire cell the fire extinguishing components should be placed as per the specifications by the supplier with a division as per the supplier s user manual o Ignite the PUR mat sets 1 2 and 3 ina corner with a match o Ignite the methyl
60. ftware design K ii K 6 3 Program monitoring K id X 6 4 Storage of program and data X X 6 5 Monitoring of memory contents X x A X 6 6 Software documentation X K Evaluation Guideline Kiwa N V 61 BRL K21014 04 June15 2009 Nr Subject FEC HUB AMS FEC Standalone 6 7 Operation of the e c d in the event of a system K j X fault 7 Marking K X 8 Documentation X X 9 Tests X i X 9 1 General test requirements X gt 2 X 9 2 Functional tests K i R X 9 3 Environmental tests X iy K 9 4 Damp heat cyclic K id i X 9 5 SO gt corrosion endurance K K 10 Evaluation of conformity K ii K 10 1 General K 3 X 10 2 Initial type testing X i 7 X 10 3 Factory production control X ji A K Appendix Summary of indications X y 4 X A Appendix Clauses addressing the provisions of the EU X 7 K ZA Construction Products Directive 89 106 ECC Not within scope this has been settled elsewhere in the directive Evaluation Guideline Kiwa N V 62 BRL K21014 04 June15 2009 14 Appendix 7 Cross reference EN 54 5 Nr Subject FEC HUB AMS FEC Standalone 1 Scope 7 s 2 Normative references X ii X 3 Definitions and abbreviations X 3 X 4 Requirement
61. gure 7 HUB and AMS HUB Indicator Buzzer Status Behaviour Evaluation Guideline Kiwa N V 22 BRL K21014 04 June15 2009 The optical and acoustic indicators must show a pattern as stated in table 5 Status LED Buzzer behaviour SAFE LED 100ms step m 5 seconds HUB Buzzer KHz Sweep Silent SAFE LED 100ms step Green LED blinks at every radio telegram received AMS HUB Buzzer KHz Sweep AMS HUB is not provided with a buzzer FACTORY LED 100ms step J Buzzer KHz Sweep Silent ERROR LED 100ms step Buzzer KHz Sweep Silent OFFLINE LED 100ms step Buzzer KHz Sweep 4 4 Table 3 HUB and AMS HUB indicator behaviour 2 4 2 Power supply The power supply of the HUB must meet the requirements stated in EN 54 4 1997 AC 1999 and EN 54 4 1997 A1 2002 B The batteries must be replaced according to the supplier s maintenance schedule or when the HUB and or AMS HUB give a low voltage warning B The primary power supply must be obtained from an external transformer 110 V 260 V 50 Hz 60 Hz B The secondary emergency power supply must be composed of gas tight batteries or storage batteries B Malfunctions in the power supply or a low storage battery voltage must be detected by the alarm management system 2 4 3 Radio connection of the HUB The radio connections and system req
62. h i a an 4 L oF Partner for progress Evaluation Guideline for the Kiwa product certificate for aerosol fire extinguishing systems for fire protection in enclosed compartments containing electrical components BRL K21014 04 June 15 2009 Evaluation Guideline for the Kiwa product certificate for aerosol fire extinguishing systems for fire protection in enclosed compartments containing electrical components 2009 Kiwa N V All rights reserved No part of this book may be reproduced stored in a database or retrieval system or published in any form or in any way electronically mechanically by print photoprint microfilm or any other means without prior written permission from the publisher The use of this evaluation guideline by third parties for any purpose whatsoever is only allowed after a written agreement is made with Kiwa to this end Validation This evaluation guideline has been validated by Kiwa on 2009 06 15 Kiwa N V Sir W Churchill laan 273 Postbus 70 2280 AB RIJSWIJK The Netherlands Tel 31 70 414 44 00 Fax 31 70 414 44 20 Summary The requirements mentioned in this Evaluation Guideline BRL are operated by Kiwa when handling a request or upkeep for the Kiwa product certificate EN 45011 for aerosol fire extinguishing systems for fire protection in enclosed compartments containing electrical components aerosol fire extinguishing system The system consist
63. hat frequency the inspection tests will take place 1 5 Acceptance of research reports provided by the manufacturer If the supplier submits reports by test institutions or laboratories as prove that the requirements from the Evaluation Guideline are met it must be proven that these reports are drawn up by an institution that meets the applicable accredited directives namely NEN EN ISO TEC 17025 for laboratories NEN EN ISO TIEC 17020 for test institutions NEN EN 45011 for certification institutions certifying products NEN EN ISO IEC 17021 for certification institutions certifying systems NEN EN ISO IEC 17024 for certification institutions certifying persons WARANA The institution is supposed to meet the reguirements when an accreditation certificate can be submitted that has been granted by the Dutch Council for Accreditation RvA or an accreditation institution with which the RvA has concluded a mutual acceptance agreement This accreditation should relate to the tests required for this Evaluation Guideline If no accreditation Evaluation Guideline BRL K21014 04 Kiwa N V 12 June15 2009 certificate can be submitted the certification institution itself will verify whether the accreditation directives have been met or else carry out or have carried out the tests in question 1 6 Declaration of quality The declaration of quality that is granted based on this Evaluation Guideline are denoted as Kiwa product certif
64. he real life test The FEC that is placed outside of the test cabinet will be provided with a LED indicator in stead of an aerosol extinguishing component in order to demonstrate the driving of the interbus Reaction time Within 120 seconds the fire extinguishing component should activate a fire alarm and an extinguishing Explanation The tests are carried out with stationary extinguishing components based on dry aerosol which are certified conformably to evaluation guideline K23001 Evaluation Guideline BRL K21014 04 Kiwa N V 97 June15 2009 In this evaluation guideline the following performance requirements are stated Performance requirements aerosol fire extinguishing component The aerosol fire extinguishing components must extinguish the objects to be extinguished for the fire class in question in an effective way As a boundary condition for this the aerosol fire extinguishing components must be coupled to and activated by an effective fire alarm extinguishing centre with detection component For this a quick detection and a quick reaction are imperative Extinguishing effectively means that the object to be extinguished after the test does no longer burn and neither will reignite in course of time In order to be able to match the aerosol fire extinguishing components regarding the extinguishing performance with the fire classes as stated in the fields of application The extinguishing components are tested for ev
65. he system is tested and proven in the following dimensioning and projection These dimensioning and projection fall within the scope of the product certificate The number of fire extinguishing components FEC needed for a specific object also determines the projection i e the position and direction in which the FEC s must be mounted When applying 1 FEC it will be placed in the middle of the object on the upper side having the outflow openings pointing to the left and the right Ensure that both outflow openings of the FEC have at least 15 cm of free outflow space in order to prevent damage to equipment The antenna has to be connected to the FEC by means of an antenna extension cord When applying 2 or more FEC s these are placed on the side of the object to be protected having the outflow openings pointing upwards and downwards Ensure that both outflow openings of the FEC have at least 15 cm of free outflow space in order to prevent damage to equipment When applying more than 1 FEC in a cabinet these must be linked by means of a bus connection The FE is tested under following conditions to determine if detection is within the requirements of guideline BRL K21014 The following conditions have been used e TF1 wood crib source 7 according to BS 5852 2 1990 e TF4 polyurethaan mats comparable with NEN 2535 1996 and EN 54 7 2000 e TF7 methylated spirit 85 comparable with NEN 2535 1996 e TF10 print with 5 resistors comparable with
66. icate granted to the certified supplier A model of this declaration of quality is provided as an appendix to this Evaluation Guideline This is a combination of a testimonial and a product certificate based on the following definitions Testimonial a document in which Kiwa declares that the properties of a product or a building part are supposed to meet the performance requirements recorded in the Evaluation Guidelines applying for that product or building part provided that B The products and materials applied in the product or building part meet the specifications stated in the testimonial B The working instructions stated in the testimonial are applied R The application conditions stated in the testimonial are heeded Product certificate a document in which Kiwa declares that on delivery a product or building part is supposed to meet the product specification as recorded in the product certificate Evaluation Guideline BRL K21014 04 Kiwa N V 13 June15 2009 2 Performance requirements 2 1 General These chapters describe the performance requirements that the components of the aerosol fire extinguishing system must meet Furthermore determination methods are included which can be used to determine whether the requirements are met 2 2 Description and structure of the system The aerosol fire extinguishing system must be able to detect a starting fire in the environments mentioned communicate an alarm signal to
67. ient bursts K K K K 9 12 Voltage transients slow high energy K K K K transients 9 13 Mains voltage dips and interruptions K K K K 9 14 Supply voltage variation K K K K 9 15 Damp heat steady state K K K K 9 16 Vibration sinusoidal K K K K Appendix Special national condition X X X X A Appendix Clauses of this European Standard X X X X ZA addressing essential requirements of the Construction Products or other provisions of EU Directives Appendix Procedure for monitoring of the battery X X X X B internal resistance required Not within scope this has been settled elsewhere in the directive Evaluation Guideline Kiwa N V 60 BRL K21014 04 June15 2009 13 Appendix 6 Cross reference EN 12094 1 Nr Subject FEC HUB AMS FEC Standalone 1 Scope x i 25 Normative references K pil z X 3 Terms definitions and abbreviations X z X 3 1 Definitions X F 5 X 3 2 Abbreviations X K 4 Functional requirements K X 4 1 General X 3 X 4 2 Environmental class X ig X 4 3 Signal processing and indication X i j X 4 4 Reception and processing of input triggering i il 7 signals 4 5 Transmission of extinguishing signal K 3 X 4 6 Activation of alarm devices ii 3 4 7 Indication of the supply of power K K 4 8 Activated condit
68. ification requirements The following qualification requirements have been set up by the Board of Experts for regarding the subject of this Evaluation Guideline Certification personnel Education Experience Certification expert Higher level of professional education 3 year Electrical engineering or equivalent Internal training certification and Kiwa policy Audit training Projection expert fire alarm systems ISE or equivalent Knowledge of EGL K21014 and EGL K23001 Inspectors Intermediate level of professional education 3 year e Electrical engineering or equivalent e Internal training certification and Kiwa policy e Audit training e Knowledge of EGL K21014 and EGL K23001 Decision makers Higher level of professional education 5 year management e Engineering or equivalent experience e Internal training certification and Kiwa policy Table 11 Qualification requirements Proof of the level of education and experience of personnel involved must be recorded 6 3 Frequency of external inspections audits At the time this Evaluation Guideline takes effect the frequency has been set at two inspection visits audits per year per product location Evaluation Guideline BRL K21014 04 Kiwa N V 41 June15 2009 7 List of documents stated 7 1 Public law regulations The following legal decrees apply to this product 2006 95 EG Low Voltage Directive 2006 99 5 EG Radio amp Telecommunication Terminal
69. in principal the requirements stated in EN 54 5 2001 and correction sheet EN 54 5 Design A1 2002 Deviations from these are Evaluation Guideline BRL K21014 04 Kiwa N V 20 June15 2009 B The detection component is a point detector with decentralized intelligence with a multi sensor detecting gas CO and heat CO detection is differentially Alerts can explicitly reset by the custodian responsible Temperature detection is differentially as well as absolute The temperature detector complies with class A1 of EN 54 5 2001 For this the ambient temperature is 25 C the maximum ambient temperature 50 C and the alarm temperature 54 C B The detection values for an alert to the user are o Increase of the CO value by 20 ppm per minute or o Increase of the temperature by 2 C per minute or o Reaching the temperature of 50 C B The detection values for an extinguishing alarm are o Increase of the temperature by 5 C per minute or o Reaching the temperature limit of 54 C or o Increase of the temperature by 2 C per minute combined with an increase of the CO value by 20 ppm per minute B The aerosol fire extinguishing component must have a delaying time of 10 seconds after detection of a fire before activation of the aerosol fire extinguishing component This is among other things for disabling and stopping ventilation provisions WERNA Determination method The determination method is described in appendix
70. ion is 4 9 Indication of activated condition X i X 4 10 Released condition X X 4 11 Indication of the released condition X X 4 12 Resetting of the activated condition and the X Hi i X released condition 4 13 Fault warning condition X id j X 4 14 Indication of fault warning condition X gt K 4 15 Disabled condition K ii 7 X 4 16 Indication of disabled condition X i X 4 17 Delay of extinguishing signal i ji 4 18 Signal representing the flow of extinguishing a ii agent 4 19 Monitoring of the status of components 2 ig S 4 20 Emergency hold device ii 7 z 4 21 Control of flooding time i 5 4 22 Initiation of secondary flooding g 4 23 Manual only mode i 3 4 24 Triggering signals to equipment within the system X id ii K 4 25 Extinguishing signals to spare cylinders ki i i 3 4 26 Triggering of equipment outside the system X ii A K 4 27 Emergency abort device 3 4 28 Control of extended discharge ji i 4 29 Release of the extinguishing media for selected s ii K flooding zones 4 30 Activation of alarm devices with different signals id ig id 5 Design requirements K K 5 1 General K X 5 2 Mechanical design X i i X 5 3 Manual control X a X 5 4 Visible indicators X i X 5 5 Audible indicators X i z X 5 6 Electrical design of components X ii 7 X 5 7 Circuit design X i X 6 Additional design requirements for software X ii i X controlled e c d s 6 1 General X ig K 6 2 So
71. le indication X jd K K 7 5 Other indications during the fire alarm K X X condition 7 6 Reset from the fire alarm condition X J K K 7 7 Output of the fire alarm condition K 3 K K 7 8 Output to fire alarm devices K a K K 7 9 Control of fire alarm routing equipment X k 7 9 1 Output to fire alarm routing equipment iji iji 792 Input from fire alarm routing equipment i z 2 ij 7 10 Output to fire protection equipment s 3 7 10 1 Output type A x ii 7 10 2 Output type B S 4 7 10 3 Output type C ie ji 7 10 4 Fault monitoring of fire protection z a equipment 7 11 Delays to output K X 7 12 Dependency on more than one alarm signal X X X ii 7 12 1 Type A dependency K t X f 7 12 2 Type B dependency X X j 7 12 3 Type C dependency X i X 7 13 Alarm counter z i 8 Fault warning condition K i X X 8 1 Reception and processing of fault signals X K K 8 1 1 Fault warning condition i K K 8 1 2 Capable of simultaneously recognizing ii X X X 8 1 3 Fault warning condition in 100 s A X z 8 2 Indication of faults X i X X 8 3 Fault signals from points X ii K K 8 4 Total loss of the power supply K ii K 8 5 System fault X X X 8 6 Audible indication X Ki K K 8 7 Reset of fault indications K x X X 8 8 Fault output X 3 K K 8 9 Output to fault warning routing equipment K i X X 9 Disabled condition X X X 9 1 General requirements K ii K K 92 Indication of the disabled condition K iji K K 9 3 Indication of specific disab
72. lements K 3 X X 9 4 Disablements and their indication X i X X 9 5 Disablement of addressable points 10 Test condition A 10 1 General requirements Zi i 10 2 Indication of the test condition X a K i Evaluation Guideline Kiwa N V 58 BRL K21014 04 June15 2009 Nr Subject FEC HUB AMS FEC Standalone 10 3 Indication of zones in the test state X i 11 Standardized input output interface a ii 12 Design requirements K K K 12 1 General requirements and manufacturers K z X X declarations 12 2 Documentation X X X X 12 3 Mechanical design requirements X Hi K K 12 4 Electrical and other design requirements K is K K 12 5 Integrity of transmission paths K i X X 12 6 Accessibility of indications and controls X K K 12 7 Indications by means of light emitting K ki K K indicators 12 8 Indications on alphanumeric displays K X 12 9 Colours and indications X i X X 12 10 Audible indications X X X 12 11 Testing of indicators X X X 13 Additional design requirements for X X X software controlled control and indicating equipment 13 1 General requirements and manufacturers X 3 X X declarations 13 2 Software documentation X i X X 13 3 Software design X 7 K K 13 4 Program monitoring K X X 13 5 The storage of programs and data X x X X 13 6 The m
73. mance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed Degrees of protection provided by enclosures IP Code FEC and HUB Purpose The purpose of this method is to determine the ingress of solid parts and rain water into the device Amount of samples The test should be executed with 3 samples Procedure The impact protection test shall be executed in accordance with IEC 60529 Degrees of protection provided by enclosures IP Code The following levels shall be used during the test B IP30 Apparatus The protection against sold objects shall be executed with appropriated test pins The protection against water shall be executed with an appropriated dripping box Inspections measurements The following parameters shall be tested measured before the test s all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DWDDDADW The following parameters should be tested measured after the test inside 2 hours all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DWDDDW Acceptance criteria The device is considered to have passed the test if the entire test popula
74. munication equipment is usually provided by the alarm receiving station Evaluation Guideline BRL K21014 04 Kiwa N V 14 June15 2009 The figure below shows an overview of the aerosol fire extinguishing system Backup Radio communication communication standard 802 15 4 2 4GHz route Y 4 HUB gA 4 NO aa AMS HUB NY am LCD Display Buttons seria HUB AMS Indicators buzzer cable Modem Figure 1 System overview E FEC s FEC Hedtrial interface y Communicatieon equipment in mpliance with piN54 13 2001 EN54 18 2003 and EN54 21 2004 4 Notificatim PACor building cu odi an Figure 2 Overview FEC standalone use Explanation The system consists of products which must meet public law regulations including the Low Voltage Directive LVD 2006 95 EG the Radio amp Telecommunication Terminal Equipment Directive R amp TTE 1999 5 EG the Electromagnetic Compatibility Directive EMC 89 336 EEG resp 2004 108 EG the Construction Products Directive CPD 89 106 EG Below an overview is given of the set up of the directives In the appendices mentioned is stated which parts of the directives apply and which parts are excluded The chapters 2 3 2 4 en 2 5 state supplementary requirements regarding the directi
75. n device X 4 5 12 3 Thermal ignition device X ig 5 13 Function reliability K j j 5 14 Open fire conditions X ig 5 15 Accessories X 5 16 Documentation X j 6 Marking X 7 Test methods X x 7 1 Conditions K ii L2 Samples X Si 7 3 Conformity K z i 7 4 Extinguishing factor determination X 7 5 Coverage determination X ii 7 6 Discharge time test X is 7 7 Temperature and humidity operation range tests K id i 7 7 1 Object of the test K ii i 7 7 2 Test procedure K t 7 7 3 Low temperature Test X ig i 7 8 Accelerated ageing test K 7 8 1 Test time X 7 8 2 Test procedure K i 7 9 Corrosion test X 7 10 Stress corrosion test K ji ii 7 11 Vibration test K jal A 7 12 Impact test X ig Evaluation Guideline Kiwa N V 56 BRL K21014 04 June15 2009 Nr Subject FEC HUB AMS 7 12 1 Test procedure K is 7 12 2 Test apparatus K ii i 7 13 Drop test K ii 2 7 13 1 Impact surface X E 7 13 2 Procedure X 3 7 13 3 Requirements X 5 7 14 Casing and aerosol flow temperatures test K ii 7 14 1 Casing temperature test X 7 7 14 2 Aerosol flow temperature test X ig ki 7 15 Ignition performance test X ig 7 16 Function test K iji ji 7 16 1 Discharge time K 7 16 2 Aerosol flow temperatures X 7 16 3 Test procedure K ii 7 16 4 Casing temperature test X 7 3 7 16 5 Discharged mass X F
76. n the upper side having the outflow openings pointing to the left and the right Ensure that both outflow openings of the FEC have at least 15 cm of free outflow space in order to prevent damage to equipment Since the antenna always has to point upwards the antenna has to be connected to the FEC by means of an antenna extension cord When applying 2 or more FEC s these are placed on the side of the object to be protected having the outflow openings pointing upwards and downwards Ensure that both outflow openings of the FEC have at least 15 cm of free outflow space in order to prevent damage to equipment When applying more than 1 FEC in a cabinet these must be linked by means of a bus connection min 150mm min 150m UT L IT AT E AT TRE lt 7 a A 1000mm Evaluation Guideline BRL K21014 04 Kiwa N V 100 June15 2009 a Lo o F Evaluation Guideline BRL K21014 04 Kiwa N V 101 June15 2009
77. nd more than one signal to the fire alarm station through signal processing and software determined algorithms Signal processing can take place in the alarm devices as well as in the fire alarm station or a combination of both B Non enterable room A room which cannot be entered by human beings because of its dimensions or other physical limitations such DDD DD Dw Evaluation Guideline BRL K21014 04 Kiwa N V 10 June15 2009 as shallow cabinets B Notification equipment for fault warnings Interface equipment for notifying a fault warning error message from the AMS to a fault warning receiving station B Notification equipment for fire alarms Interface equipment for notifying an alarm message from the AMS to a fire alarm receiving station B Object protection Object protection is a protection volume that protects a certain object in a room e g switch cabinets machines with automatic fire alarm devices B Point detector An alarm device that reacts to a perceived fire phenomenon in or near a sensor that has been fixed at a certain location B Power supply The electrical power supply for the AMS and for those parts that are supplied through the AMS fire alarm equipment comprises a primary and secondary power source as described in EN 54 4 PLC Programmable Logic Controller Receiving station for fire alarm messages An organisation institution from where at any time the necessary fire fighting and
78. nd test methods for electrical automatic control and delay devices IEC 60068 1 1 Basic Environmental testing procedures 1998 Part 1 general and guidance 1998 A1 1992 IEC 60068 2 1 Environmental testing Part 2 1 Tests Tests A Cold inclusive correction 1990 document IEC 60068 2 2 Basic environmental testing procedures Part 2 2 Tests Tests B Dry Heat d 1974 inclusive correction document IEC 60068 2 6 Environmental testing Part 2 6 Tests Tests A Fc Vibration sinusoidal inclusive 1996 correction document IEC 60068 2 27 Environmental testing Part 2 27 Tests Tests Ea Shock 1987 IEC 60068 2 30 Environmental testing Part 2 30 Tests Tests Db and guidance Damp heat cyclic 1980 IEC 60068 2 32 Environmental testing Part 2 32 Tests Tests Ed Free Fall 1993 IEC 60068 2 42 Environmental testing Part 2 42 Test methods Tests Kc Sulphur dioxide test for 2002 contacts and connections IEC 60068 2 75 Environmental testing Part 2 75 Tests Tests Eh Hammer Test 1997 IEC 60068 2 78 Environmental testing Part 2 78 Tests Tests Cab Damp Heat steady state 2001 IEC 61340 5 2 Electrostatics Part 5 2 Protection of electronic devices from electrostatic 2001 phenomena User guide EN 2 Fire classes 1994 Remark 2 The prEN 54 25 refers to the following directives regarding radio communication e EN 300113 1 V 1 4 1 2002 Electromagnetic compatibility and Radio spec
79. ndications by means of light emitting ki K indicators 7 8 Colours of indicators X 79 Tests of indicators is K 7 10 Additional design requirements for software d a X i controlled routing equipment 8 Marking X J 9 Power supply id K 10 Test reguirements x X 10 1 General test requirements il 7 K 10 2 Functional test K 10 3 Environmental tests i K E 10 4 Cold z 7 K 10 5 Damp heat steady state id K 10 6 Impact 5 i K k 10 7 Vibration sinusoidal i X 10 8 Electromagnetic compatibility EMC Immunity 7 K 7 tests 10 9 Supply voltage variation K 10 10 Damp heat steady state i K 10 11 Vibration sinusoidal il X iii Appendix A Performance requirements for alarm and fault x X warning transmission systems Appendix B Verification of performance requirements for ii K i alarm and fault warning transmission systems Appendix Clauses addressing the provisions of the EU i 7 X s ZA Construction Products Directive 89 106 ECC Not within scope this has been settled elsewhere in the directive Evaluation Guideline Kiwa N V 69 BRL K21014 04 June15 2009 20 Appendix 13 Cross reference UL 827 N B This matrix is no longer applicable Evaluation Guideline BRL K21014 04 Kiwa N V 70 June15 2009 21 Appendix 14 Environmental Reliability test Fire Extinguisher The network consists of FEC s HUBs and an AMS HUB The FEC sends information to
80. nnel for response time ii i and response temperature measurements Appendix B informative Information concerning the i ip i construction of the heat tunnel Appendix C informative Derivation of upper and lower K 4 limits of response times Appendix D informative Apparatus for impact test K X Not within scope this has been settled elsewhere in the directive Evaluation Guideline BRL K21014 04 Kiwa N V 63 June15 2009 15 Appendix 8 Cross reference ISO 7240 6 Nr Subject FEC HUB AMS FEC Standalone 1 Scope a x 2 Normative references K i i X 3 Terms definitions and abbreviations X i X 4 General requirements X bs k X 4 1 Compliance X 3 X 4 2 Individual alarm indication ul 4 3 Connection of ancillary devices K X 4 4 Monitoring of detachable detectors X ii K 4 5 Manufacturer s adjustments K i j X 4 6 On site adjustment of response behaviour X ii X 4 7 Rate sensitive response behaviour x 3 4 8 Marking X X 4 9 Data X X 4 10 Requirements for software controlled detectors X gt X 5 Tests X i t X 5 1 General X iy 7 K 5 2 Repeatability K id K 5 3 Directional dependence K z X 5 4 Reproducibility X ii A X 5 5 Cross sensitivity X z s X 5 6 Long term stability X i X 5 7 Saturation K z X 5 8 Expos
81. nspection NEN 3011 Safety colors and safety signs 1986 NEN 5509 User manuals Content structure formulation and presentation 1998 CEI IEC 62079 Preparation of instructions structure ring content and presentation 2001 IEC 60529 Consolidated Edition Degrees of protection provided by enclosures 2001 IP Code Applies to the classification of degrees of protection provided by enclosures for electrical equipment with a rated voltage not exceeding 72 5 kV Has the status of a basic safety publication in accordance with IEC Guide 104 NEN EN 54 2 Fire detection and fire alarm systems 1999 Part 2 Control and indicating equipment including correction document NEN EN 54 4 Fire detection and fire alarm systems 1999 Part 4 Power supply equipment including correction document NEN EN 54 5 Fire detection and fire alarm systems 2001 Part 5 Thermal alarm devices Point detectors PrNEN EN 54 13 Fire detection and fire alarm systems 2001 Part 13 Compatibility of system components PrNEN EN 54 18 Fire detection and fire alarm systems 2003 Part 18 Input output devices PrNEN EN 54 21 Fire detection and fire alarm systems 2004 Part 21 Alarm transmission and fault warning routing equipment PrNEN EN 54 25 Fire detection and fire alarm systems 2005 Part 25 Components using radio links and system requirements NEN EN 12094 1 Fixed fire fighting systems Components for gas extinguishing systems 2003 Part 1 Requirements a
82. nt position and certified supplier of the component 4 5 1 Risk inventory and risk evaluation of the product The certified supplier must have and keep up a risk inventory and risk evaluation of critical points B inthe assembly process B in application of the various components Based on this analysis quality cards should be available with critical assembly points The analysis and quality cards should be detailed further based on deviations recorded during the production process During the inventory spurious and or false alarms by the system should be taken into account and should be at an accepted level 4 5 2 Production provisions Assembly should take place at a location that is protected against the negative influence of electrostatic discharge to the product Evaluation Guideline BRL K21014 04 Kiwa N V 36 June15 2009 4 5 3 Archive management quality registries traceability The quality registries should be kept in archive for at least 5 years The registries should enable complete unique identification of components and systems as well as traceability of components and systems 4 6 Procedures and working instructions The certified supplier must be able to submit B procedures for handling non conforming products corrective actions to be taken if non conformities are observed dealing with complaints regarding product deliveries and or services B working instructions and inspection reports in use 4 6 1
83. of fire extinguishing components Evaluation Guideline BRL K21014 04 Kiwa N V 34 June15 2009 Installation B Is able to install an aerosol extinguishing system B Is able to install signal repeaters B Is able to translate the basic principles of electrical engineering into practice B Is able to draw up an Acceptance Report B Knows how to interpret the certified supplier s user manual Putting into operation B Is able to put an aerosol extinguishing system into operation Acceptance Is able to carry out acceptance of an aerosol extinguishing system Is able to draw up an Acceptance Report Is able to draw up a log book Is able to instruct the customer in use of the aerosol extinguishing system WARREN Maintenance B Is able to maintain an aerosol extinguishing system in compliance with the specifications that apply B Is able to fill out a log book B Is able to draw up a Maintenance Report 4 4 3 Exam requirements Evaluation of the exam is done by determining the number of correctly answered questions The exam consists of 40 multiple choice question and assessment of usage of the Radio Network Analyser The examinee is entitled to a personal certificate if at least 27 multiple choice questions have been answered correctly and the examinee has proven to master the use and data interpretation of the Radio Network Analyser The exam is compiled by Kiwa Certification and Inspections based on the questions available in
84. on Products Directive The description of the directives is stated below e ETSI EN 300 440 1 V1 3 1 2001 09 Electromagnetic compatibility and Radio spectrum Matters ERM Short range devices Radio equipment to be used in the 1 GHz to 40 GHz frequency range Part 1 Technical characteristics and test methods e ETSI EN 300 440 2 V1 1 2 2004 07 Electromagnetic compatibility and Radio spectrum Matters ERM Short range devices Radio equipment to be used in the 1 GHz to 40 GHz frequency range Part 2 Harmonized EN under article 3 2 of the R amp TTE Directive APPLICATION AND USE Application conditions 5 The user must manage the system conformably to his training 1 The number and or types of the extinguishing components to be used and to the manual must be installed conformably to the directives and calculation methods of the installer 2 A delivery user manual should be supplied 3 For product use instructions should be given by a certified product trainer who is certified by the installer 4 Maintenance of the fire extinguishing components should be carried out as per the installer s specifications TIPS FOR THE CUSTOMER 1 Inspect on delivery 3 For the correct way of storage and transport please consult 1 1 whether everything has been delivered as agreed the handling guidelines by the manufacturer 1 2 whether the activities carried out show no visual shortcomings 4 Check whether this certificate is still valid by c
85. on and Maintenance X b Instruction Manual Not within scope this has been settled elsewhere in the directive Evaluation Guideline Kiwa N V 55 BRL K21014 04 June15 2009 Appendix 3C Cross reference CEN TR 15276 1 Nr Subject FEC HUB AMS 1 Scope X a 2 Normative references X 3 Terms and definitions X i jj 4 Component requirements X S s 4 1 Condensed aerosol generator X 4 2 Solid aerosol forming compound X j 4 3 Cooling mechanism X k ii 44 Ignition device K j s 4 4 1 General X 4 4 2 Electrical ignition device K F 443 Thermal ignition device K 4 4 4 Other methods of ignition device X 2 g 4 5 End plate and housing X ig f 4 6 Extinguishants X ii 5 Condensed aerosol generators requirements K ij 5 1 General X j 5 2 Extinguishing factor X 4 ii 5 3 Agent distribution K t 5 4 Discharge time X i 5 5 Ambient temperature and humidity operation X s ranges 5 6 Service life X iji 5 7 Shelf life and storage conditions K 5 8 Corrosion X 5 9 Vibration X r il 5 10 Mechanical shock X ii x 5 11 Discharge temperature X ja jl 5 11 1 General X 7 5 11 2 Casing temperature X ii 5 11 3 Aerosol flow temperature X f 5 12 Ignition device X k 5 12 1 General X x 5 12 2 Electrical ignitio
86. one or more HUBs The HUB amplifies the signal and sends it to the next HUB The AMS HUB receives all information and sends the information by means of a serial cable 21 1 Environmental Reliability tests FEC HUB AMS and FEC standalone The fire detector and extinguisher should work reliably in different environments The following table gives an overview of all reliability tests Directive Test Test level TEC 60068 2 1 Tests A Cold 100C 2 C 16 hours IEC 60068 2 2 Tests B Dry heat 60 C 2 C 16 hours IEC 60068 2 6 Test Fc Vibration sinusoidal endurance 10 150 Hz 5 m 2 3 axes 20 sweep axes 1dB octave TEC 60068 2 27 Test Ea Shock Half sine 6ms 10x 100 20M m s M mass of device TEC 60068 2 30 Test Db Damp heat cyclic 250C 20C gt 95 RH lt gt 409C XC 93 RH 3 2 cycles TEC 60068 2 32 Test Ed Free fall 2m 6 sides 4 corners 2x TEC 60068 2 42 Test Kc Sulphur dioxide test for contacts and connections 259C 2 C 93 RH 3 25 5 vol ppm 21 days TEC 60068 2 75 Test Eh Hammer tests 1 5 0 13 m s IEC 60068 2 78 Test Cab Damp heat steady state 40 C 20C 93 RH 2 3 21 days TEC 60529 Degrees of protection provided by enclosures IP Code IP 30 Table 13 Environmental tests FEC HUB and AMS HUB Evaluation Guideline Kiwa N V 71
87. onitoring of memory contents X X X 13 7 Operation of the control and indicating X i X X equipment in the event of a system fault 14 Marking X 5 K K 15 Test K X X 15 1 General X i X X 15 2 Functional test X X X 15 3 Environmental tests X i X X 15 4 Cold X i X X 15 5 Damp heat steady state X X X 15 6 Impact X S X X 15 7 Vibration sinusoidal X X X 15 8 Electrostatic X X X X 15 9 Radiated electromagnetic interference X X X 15 10 Voltage transients fast transient bursts X X X 15 11 Voltage transients slow high energy X X X transients 15 12 Mains voltage dips and interruptions X X X 15 13 Supply voltage variation X ip K K 15 14 Damp heat steady state endurance K ii K K 15 15 Vibration sinusoidal endurance K K K Appendix Explanation of access levels K 7 K K A Appendix Optional functions with requirements and K K K B alternatives Appendix Processing of signals from fire detectors K K K C Appendix Explanation of zones and the zone indication s D of fire alarms Appendix Delays to output 7 gt E Appendix Fault recognition and indication K j X X F Appendix Standardized input output interface for the X i X X G connection of ancillary equipment Appendix Integrity of transmission paths X i X X H Not within scope this has been settled elsewhere in the directive Evaluation Guideline Kiwa N V 59 BRL K21014 04 June15 2009 12 Appendix 5 Cro
88. onsulting 2 If based on the afore mentioned you decide to reject please Kiwa website www kiwa nl and searching for certified contact companies under guideline BRL K21014 21 EBAH and if necessary 2 2 KiwaN V Evaluation Guideline BRL K21014 04 Kiwa N V 49 June15 2009 9 Appendix 2 IQC scheme Inspection subjects Inspection Inspection Inspection Inspection aspects method frequency registration Raw materials or supplied materials B Product composition B Recipe sheets B Entrance inspection raw materials Production process B Procedures B Working instructions B Equipment B Material End products B a o statistic process inspection as per 1502859 Measuring and test eguipment B Measuring means B Calibration Logistics B Internal transport Storage Packaging Preservation DnDD DV Identification or marking of semi finished and end products Table 12 IQC scheme The IQC scheme is drawn up by the certified supplier and set by the Certification Institution Evaluation Guideline BRL K21014 04 Kiwa N V 50 June15 2009 10 Appendix 3 Cross reference aerosol Evaluation Guideline BRL K21014 04 Kiwa N V 51 June15 2009 Appendix 3A Cross reference BRL K23001
89. ortance of a Program of Requirements B Knows the importance of frequency measurements Detailed design B Knows the concept and importance of an installation plan B Knows the importance of calculating the amount of extinguishing agent needed for a compartment B Knows the right projection of fire extinguishing components Installation Knows the concept and importance of a correct installation Knows how to handle signal repeaters Knows the basic principles of electrical engineering Knows the concept and importance of an Acceptance Report Knows the certified supplier s user manual DUDDA Putting into operation B Knows the concept and importance of putting into operation Acceptance B Knows the concept and importance of acceptance B Knows the concept and importance of an Acceptance Report B Knows the concept and importance of a log book B Knows the importance of instructing the customer in use of the aerosol extinguishing system Maintenance B Knows the concept and importance of maintenance as per the specifications that apply B Knows the importance of correct filling out of the log book B Knows the concept and importance of a Maintenance Report 4 4 2 Test terms Each end term has been translated into test terms The scheme below shows the test terms for each end term Legislation and regulations B Can explain what an Evaluation Guideline is B Can name the main issues in the EGL BRL K23001 and K21014 B Can state
90. parts into the device Amount of samples The test should be executed with 1 sample Procedure The ingress protection test shall be executed in accordance with IEC 60529 Degrees of protection provided by enclosures IP Code The following levels shall be used during the test R IP30 Apparatus The protection against sold objects shall be executed with appropriated test pins Inspections measurements The following parameters shall be tested measured before the test LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DNDDNDDDA WwW The following parameters should be tested measured after the test LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DWDDDDAW Acceptance criteria It should be taken care of that no dangerous situations can arise during insertion of the test pin The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable LEDs and display test still working Button test still working Buzzer test still working Serial communication to AMS HUB still working Modem communication still working Switching of relays still working DWDDDD DW Evaluation Guideline BRL K21014 04 Kiwa N V 91 June15 2009 22 1
91. perature change inside the 3 hours duration The samples should be placed in a dry environment after the test 20 C 500 Inspections measurements The following parameters shall be tested measured before the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DNDDnDDW The following parameters should be tested measured during the test B Radio communication B COmeasurement B Temperature measurement Evaluation Guideline BRL K21014 04 Kiwa N V 80 June15 2009 The following parameters should be tested measured between 4 and 24 hours after the test Radio communication Bus communication Ignition CO measurement Temperature measurement WARANA Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working B Bus communication still working B Ignition still working B CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 40C are allowed 21 9 Sulphur dioxide test for contacts and connections FEC and HUB Purpose The sulphur dioxide test will be carried out to stimulate corrosion especially on contacts and connections Corrosion can
92. polyurethane mats Shape Open cell structure flexible artificial foam Colour Variable Thickness Approx 17 20 kg m Water solubility Not soluble Decomposition temperature gt 180 C Ignition temperature gt 400 C Stability and reactivity The product is stable within a temperature range from 40 C to 80 C Keep ignition sources away Fire material TF7 Methylated spirit 85 in a round bowl of 15 cm diameter and 5 cm deep Filled with 150 cl methylated spirit Fire material TF1 wood crib In cubic shape piled beech Fagus Silvatica wood crib ignited by means of 10 cl methylated spirit in a cup at the bottom centre of the piled cube Dimensions of the 4 x 5 piled wood crib are 80 mm x 10 mm x 10 mm on clean aluminium foil Moisture percentage of the wood crib lt 10 Equipment The complete product of the supplier with equipment for detection alarming and communication Measuring equipment from the test laboratory in order to register the parameters temperature air humidity CO value etc during the test as stated in table 18 A fire box of non inflammable material with approximate dimensions to the mats will be placed on two rests of non inflammable material in order to isolate the test fire from the ground floor Test setup The inflammable material is placed below on the right side of test cabinet The fire extinguishing components will be placed left middle and right at the top of the test cabinet see
93. projection The product certificate should show the standard projection proper for the system The tests can also be carried out for other cabinets with obviously deviating dimensions These tests will then be conclusive for the standard projection belonging to this projection and should be stated as such in the product certificate Evaluation Guideline BRL K21014 04 Kiwa N V 92 June15 2009 Poog 5 g T S 8 3 E S lt oz Sj S 270 00 00 004 00 004 00 08 00 0091 Evaluation Guideline BRL K21014 04 Kiwa N V 93 June15 2009 22 2 TF9 Evaluation of reference framework CO sensor detection General The purpose of this test is to determine the algorithm of the CO sensor Equipment Gas container with gauge gas of 30 ppm Enclosed glass room of 10 litres with at the bottom a closed supply pipe and on the upper side a lockable venting Stopwatch Test setup The fire extinguishing component will be placed in an enclosed room of 10 litres to which a reference gas is supplied directly Amount During 1 minute the reference gas of 30 ppm is supplied Test procedure Before testing the product must be conditioned and synchronized The reference gas should fill the housing within 1 minute Reaction time Within 1 minute the alert alarm should be activated 22 3 TF10 Test fire with five resistors detection General
94. rage Temperature 20 C to 40 C 20 C to 50 C 20 C to 50 C Air humidity 25 to 75 RH 25 to 75 RH 25 to 75 RH Air pressure 86 to 106kPa 86 to 106kPa 86 to 106kPa Transport during a maximum of 24 hours Temperature 35 C to 50 C 35 C to 85 C 35 C to 85 C Air humidity lt 95 RH lt 95 RH lt 95 RH Air pressure 86 to 106kPa 86 to 106kPa 86 to 106kPa no condensation The hardware is supposed to operate up to 60 C Table 1 Conditional requirements The parts of the system should have been developed as per IEC 60721 3 1 and IEC 60721 3 2 and tested as per IEC 60721 4 1 and IEC 60721 4 2 in order to be stored or transported without changing the properties or life time 1 3 Terms and abbreviations The following definitions are used in this Evaluation Guideline B Alarm management system AMS The part that offers information on the fire extinguishing components connected and that initiates the necessary actions as per this Evaluation Guideline B Alphanumeric display An optical indicator that offers information by displaying messages consisting of alphanumeric characters digits and letters B AMS HUB Radio Interface controlling communication between AMS HUB and FEC B AQL Accepted quality level B BRL EGL BRL is the abbreviation for Beoordelingsrichtlijn which is Dutch for Evaluation Guideline B CO Carbon monoxide B Communication equipment Equipment such
95. rantees that faults are solved within 24 12 or 6 hours then an emergency power capacity will suffice of at least 24 12 or 6 hours of which at least 30 minutes in alarm status Evaluation Guideline BRL K21014 04 Kiwa N V 24 June15 2009 2 5 1 1 Operational statuses Figure 8 and table 4 show the behaviour of operational statuses and the optical and acoustic indicators of the AMS eo POWER SUPPLY ON 66 a MAINTENANCE ON OPERATIONAL NERT MAINTENANCE OFF All FECs HUBs FIRE ALARM MAINTENANCE ON and AMS are in SAVE state Start interruption TIMER ALERT All AMS FECs and HUBs SAFE FIRE ALARM No ALERT but ERROR Start interruption TIMER FIRE ALARM Interruption TIMER concluded or ____ EXTINGUISHING ACTIVATED FIRE ALARM A AMS RESET BUTTON PUSHED EXTINGUISHING ACTIVATED Start interruption TIMER _ New EXTINGUISHING BUZZER OFF ACTIVATED EXTINGUISHING hae Figure 8 AMS Indicator Status Behaviour The green LED indicator on the front panel is always on to indicate that the power supply to the AMS is on Table 4 shows the various LED patterns that may be active depending on the current status Status LED Buzzer behaviour ERROR LED 100ms step Buzzer KHz Sweep 5 5 ALERT LED 100ms step Buzzer KHz Sweep 5 5 5 5 F
96. ring its composition consisted of the following members Mr F C Koelewijn RVK NOFIQ Systems B V Mr J W M Geraerts De Goudse Verzekeringen Mr A H A Adrichem Hannover Risks Consultants Mr ing M Gerbers Astron Mr G M de Groot De Groot Installatiegroep B V Mr ir R J van Geer SPIRID Creation B V Mr ir M Wittenberg SPIRID Creation B V Mr drs ir A van Ardenne AstroTec Mr ing E Hommes AstroTec Mr P E Voshol Kiwa Certification and Inspection secretary Mr R G C Reijns FSB Mr B Sc E E J Schuurmans TNO Electronic Products and Services Mr P de Beer TNO Electronic Products and Services Mr M Steffens BAM Techniek This Committee is also in charge of execution of certification and makes adjustments to this Evaluation Guideline if necessary This Evaluation Guideline will be applied by Kiwa together with the Kiwa Regulations for Product Certification in which all Kiwa s general certification rules are recorded This Evaluation Guideline aims to guarantee based on the current technical state an acceptable level of fire protection in order prevent or control damage to human beings and goods Evaluation Guideline BRL K21014 04 Kiwa N V 3 June15 2009 1 1 1 2 13 1 4 15 1 6 2 2 2 23 2 4 2 5 3 1 3 2 3 3 3 4 3 5 3 6 3 7 4 1 4 2 4 3 4 4 4 5 4 6 4 7 4 8 4 9 Contents Int
97. roduction General Scope Terms and abbreviations Requirements and determination methods Acceptance of research reports provided by the manufacturer Declaration of quality Performance requirements General Description and structure of the system Performance requirements of the components o o v 12 12 13 14 14 14 17 Performance requirements signal repeater HUB and radio interface AMS HUB 22 Performance requirements alarm management system AMS Product requirements General Environmental requirements Manual Quality structure Software identification Packaging preservation storage identification Certification mark Quality system requirements General Custodian of the quality system Organisation and personnel Requirements training courses Internal quality control quality plan Procedures and working instructions End inspection production Other requirements to the quality system Subcontracting of activities 24 27 27 28 28 28 29 30 30 31 31 31 31 31 36 37 37 38 38 Evaluation Guideline Kiwa N V 4 BRL K21014 04 June15 2009 4 10 4 11 5 5 1 5 2 5 3 6 6 1 6 2 6 3 7 Al 7 2 8 9 10 Legal liability Storage and treatment Summary of tests and inspections Inspection matrix Changes in design Inspection of the quality management system Requirements to certification institutions General Certification personnel Frequenc
98. rtification and Inspections This certificate is issued in accordance with Kiwa Regulations for product certification and consists of pages Publication of the certificate is permitted Supplier Inspections Company 2280 AB Rijswijk The Netherlands Telephone 070 41 44 400 Fax 070 41 44 420 Evaluati Kiwa I Aerosol fire extinguishing systems for fire protection in enclosed compartments containing electrical components PRODUCT SPECIFICATION The system consists of the following components 1 Fire extinguishing component FEC containing a Aerosol fire extinguishing component for extinguishing b Fire alarm extinguishing station for driving the aerosol fire extinguishing component and other drivers 6 Detection component for monitoring and guarding the object 2 Signal repeater HUB 3 Alarm management system with radio interface The maximum combined number of fire extinguishing components FEC and signal repeaters HUB within one system is 511 Within a system configuration the transmission path between a fire extinguishing component and the alarm management system is limited to a maximum of 32 signal repeaters HUB The system has to communicate on a licence free frequency band ISM frequency for which wireless communication for alarm purposes is permitted The aerosol fire extinguishing system should be constructed in such a way that the radio connection as transmission path is carried out redundantly T
99. s X ii K 4 1 Compliance K X 4 2 Classification X is X 4 3 Position of heat sensitive elements F i 4 4 Individual alarm indication bi i ii 4 5 Connection of ancillary devices K i A X 4 6 Monitoring of detachable detectors X X 4 7 Manufacturer s adjustments X is X 4 8 On site adjustments of response behaviour X iji K 4 9 Marking K E X 4 10 Data X id X 4 11 Additional requirements for software X E X controlled detectors 5 Test X i X 5 1 General X i X 5 2 Directional dependence X ii K 5 3 Static response temperature X x X 5 4 Response times from typical application X X temperature 5 5 Response times from 25 C X id X 5 6 Response times from high ambient temperature X 7 5 X Dry heat operational 27 Variation in supply parameters X X 5 8 Reproducibility X i K 5 9 Cold operational K i X 5 10 Dry heat endurance X A X 5 11 Damp heat cyclic operational X X 5 12 Damp heat steady state endurance X is X 5 13 Sulphur dioxide SO2 corrosion endurance K i X 5 14 Shock operational X X 5 15 Impact operational X i t X 5 16 Vibration sinusoidal operational X i bd K 5 17 Vibration sinusoidal endurance K id X 5 18 Electromagnetic Compatibility EMC X 4 z X Immunity tests operational 6 Additional tests for detectors with class f suffices 6 1 Test for suffix S detectors ji ii 6 2 Test for suffix R detectors X ig i X Appendix A informative Heat tu
100. s carried out to evaluate the properties of material as they are influenced by the absorption and diffusion of moisture and moisture vapour Hygroscopic materials are sensitive to moisture and deteriorate rapidly under high humidity conditions Absorption of moisture by many materials results in swelling which destroys their functional utility and causes loss of physical strength and changes in other important mechanical properties Insulating materials that absorb moisture may suffer degradation of their electrical properties This method while not necessarily intended as a simulated tropical test is of use in determining moisture absorption of materials Amount of samples The test should be executed with 3 samples The samples will be tested measured before and after the test Procedure Exposure The damp heat test shall be executed in accordance with IEC 60068 2 56 Test Cb Damp heat steady state The following level shall be used during the test 40 C 2 C 93 RH 3 21 days Inspections measurements The following parameters shall be tested measured before the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DWDDDW The following parameters should be tested measured at day 21 with the high humidity still in the climate chamber The samples should be taken out of the climate chamber one by one The following parameters should be test
101. s necessary B Fire alarm and extinguishing centre component for driving the aerosol fire extinguishing component and other drivers see also 2 2 B IP classification International Protection as per IEC 60529 2001 This denotes the degree of protection against ingress of particles dust and or water and or mechanical influences B IQC scheme Internal Quality Control scheme for production factory control ISE Intermediate Safety Expert ISM The ISM Industrial Scientific and Medical radio bands were originally reserved internationally for non commercial use of RF electromagnetic fields for industrial scientific and medical purposes The ISM band is defined in recommendation 70 03 of the European Radio Communications Committee LVD Low Voltage Directive European directives Maintenance interface cable specific cable for this system for maintenance activities B Maximum alarm device An alarm device that initiates an alarm when the size of the phenomenon measured during a certain amount of time exceeds a fixed value B Multiple status alarm device An alarm device that states multiple statuses more than two that refer to its normal status and one or more fire alarm statuses and other specific statuses B Multi sensor An alarm device that is sensitive to more than one fire phenomenon These are so called multi criteria alarm devices containing one or two sensors which detect the same fire phenomenon These devices se
102. s of the following components 1 Fire extinguishing component FEC containing a Aerosol fire extinguishing component for extinguishing b Fire alarm extinguishing station for driving the aerosol fire extinguishing component and other drivers c Detection component for monitoring and guarding the object 2 Signal repeater HUB 3 Alarm management system AMS with radio interface AMS HUB Component 1 can be used autonomously standalone as well without using the components 2 and 3 Alarm follow up can be guaranteed by means of other communication equipment The communication equipment must meet the requirements from the directives PrEN 54 13 EN 54 18 and EN 54 21 This communication equipment is usually provided by the alarm receiving station The aerosol fire extinguishing system must monitor the environment to be protected for fire phenomena This is done by detecting these fire phenomena and then communicates with other equipment within the system The purpose is to alarm in an initial phase of fire to notify a fire alarm station to extinguish in the fire phase and to control during a set time The aerosol fire extinguishing system is aimed to be applied in compartments such as those mentioned below i e object protection e Switch cabinets e Computers e Meter boxes Starting point is a standard projection see appendix 15 for detection and extinguishing The system s installation must be described in the suppli
103. safety measures can be initiated B Receiving station for fault warning messages An organisation institution from where the necessary correcting measures can be initiated B R amp TTE Radio amp Telecommunication Terminal Equipment European directives B Serial connection A communication connection by means of a cable for data transfer between the various components of a communication system Through the serial connection data can be exchanged between the various system parts This exchange takes place one after another B Signal repeater HUB The component that receives amplifies repeats and identically forwards the communication signal in order to span greater distances SFE Standard fire extinguishing agent SMS Short Message Service SSE Senior Safety Expert Standard projection Projection based on type tests as described in the configuration mentioned in appendices 15 and 16 B Stationary extinguishing components based on dry aerosol Extinguishing component based on a dry aerosol implemented in the fire extinguishing component The fire extinguishing component activates autonomously at a certain temperature as defined in EGL K23001 B Thermal alarm device An alarm device that is sensitive to rise of temperature DW DNDDDW Evaluation Guideline BRL K21014 04 Kiwa N V 11 June15 2009 1 4 Requirements and determination methods In this Evaluation Guideline requirements and determination methods have
104. sage conditions 10 to 450C 25 75 RH 86 106kPa the batteries must have a minimal lifetime of two years Evaluation Guideline BRL K21014 04 Kiwa N V 17 June15 2009 The batteries must be replaced according to the supplier s maintenance schedule or when the FEC gives a low voltage warning message Optional it should be possible to connect the FEC to a primary power supply 110 V 260 V 50 Hz 60 Hz This primary power supply must be supplied by the system s supplier and must meet the system s specifications In this case the power supply through batteries functions as emergency power supply Explanation 2 When applying the FEC as a standalone component as a standard it must be provided with a primary and a secondary power supply If functioning of the FEC is monitored externally a secondary power supply is not required Malfunctions in the power supply or a low storage battery voltage must be detected by the alarm management system and or must be notified to for example a custodian a receiving station for fault warnings or a receiving station for fire alarms B The requirements and test methods for electrical automatic control and delay devices must meet the requirements stated in EN 12094 1 2003 Deviations from these are The aerosol fire extinguishing component must be checked for wire breakage It must be possible to activate at least four fire extinguishing components simultaneously The interjacent
105. scription of requirement Article EGL Inspection within scope of Pre certification Supervision by CI after granting audit type test of the certificate Type test Audit Performance requirements Components H2 PA TT 2x per year Detection and extinguishing Appendix 15 PA TT 1x per year 1x per year Product requirements Requirements H3 PA TT 2x per year Quality system Quality system H4 PA 2x per year Table 10 Inspection matrix During the product s pre certification audits PA type tests TT should be carried out to determine whether the products meet the specific performance and product requirements The matrix above shows which requirements must be met to be eligible for certification Furthermore should be verified whether the certified product supplier s quality system meets the demands After granting of the product certificate periodical inspections should check whether the production still meets the specific performance and product requirements Renewed type tests could be applied Periodical audits should check whether the certified product supplier s quality system still complies and whether the product is still produced according to the initially tested specifications 5 2 Changes in design Changes to the certified product s design must always be reported to Kiwa before these are applied in production Kiwa will evaluate whether the design changes will lead
106. sion Test 31 Salt Spray Corrosion Test K ig ki 32 Thirty day Elevated Temperature Test K 33 Temperature Cycling Test K 34 One Year Time Leakage Test i 35 Hydrostatic Pressure Test i 35 1 Pressure Vessels i K y 35 2 Other pressure retaining devices 3 i 35 3 Test method 36 Pressure Relief Test 37 Flexible Hose Assembly Low Temperature Test ii ii ii 38 Calibration Test Gauges ii il 39 Burst Strength Test Gauges ji bi t 40 Overpressure Test Gauges i 41 Impulse Test Gauges is 42 Pressure Relief Test Gauges z H 43 Water Resistance Test Gauges j 44 Pneumatic Operation Test id ig s 45 Pneumatic Time delay Verification Test x i 46 Pressure Operated Alarm Test ii ii 47 Operation Test of Manual Actuators and Manual b iii Pull Stations 48 500 Cycle Operation Test K ji i 48 1 Electrical initiators X i Evaluation Guideline Kiwa N V 54 BRL K21014 04 June15 2009 Nr Subject FEC HUB AMS 48 2 Other Devices X ji ji 49 Class A and B Fire Extinguishing Tests K i 49 1 General test parameters K 49 2 Class A fire extinguishing tests K ig 49 3 Class B fire extinguishing tests K i i 50 Distribution Verification Extinguishing Tests with X ii Extinguishing System Units 50 1 General X 50 2 Test enclosure X T i 50 3 Maximum area
107. sly determined sampling with an accepted quality level as per IS02859 1 This should be determined based on risk inventory and evaluation The minimal sample size should be inspection level S2 and accepted quality level AQL 6 5 Every component from figure 1 should have a unique digital code 4 7 End inspection production After assembly the end product s functioning should be checked This should take place with a software based product inspection such as carrying out functional tests of critical functions Before packaging of the product a last visual inspection of the exterior should take place Evaluation Guideline BRL K21014 04 Kiwa N V 37 June15 2009 4 8 Other requirements to the quality system The certified supplier should have a functional quality system as per NEN EN ISO9001 2000 4 9 Subcontracting of activities If the whole process is put out to subcontractors then these subcontractors themselves must be certified in compliance with this Evaluation Guideline If parts of the process are subcontracted concluding procedures have to be included in the IQC scheme in which the certified supplier declares how the subcontractor s performance quality is guaranteed It concerns the following aspects equipment material to be used working instructions for the subcontractor inspections to be carried out by the subcontractor the entrance inspections of the certified installation mechanic quality registration of th
108. ss reference EN 54 4 Nr Subject FEC HUB AMS FEC Standalone 1 Scope 2 Normative references X X X X 3 Definitions and abbreviations X X X X 3 1 Definitions X X X X 3 2 Abbreviations X X X X 4 General requirements X X X X 4 1 Compliance X X X X 4 2 Power sources K i 5 General requirements for indications K K K K 5 1 Power supply from the main power source X X X X 5 2 Power supply from the standby power source X X X X 5 2 1 Standby power X X X X 5 2 2 Battery ig is K 5 3 Charger g X b 5 3 1 Charged automatically i 7 K 5 4 Faults X in 6 Materials design and manufacture K K K K 6 1 Manufacturer s declaration K K K K 6 2 Mechanical design K K K K 6 3 Electrical design K K K K 6 4 Power supply interface K K K K 7 Documentation K K K K 7 1 User s documentation K K K K 7 2 Design documentation K K K K 8 Marking K K K K 9 Test K K K K 9 1 General K K K K 9 2 Functional test K K K K 9 3 Test of the charger and the standby power if K F source 9 3 1 Test procedure i K 9 3 2 Requirements 7 X 9 4 Environmental tests K K K K 9 5 Cold K K K K 9 6 Damp heat steady state K K K K 9 7 Impact K K K K 9 8 Vibration sinusoidal K K K K 9 9 Electrostatic X X X X 9 10 Radiated electromagnetic interference X X X X 9 11 Voltage transients fast trans
109. supplier s quality system Organisation and personnel The certified supplier s organisation must be recorded in an organisation chart or structure diagram The tasks responsibilities and authorisations of all personnel plus their respective replacements must be known at Kiwa Changes in the organisation must be passed to Kiwa by postal correspondence Requirements to other verification personnel Personnel Qualification Level Experience Education Knowledge of by Custodian quality Management High 1 year within field Management or 1SO9001 t of application comparable BRL K21014 2 BRL K23001 Production Management High 1 year within field Electrical engineering 1SO9001 M of application or comparable BRL K21014 it BRL K23001 Assembly Production Lower 1 year within field tpc_a 610 IPC A 600 employees manager of application Employee Production Mid 1 year within field Electrical engineering IPC A 610 end control manager of application or comparable IPC A 600 BRL K21014 Trainers Management High 1 year within field Safety expert or BRL K21014 application course of application Electrical engineering BRL K23001 Installation Quality Mid 1 year within field Electrical engineering BRL K21014 mechanic manager of application Table 9 Overview requirements other verification personnel Proof of education and experience of personnel in question must be recorded 4 4 Requirements training co
110. surement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed Hammer test FEC and HUB Purpose The hammer test will be executed to simulate high forces on the mounting construction during a fire The hammer test can damage the housing Amount of samples The test should be executed with 3 samples Procedure The hammer test shall be executed in accordance with IEC 60068 2 75 Test Eh Hammer test the following levels shall be used during the test B Impact energy 1 9 0 1 J B Hammer velocity 1 5 0 13m s B Number of impacts 1 Inspections measurements The following parameters shall be tested measured before the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DNDDnDDW The following parameters shall be tested measured during the impact and 2 minutes after the impact All samples B No alarm or fault messages The following parameters should be tested measured after the test all samples Radio communication Bus communication Ignition CO measurement Temperature measurement DNDnDDW Evaluation Guideline BRL K21014 04 Kiwa N V 82 June15 2009 21 11 Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following perfor
111. t the amount of extinguishing amount left behind in the cooling of the fire extinguishing component Determination of the extinguishing performance should be carried out on the following conditions Evaluation Guideline BRL K21014 04 Kiwa N V 98 June15 2009 method by means of at least 5 thermo couples as per procedure with AT 10 sec registration through a logger laboratory Function Performance Unit Fire class Fire class A and B Determination method as per EN2 Thermal energy power See 22 1 Fire time realised by a catalyst 30 Seconds Catalyst See test procedure Air humidity in the room before the fire 60 20 measured by a hygrometer Ambient temperature before the fire to be 15 10 C measured by a thermo couple directly outside the room with a AT 10 sec registration through a logger Room temperature Determination To be determined during test in test C Dimensioning test room See 22 1 Meters and m3 Ventilation during the time of fire by means of a constant determination See 22 1 determining the outflow percentage of the extinguishing agent Ventilation opening and positioning See test procedure m2 during the extinguishing Air current in the room Forced Close test room after ignition fire Direct Seconds Amount of extinguishing agent necessary As per design formula EGL K23001 Grams m as per the formula Extinguishing time 10
112. temperature and functions like ignition radio communication and bus communication that would show the deleterious effects due to exposure to low ambient temperatures will be measured Amount of samples The test should be executed with 5 samples One sample will be tracked during the test The other four samples will be tested measured before and after the test Procedure The dry heat test shall be executed in accordance with IEC 60068 2 2 Test B Dry heat The following level shall be used during the test 60 C 2 C during 16 hours Inspections measurements The following parameters shall be tested measured before the test all samples B Radio communication B Bus communication B Ignition B CO measurement B Temperature measurement The following parameters should be tested measured at a high temperature during 16 hours 1 sample B Radio communication B CO measurement B Temperature measurement The following parameters should be tested measured after 16 hours The parameters should be tested at a high temperature 5 samples B Radio communication B Bus communication B Ignition B CO measurement B Temperature measurement Evaluation Guideline BRL K21014 04 Kiwa N V 75 June15 2009 Acceptance criteria The device is considered to have passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differenc
113. the outside world extinguish a starting fire and control it The number of fire extinguishing components FEC and signal repeaters HUB together within an aerosol fire extinguishing system may not exceed 511 Within an aerosol fire extinguishing configuration the transmission path between a fire extinguishing component and the alarm management system may consist of a maximum of Signal repeaters HUB The aerosol fire extinguishing system should communicate on a licence free frequency band ISM frequency for which wireless communication for alarm purposes is permitted The aerosol fire extinguishing system should be constructed in such a way that the radio connection as transmission path is carried out redundantly The aerosol fire extinguishing system consists of the following components 1 Fire extinguishing component FEC containing a Aerosol fire extinguishing component for extinguishing b Fire alarm extinguishing station for driving the aerosol fire extinguishing component and other drivers c Detection component for monitoring and guarding the object 2 Signal repeater HUB 3 Alarm management system AMS with radio interface AMS HUB Component 1 can be used autonomously standalone as well without using the components 2 and 3 Alarm follow up can be guaranteed by means of other communication equipment The communication equipment must meet the requirements from the directives prEN 54 13 EN 54 18 and EN 54 21 This com
114. the structure of legislation and regulations about the aerosol extinguishing system General knowledge of fire Can name the definition of fire Can name the standard fire curve Can name the fire triangle quadrangle and pentagon Can name the fire classes Can name the risks that arise during a fire DNDnDDADW Evaluation Guideline BRL K21014 04 Kiwa N V 33 June15 2009 Can explain the concept flash point and the different categories Can explain the concept self ignition point Can explain the concept explosion area and the concepts LEL and UEL Can name the different extinguishing methods Can name the different extinguishing agents and their extinguishing efficacy Can explain a dry aerosol as extinguishing system Can name the different fire protection systems Can name the different types of automatic alarm devices DNDnDDADW DDD General knowledge of radio communication B Can name the definition of radio communication B Can explain the concept radio spectrum B Can name the different bands R Can explain the concept polarisation of radio radiation in free space B Can explain the general concepts of radio communication B Can explain the concept signal strength B Can explain the concept display and power in dB B Can explain the concept signal quality B Can explain the concept and properties of transmission lines B Can explain the functioning of antennas B Can explain the concept polarisation B Can explain the
115. tion withstands the test according to the relevant performance levels The following performance differences are acceptable B Radio communication still working Evaluation Guideline BRL K21014 04 Kiwa N V 83 June15 2009 Bus communication still working Ignition still working CO measurement still working measurement differences of 8 ppm are allowed B Temperature measurement still working temperature differences of 4 C are allowed DDD The AMS receives alarm and fault warning messages from the NOFIQ equipment It also regularly receives a still alive message from all devices within the network Evaluation Guideline BRL K21014 04 Kiwa N V 84 June15 2009 21 12 Environmental Reliability tests AMS The following table gives an overview of all reliability tests Directive Test Test level TEC 60068 2 1 Test A Cold 0 C 2 C 16 hours IEC 60068 2 6 Test Fc Vibration sinusoidal endurance 10 150 Hz 0 981 m s 3 axes 1 sweep axes for each function 1dB octave by enclosures IP Code IEC 817 Impact operational 0 5 0 04 J 3 impact point IEC 60068 2 78 Test Cab Damp heat steady state 40 C 2 C 93 RH 2 3 4 days TEC 60529 Degrees of protection provided IP 30 Table 16 Environmental reliability tests AMS A test sequence has been made to reduce the amount of samples and to reduce the total test time Th
116. tioning system In certain fields this Evaluation Guideline exceeds the directives Only certified normalized or specified materials may be applied for system components The certified supplier should operate a quality system conformably to ISO 9001 2000 system certification EN 45012 This should also contain the warrant for the application course personal certificate ISO 17024 During the product s pre certification tests PCT type tests TT should be carried out to determine whether the products meet the specific performance and product requirements Furthermore should be verified whether the certified product supplier s quality system meets the demands After granting of the product certificate periodical inspections should check whether the production still meets the specific performance and product requirements Renewed type tests could be applied Periodical audits should check whether the certified product supplier s quality system still complies and whether the product is still produced according to the initially tested specifications Evaluation Guideline BRL K21014 04 Kiwa N V 2 June15 2009 Preface This Evaluation Guideline BRL has been set up by the College van Deskundigen Brandveiligheid Committee of Experts in Fire Protection in which concerned parties in the field of fire extinguishing systems are represented This Evaluation Guideline is drawn up by the technical work group BRL K21014 and du
117. to new product type tests The changed product can only be supplied with the Kiwa certification mark after Kiwa s written approval of the new product Evaluation Guideline BRL K21014 04 Kiwa N V 39 June15 2009 5 3 Inspection of the quality management system The inspection of the quality management system can be proven by means of a certificate granted by an accredited certification institution under EAC Accreditation Furthermore tests and audits should be carried out as per the inspection matrix stated in this Evaluation Guideline The audit frequency is 2x per year Evaluation Guideline BRL K21014 04 Kiwa N V 40 June15 2009 6 Requirements to certification institutions 6 1 General This chapter contains the agreements made by the Board of Experts on the implementation of the certification by the certification institution CI 6 2 Certification personnel The personnel involved in the certification may be divided into B Certification experts in charge of the implementation of the pre certification tests and the assessment of the inspectors reports B Inspectors in charge of the implementation of external inspections at the certified supplier s B Decision makers in charge of taking decisions in connection with the pre certification tests carried out of continuation of the certification in connection with inspections carried out and decisions regarding the need to take corrective actions 6 2 1 Qual
118. trum Matters ERM Land mobile service Radio equipment intended for the transmission of data and or speech using constant or non constant envelope modulation and having an antenna connector Part 1 Technical characteristics and methods of measurement e EN 300220 1 V 1 3 1 2000 Electromagnetic compatibility and Radio spectrum Matters ERM Short range devices Radio equipment to be used in the 25 MHz to 1000 MHz frequency range with power levels ranging up to 500 mW Part 1 Technical characteristics and test methods e 99 5 EC Directive 1999 5 EC of the European Parliament and of the Council of 9 March 1999 on radio equipment and telecommunications terminal equipment R amp TTE and the mutual recognition of their conformity The directive EN 300220 1 is used for defining and testing of radio products in a frequency band of 25 MHz to 1 GHz This product functions on a frequency of 2 4 GHz The 2 4 GHz is a free band which throughout Europe can be used for alarm purposes The Construction Products Directive CPD has not taken into account higher frequencies although this is technically possible and directives for these are available A Notified Body has granted a general directive for a frequency band that covers this product 1 GHz 40 GHz thus meeting the Evaluation Guideline Kiwa N V BRL K21014 04 48 June15 2009 R amp TTE directives and aligning as close as possible to the Constructi
119. uirements must meet the relevant directives as per the applying CE marking guidelines and EN 54 25 Deviations and supplementary requirements are B The HUB and AMS HUB must communicate on a licence free frequency band ISM frequency for which wireless communication for alarm purposes is permitted B Atleast every 5 minutes status reports containing a o power supply conditions operational status of the HUB must be exchanged between FEC HUB and AMS 2 4 4 Housing The housing of the HUB and AMS HUB must meet the following performance requirements B The requirements in appendix 14 apply B The housing must have at least IP class 30 as per IEC 60529 2001 B It must be possible to attach the HUB appropriately to walls and ceilings of the protected room The housing and fixing materials must be able to carry 5 x their own weight with a minimum of 5 kg Evaluation Guideline BRL K21014 04 Kiwa N V 23 June15 2009 2 5 Performance requirements alarm management system AMS Below the performance requirements for the various components of the AMS are stated supplementary to and or deviating from appendices 1 t m 16 2 5 1 General B The AMS must be able to function at a temperature from 10 C to 60 C and an air humidity of maximum 95 no condensation B The AMS must meet the requirements stated in EN 54 2 1998 and EN 54 2 Design A1 2004 The AMS must be kept connected to the AMS HUB by means of serial cabling of
120. uishing It therefore concerns a pre engineered system The installation of the aerosol fire extinguishing system should be described in the supplier s manual The users will be instructed in design installation acceptance and follow up by means of a training by the supplier For an integral safety concept this training should be applied in combination with this BRL EGL Explanation If the detection system does not function the system shall be activated by means of a thermal cord If this thermal cord refuses activation takes place based on the aerosols own activation temperature The values must be declared in the product certificate of the aerosol extinguishing agent as per BRL K23001 Additionally the product certificate must give insight in dimensioning of the system The aerosol fire extinguishing system should be able to function in an indoor environment meeting the following conditions Conditions FEC HUB AMS Use Temperature 10 C to 45 C 10 C to 60 C 10 C to 60 C Air humidity lt 95 RH lt 95 RH lt 95 RH Air pressure 86 to 106kPa 86 to 106kPa 86 to 106kPa Storage Temperature 20 C to 40 C 20 C to 50 C 20 C to 50 C Air humidity 25 to 75 RH 25 to 75 RH 25 to 75 RH Air pressure 86 to 106kPa 86 to 106kPa 86 to 106kPa Transport during a maximum of 24 hours Temperature 35 C to 50 C 35 C to 85 C 35 C to 85 C Air humidity lt 95 RH lt 95 RH
121. une15 2009 Directive normative reference Concerns AMS HUB FEC NEN EN 54 4 Power supply primary K NEN EN 54 4 Power supply secondary battery K UL 609050 EN 60950 EN 55022 Primary power supply internal AC DC converter K EN 61000 NEN EN 54 4 Emergency power supply regulator K EN IEC 60950 1 Adapter power supply external AC DC converter K x IEC 60086 1 IEC 60086 2 IEC Battery power supply K K 60086 3 IEC 60086 4 IEC 60086 5 DIN 4102 12 Cables with functionality maintenance E30 30 minutes K K as per NEN 2535 TEC 60529 Housing IP 30 K K K UL 94 Fire delaying plastic 94V 2 Flame Class Rating 3 K K UL 2034 EN 50291 CSA22 2 CO sensor X EN 60950 EN 55022 Class B External communication X EN 55024 NEN EN 54 2 Display X EN IEC 60950 AMS Controller X Table 7 Normalized products without product control mark optional 3 1 3 Non normalized products All non normalized products must be checked functionally for its function All materials must be checked visually for damage It concerns the following materials Small components like resistors capacitors indicators switches etc B Mounting materials like fixing screws B Electric flat cable connections which are used for communication between the various components 3 2 Environmental requirements The solder and connection joints in the product must be lead free as well as soldered l
122. ure to chemical agents associated with a X i K fire 5 9 Variation in supply parameters X j 7 K 5 10 Air movement ji 5 11 Dry heat operational K Ks K 5 12 Cold K X 5 13 Damp heat steady state operational X id ii K 5 14 Damp heat steady state endurance K i z X 5 15 Sulphur dioxide SO2 corrosion endurance K me K 5 16 Shock K x X 5 17 Impact X i K 5 18 Vibration sinusoidal operational K X 5 19 Vibration sinusoidal endurance X i X 5 20 Electromagnetic Compatibility EMC X i X Immunity tests 5 21 Fire sensitivity K si a K 6 Test report X i k X Appendix A Gas test chamber for response threshold value X T X X and cross sensitivity measurements Appendix B Apparatus for impact test X 7 K Appendix C Fire test room 3 Appendix D Smouldering wood fire TF2 x 4 ii Appendix E Glowing smouldering cotton fire TF3 ji id id Appendix F Deep seated smouldering cotton fire TF9 d i 7 Appendix G_ Information concerning the construction of ii the gas test chamber Not within scope this has been settled elsewhere in the directive Evaluation Guideline BRL K21014 04 Kiwa N V 64 June15 2009 16 Appendix 9 Cross reference EN 54 25 Nr Subject FEC HUB AMS 1 Scope gt 4 K Normative references is
123. urses The end terms of the certified supplier s application training must satisfy the afore mentioned competences Evaluation Guideline Kiwa N V 31 BRL K21014 04 June15 2009 4 4 1 Application training installation mechanic The end terms below apply Legislation and regulations B Knows what an Evaluation Guideline is B Knows the existence of the EGL BRL K23001 and K21014 B Knows the structure of legislation and regulations about the aerosol extinguishing system General knowledge of fire Knows the definition of fire Knows the standard fire curve Knows the fire triangle quadrangle and pentagon Knows the fire classes Knows the risks that arise during a fire Knows the concept flash point and the different categories Knows the concept self ignition point Knows the concept explosion area and the concepts LEL and UEL Knows the different extinguishing methods Knows the different extinguishing agents and their extinguishing efficacy Knows a dry aerosol as extinguishing system Knows the different fire protection systems Knows the different types of automatic alarm devices DDDNDDDVADVADVAAW DDD General knowledge of radio communication B Knows the definition of radio communication B Knows the concept radio spectrum B Knows the different bands B Knows the concept polarisation of radio radiation in free space B Knows the general concepts of radio communication B Knows the concept signal strength
124. ve passed the test if the entire test population withstands the test according to the relevant performance levels The following performance differences are acceptable LEDs and display test still working Button test still working Buzzer test still working Serial communication to AMS HUB still working Modem communication still working Switching of relays still working DWDDDDA WwW Evaluation Guideline BRL K21014 04 Kiwa N V 89 June15 2009 21 16 Damp heat steady state AMS Purpose This test is carried out to evaluate the properties of material as they are influenced by the absorption and diffusion of moisture and moisture vapour Hygroscopic materials are sensitive to moisture and deteriorate rapidly under high humidity conditions Absorption of moisture by many materials results in swelling which destroys their functional utility and causes loss of physical strength and changes in other important mechanical properties Insulating materials that absorb moisture may suffer degradation of their electrical properties This method while not necessarily intended as a simulated tropical test is of use in determining moisture absorption of materials Amount of samples The test should be executed with 2 samples The samples will be tested measured before and after the test Procedure The damp heat test shall be executed in accordance with IEC 60068 2 56 Test Cb Damp heat steady state The following level
125. ves mentioned in order to achieve a well Evaluation Guideline BRL K21014 04 Kiwa N V 15 June15 2009 functioning system In certain fields this Evaluation Guideline exceeds the directives The overview below is informative The appendices mentioned are normative PERFORMANCE REQUIREMENTS DIRECTIVE REFERENCE 1 Fire extinguishing component FEC a Aerosol fire extinguishing component BRL K23001 03 2005 for product and quality or UL See appendix 2775 2008 or CEN TR 15276 1 for product 3A 3B and 3C b Fire alarm extinguishing device EN 54 2 1998 and EN 54 2 Design A1 2004 See appendix 4 and 13 Power supply EN 54 4 1997 AC 1999 and EN 54 4 1997 A1 2002 See appendix 5 Requirements and test methods for EN 12094 1 2003 See appendix 6 electrical automatic control and delay devices c Detection component Thermal alarm devices Point detector EN 54 5 2001 and correction sheet EN 54 5 Design See appendix 7 A1 2002 Carbon monoxide fire detectors using ISO 7240 6 2004 See appendix 8 electro chemical cells Radio connections and system The product must meet the relevant requirements as See appendix 9 requirements per the applying CE marking directives and EN54 25 2008 Housing IEC 60068 2 1 IEC 60068 2 2 IEC 60068 2 6 IEC See appendix 14 60068 2 27 IEC 60068 2 30 TEC 60068 2 32 IEC 60068 2 42 IEC 60068 2 56 IEC 60068 2 75 IEC 60068 2 78 and
126. working Buzzer test still working Serial communication to AMS HUB still working Modem communication still working Switching of relays still working DWDDNDDDW Evaluation Guideline BRL K21014 04 Kiwa N V 88 June15 2009 21 15 Hammer test AMS Purpose The hammer test will be executed to simulate high forces on the mounting construction during a fire The hammer test can damage the housing Amount of samples The test should be executed with 1 sample Procedure The hammer test shall be executed in accordance with IEC 60068 2 75 Test Eh Hammer test The following levels shall be used during the test B Impact energy 1 9 0 1 J B Hammer velocity 1 5 0 13m s Number of impacts 1 on each visible side front left right up and bottom Inspections measurements The following parameters shall be tested measured before the test all samples LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DWDDDDA DW The following parameters shall be tested measured during the impact and 2 minutes after the impact All samples B No alarm or fault messages The following parameters should be tested measured after the test LEDs and display test Button test Buzzer test Serial communication to AMS HUB Modem communication Switching of relays DNWDDNDDDA DW Acceptance criteria The device is considered to ha
127. y means of a specific interface cable for executing maintenance activities B The fire alarm extinguishing device must be provided with at least one potential free contact for disabling for example a ventilator 24 Volt 1 Ampere When applying the FEC as a standalone component it must be possible to delay notification of alarms in the transmission path The delay must be at least 30 seconds Explanation 1 when applying several standalone components by means of a serial bus combining groups of alarms is possible B The FEC must be able to support different operational situations and must be provided with an acoustic indicator and three different optical red yellow green indicators see paragraph 2 3 3 1 B The fire alarm extinguishing device must be provided with a connector to connect an antenna When the FEC has been installed in for example a switch cabinet and no radio communication would be possible Faraday s Cage than it should be possible to place the antenna outside the switch cabinet and connect it by means of an extension cord thus ensuring radio communication The maximum length of the extension cord is 3 meters with a maximum attenuation of 1 dB B The power supply of the fire extinguishing component must meet the requirements stated in EN 54 4 1997 AC 1999 and EN 54 4 1997 A1 2002 Deviations from these are o The secondary power supply must be composed of gas tight batteries or storage batteries Under normal u
128. y of external inspections audits List of documents stated Public law regulations Directive normative documents Appendix 1 model product certificate Appendix 2 IQC scheme Appendix 3 Cross reference aerosol Appendix 3A Cross reference BRL K23001 Appendix 3B Cross reference UL 2775 Appendix 3C Cross reference CEN TR 15276 1 11 12 13 14 15 16 17 18 19 Appendix 4 Cross reference EN 54 2 Appendix 5 Cross reference EN 54 4 Appendix 6 Cross reference EN 12094 1 Appendix 7 Cross reference EN 54 5 Appendix 8 Cross reference ISO 7240 6 Appendix 9 Cross reference EN 54 25 Appendix 10 Cross reference EN 54 13 Appendix 11 Cross reference EN 54 18 Appendix 12 Cross reference EN 54 21 38 38 39 39 39 40 41 41 41 41 42 42 43 45 50 51 52 54 56 58 60 61 63 64 65 67 68 69 Evaluation Guideline Kiwa N V 5 BRL K21014 04 June15 2009 20 21 21 1 21 2 21 3 21 4 21 5 21 6 21 7 21 8 21 9 21 10 21 11 21 12 21 13 21 14 21 15 21 16 21 17 22 22 1 22 2 22 3 22 4 23 23 1 23 2 Appendix 13 Cross reference UL 827 70 Appendix 14 Environmental Reliability test Fire Extinguisher 71 Environmental Reliability tests FEC HUB AMS and FEC standalone 71 Cold FEC and HUB 74 Dry heat FEC and HUB 75 Vibration sinusoidal FEC and HUB 76 Shock FEC and HUB 77 Free fall Drop test FEC and HUB
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