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Standard and/or project under the direct responsibility of ISO/TC 92/SC 4 Secretariat | Stage | ICS |
---|---|---|
Principles of structural fire-engineering design with special regard to the connection between real fire exposure and the heating conditions of the standard fire-resistance test (ISO 834)
|
95.99 | |
Fire safety engineering — Part 1: Application of fire performance concepts to design objectives
|
95.99 | |
Fire safety engineering — Part 2: Design fire scenarios and design fires
|
95.99 | |
Fire safety engineering — Part 3: Assessment and verification of mathematical fire models
|
95.99 | |
Fire safety engineering — Part 4: Initiation and development of fire and generation of fire effluents
|
95.99 | |
Fire safety engineering — Part 5: Movement of fire effluents
|
95.99 | |
Fire safety engineering — Part 6: Structural response and fire spread beyond the enclosure of origin
|
95.99 | |
Fire safety engineering — Part 7: Detection, activation and suppression
|
95.99 | |
Fire safety engineering — Part 8: Life safety — Occupant behaviour, location and condition
|
95.99 | |
Fire safety engineering — Guidance for use of fire zone models
|
90.93 | |
Fire safety engineering — Examples of fire safety objectives, functional requirements and safety criteria
|
90.93 | |
Fire safety engineering — Procedures and requirements for verification and validation of calculation methods — Part 1: General
|
90.93 | |
Fire safety engineering — Assessment, verification and validation of calculation methods — Part 2: Example of a fire zone model
|
90.93 | |
Fire safety engineering — Assessment, verification and validation of calculation methods — Part 3: Example of a CFD model
|
90.93 | |
Fire safety engineering — Assessment, verification and validation of calculation methods — Part 4: Example of a structural model
|
90.93 | |
Fire safety engineering — Assessment, verification and validation of calculation methods — Part 5: Example of an Egress model
|
90.93 | |
Fire safety engineering — Assessment, verification and validation of calculation methods
|
95.99 | |
Fire safety engineering — Fire risk assessment — Part 1: General
|
90.92 | |
Fire safety engineering — Fire risk assessment — Part 1: General
|
30.60 |
|
Fire Safety Engineering — Fire risk assessment — Part 2: Example of an office building
|
90.93 | |
Fire safety engineering — Fire risk assessment — Part 3: Example of an industrial property
|
90.93 | |
Fire safety engineering — Guidance on fire risk assessment
|
95.99 | |
Fire safety engineering — Selection of design fire scenarios and design fires — Part 1: Selection of design fire scenarios
|
90.92 | |
Fire safety engineering — Selection of design fire scenarios and design fires — Part 1: Selection of design fire scenarios
|
60.00 | |
Fire safety engineering — Selection of design fire scenarios and design fires — Part 2: Design fires
|
90.93 | |
Fire safety engineering — Selection of design fire scenarios and design fires
|
95.99 | |
Fire safety engineering — Requirements governing algebraic equations — Fire plumes
|
95.99 | |
Fire safety engineering — Requirements governing algebraic equations — Smoke layers
|
95.99 | |
Fire safety engineering — Requirements governing algebraic equations — Ceiling jet flows
|
95.99 | |
Fire safety engineering — Requirements governing algebraic equations — Vent flows
|
95.99 | |
Fire safety engineering — Requirements governing algebraic equations — Vent flows
|
95.99 | |
Fire-safety engineering — Technical information on methods for evaluating behaviour and movement of people
|
90.93 | |
Fire safety engineering — Design of evacuation experiments
|
60.60 | |
Fire safety engineering — Survey of performance-based fire safety design practices in different countries
|
60.60 | |
Fire safety engineering — Verification and validation protocol for building fire evacuation models
|
60.60 | |
Fire safety engineering — Active fire protection systems — Part 1: General principles
|
60.60 | |
Fire safety engineering — Active fire protection — Part 2: Estimation of heat detection time
|
30.60 |
|
Fire safety engineering — Estimating the reduction in movement speed based on visibility and irritant species concentration
|
60.60 | |
Fire safety engineering – Concept and example applications of risk-based fire safety design of buildings
|
30.60 | |
Fire safety engineering — General principles — Part 1: General
|
90.93 | |
Fire safety engineering — General principles — Part 2: Example of a dry-cleaning store
|
60.60 | |
Fire safety engineering — General principles
|
95.99 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 1: General requirements
|
90.93 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 2: Fire plume
|
60.60 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 3: Ceiling jet flows
|
60.60 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 4: Smoke layers
|
60.60 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 5: Vent flows
|
60.60 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 6: Flashover related phenomena
|
90.92 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 6: Flashover related phenomena
|
30.99 |
|
Fire safety engineering — Requirements governing algebraic formulae — Part 7: Radiation heat flux received from an open pool fire
|
90.92 | |
Fire safety engineering — Requirements governing algebraic formulae — Part 7: Radiation heat flux received from an open pool fire
|
20.00 |
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Fire safety engineering — Requirements governing algebraic formulae — Part 9: Ejected flame from an opening
|
60.60 | |
Fire safety engineering — Performance of structures in fire — Part 1: General
|
90.93 | |
Fire safety engineering — Performance of structure in fire — Part 2: Example of an airport terminal
|
90.93 | |
Fire safety engineering — Performance of structure in fire — Part 3: Example of an open car park
|
90.93 | |
Fire safety engineering — Performance of structures in fire — Part 4: Example of a fifteen-storey steel-framed office building
|
90.92 | |
Fire safety engineering — Performance of structures in fire — Part 4: Example of a fifteen-storey steel-framed office building
|
20.20 |
|
Fire safety engineering — Performance of structures in fire — Part 5: Example of a timber building in Canada
|
60.60 | |
Fire safety engineering — Performance of structures in fire — Part 6: Example of an eight-storey office concrete building
|
90.93 | |
Fire safety engineering — Performance of structures in fire — Part 8: Example of a probabilistic assessment of a concrete building
|
60.60 | |
Fire safety engineering — Performance of structures in fire
|
95.99 | |
Fire safety engineering — Selection of design occupant behavioural scenarios
|
90.93 |
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