| Name |
Description |
Abstract |
Status |
Publication date |
Edition |
Number of pages |
Technical committee |
ICS |
| ISO 9972:2006/Amd 1:2009 |
Thermal performance of buildings — Determination of air permeability of buildings — Fan pressurization method — Amendment 1 |
|
Withdrawn |
2009-03 |
Edition : 2 |
Number of pages : 2 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 9972:2015 |
Thermal performance of buildings — Determination of air permeability of buildings — Fan pressurization method |
ISO 9972:2015 is intended for the measurement of the air permeability of buildings or parts of buildings in the field. It specifies the use of mechanical pressurization or depressurization of a building or part of a building. It describes the measurement of the resulting air flow rates over a range of indoor-outdoor static pressure differences.
ISO 9972:2015 is intended for the measurement of the air leakage of building envelopes of single-zone buildings. For the purpose of this International Standard, many multi-zone buildings can be treated as single-zone buildings by opening interior doors or by inducing equal pressures in adjacent zones.
ISO 9972:2015 does not address evaluation of air permeability of individual components.
|
Published |
2015-08 |
Edition : 3 |
Number of pages : 26 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10077-1:2000 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 1: Simplified method |
|
Withdrawn |
2000-07 |
Edition : 1 |
Number of pages : 27 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-1:2006 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 1: General |
ISO 10077-1:2006 specifies methods for the calculation of the thermal transmittance of windows and pedestrian doors consisting of glazed and/or or opaque panels fitted in a frame, with and without shutters.
ISO 10077-1:2006 allows for the following:
different types of glazing (glass or plastic; single or multiple glazing; with or without low emissivity coatings, and with spaces filled with air or other gases);opaque panels within the window or door;various types of frames (wood, plastic, metallic with and without thermal barrier, metallic with pinpoint metallic connections or any combination of materials);where appropriate, the additional thermal resistance introduced by different types of closed shutter, depending on their air permeability.
The thermal transmittance of roof windows and other projecting windows can be calculated using ISO 10077-1:2006, provided that the thermal transmittance of their frame sections is determined by measurement or by numerical calculation.
Default values for glazing, frames and shutters are given in ISO 10077-1:2006.
Thermal bridge effects at the rebate or joint between the window or door frame and the rest of the building envelope are excluded from the calculation. The calculation also does not include effects of solar radiation, heat transfer caused by air leakage, calculation of condensation, ventilation of air spaces in double and coupled windows and surrounding parts of an oriel window.
ISO 10077-1:2006 does not apply to curtain walls and other structural glazing and industrial, commercial and garage doors.
|
Withdrawn |
2006-09 |
Edition : 2 |
Number of pages : 35 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-1:2006/Cor 1:2009 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 1: General — Technical Corrigendum 1 |
|
Withdrawn |
2009-11 |
Edition : 2 |
Number of pages : 7 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-1:2017 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 1: General |
ISO 10077-1:2017 specifies methods for the calculation of the thermal transmittance of windows and pedestrian doors consisting of glazed and/or opaque panels fitted in a frame, with and without shutters.
|
Published |
2017-06 |
Edition : 3 |
Number of pages : 40 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-2:2003 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 2: Numerical method for frames |
ISO 10077-2:2003 specifies a method and gives reference input data for the calculation of the thermal transmittance of frame profiles and of the linear thermal transmittance of their junction with glazings or opaque panels.
The method can also be used to evaluate the thermal resistance of shutter profiles and the thermal characteristics of roller shutter boxes.
ISO 10077-2:2003 also gives criteria for the validation of numerical methods used for the calculation. ISO 10077-2:2003 does not include effects of solar radiation, heat transfer caused by air leakage or three-dimensional heat transfer such as pin point metallic connections. Thermal bridge effects between the frame and the building structure are not included.
|
Withdrawn |
2003-10 |
Edition : 1 |
Number of pages : 26 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-2:2012 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 2: Numerical method for frames |
ISO 10077-2:2011 specifies a method and gives reference input data for the calculation of the thermal transmittance of frame profiles and of the linear thermal transmittance of their junction with glazing or opaque panels.
The method can also be used to evaluate the thermal resistance of shutter profiles and the thermal characteristics of roller shutter boxes and similar components (e.g. blinds).
ISO 10077-2:2011 also gives criteria for the validation of numerical methods used for the calculation.
ISO 10077-2:2011 does not include effects of solar radiation, heat transfer caused by air leakage or three‑dimensional heat transfer such as pin point metallic connections. Thermal bridge effects between the frame and the building structure are not included.
|
Withdrawn |
2012-03 |
Edition : 2 |
Number of pages : 36 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-2:2012/Cor 1:2012 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 2: Numerical method for frames — Technical Corrigendum 1 |
|
Withdrawn |
2012-07 |
Edition : 2 |
Number of pages : 1 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-2:2017 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 2: Numerical method for frames |
ISO 10077-2:2017 specifies a method and gives reference input data for the calculation of the thermal transmittance of frame profiles and of the linear thermal transmittance of their junction with glazing or opaque panels.
The method can also be used to evaluate the thermal resistance of shutter profiles and the thermal characteristics of roller shutter boxes and similar components (e.g. blinds).
ISO 10077-2:2017 also gives criteria for the validation of numerical methods used for the calculation.
ISO 10077-2:2017 does not include effects of solar radiation, heat transfer caused by air leakage or three-dimensional heat transfer such as pinpoint metallic connections. Thermal bridge effects between the frame and the building structure are not included.
NOTE Table 1 in the Introduction shows the relative position of ISO 10077-2:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1.
|
Published |
2017-06 |
Edition : 3 |
Number of pages : 70 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10077-2:2017/DAmd 1 |
Thermal performance of windows, doors and shutters — Calculation of thermal transmittance — Part 2: Numerical method for frames — Amendment 1 |
|
Under development |
|
Edition : 3 |
Number of pages : 11 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10211-1:1995 |
Thermal bridges in building construction — Heat flows and surface temperatures — Part 1: General calculation methods |
Sets out specifications on a 3-D geometrical model of a thermal bridge for the numerical calculation of heat flows in order to assess heat loss from a building and calculation of minimum surface temperatures in order to assess the risk of surface condensation.
|
Withdrawn |
1995-08 |
Edition : 1 |
Number of pages : 54 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10211-1:1995/Cor 1:2002 |
Thermal bridges in building construction — Heat flows and surface temperatures — Part 1: General calculation methods — Technical Corrigendum 1 |
|
Withdrawn |
2002-05 |
Edition : 1 |
Number of pages : 7 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10211-2:2001 |
Thermal bridges in building construction — Calculation of heat flows and surface temperatures — Part 2: Linear thermal bridges |
|
Withdrawn |
2001-03 |
Edition : 1 |
Number of pages : 15 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12567-1:2000 |
Thermal performance of windows and doors — Determination of thermal transmittance by hot box method — Part 1: Complete windows and doors |
|
Withdrawn |
2000-09 |
Edition : 1 |
Number of pages : 41 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 10211:2007 |
Thermal bridges in building construction — Heat flows and surface temperatures — Detailed calculations |
ISO 10211:2007 sets out the specifications for a three-dimensional and a two-dimensional geometrical model of a thermal bridge for the numerical calculation of:
heat flows, in order to assess the overall heat loss from a building or part of it;
minimum surface temperatures, in order to assess the risk of surface condensation.
These specifications include the geometrical boundaries and subdivisions of the model, the thermal boundary conditions, and the thermal values and relationships to be used.
ISO 10211:2007 is based upon the following assumptions:
all physical properties are independent of temperature;
there are no heat sources within the building element.
ISO 10211:2007 can also be used for the derivation of linear and point thermal transmittances and of surface temperature factors.
|
Withdrawn |
2007-12 |
Edition : 1 |
Number of pages : 45 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10211:2017 |
Thermal bridges in building construction — Heat flows and surface temperatures — Detailed calculations |
ISO 10211:2017 sets out the specifications for a three-dimensional and a two-dimensional geometrical model of a thermal bridge for the numerical calculation of
- heat flows, in order to assess the overall heat loss from a building or part of it, and
- minimum surface temperatures, in order to assess the risk of surface condensation.
These specifications include the geometrical boundaries and subdivisions of the model, the thermal boundary conditions, and the thermal values and relationships to be used.
ISO 10211:2017 is based upon the following assumptions:
- all physical properties are independent of temperature;
- there are no heat sources within the building element.
ISO 10211:2017 can also be used for the derivation of linear and point thermal transmittances and of surface temperature factors.
NOTE Table 1 in the Introduction shows the relative position of ISO 10211:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1.
|
Published |
2017-06 |
Edition : 2 |
Number of pages : 55 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10456:1997 |
Thermal insulation — Building materials and products — Determination of declared and design thermal values |
|
Withdrawn |
1997-08 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
91.100.01
Construction materials in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 10456:1997/Cor 1:1997 |
Thermal insulation — Building materials and products — Determination of declared and design thermal values — Technical Corrigendum 1 |
|
Withdrawn |
1997-12 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
91.100.01
Construction materials in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 10456:1999 |
Building materials and products — Procedures for determining declared and design thermal values |
|
Withdrawn |
1999-12 |
Edition : 2 |
Number of pages : 16 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10456:2007 |
Building materials and products — Hygrothermal properties — Tabulated design values and procedures for determining declared and design thermal values |
ISO 10456:2007 specifies methods for the determination of declared and design thermal values for thermally homogeneous building materials and products, together with procedures to convert values obtained under one set of conditions to those valid for another set of conditions. These procedures are valid for design ambient temperatures between -30 °C and +60 °C.
ISO 10456:2007 provides conversion coefficients for temperature and for moisture. These coefficients are valid for mean temperatures between 0 °C and 30 °C.
ISO 10456:2007 also provides design data in tabular form for use in heat and moisture transfer calculations, for thermally homogeneous materials and products commonly used in building construction.
|
Published |
2007-12 |
Edition : 3 |
Number of pages : 25 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 10456:2007/Cor 1:2009 |
Building materials and products — Hygrothermal properties — Tabulated design values and procedures for determining declared and design thermal values — Technical Corrigendum 1 |
|
Published |
2009-12 |
Edition : 3 |
Number of pages : 1 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12241:1998 |
Thermal insulation for building equipment and industrial installations — Calculation rules |
|
Withdrawn |
1998-03 |
Edition : 1 |
Number of pages : 39 |
Technical Committee |
91.120.10
Thermal insulation of buildings
;
91.140.01
Installations in buildings in general
|
| ISO 12241:2008 |
Thermal insulation for building equipment and industrial installations — Calculation rules |
ISO 12241:2008 gives rules for the calculation of heat-transfer-related properties of building equipment and industrial installations, predominantly under steady-state conditions. ISO 12241:2008 also gives a simplified approach for the treatment of thermal bridges.
|
Withdrawn |
2008-06 |
Edition : 2 |
Number of pages : 45 |
Technical Committee |
91.120.10
Thermal insulation of buildings
;
91.140.01
Installations in buildings in general
|
| ISO 11253:1993 |
Lasers and laser-related equipment — Laser device — Mechanical interfaces |
Specifies dimensions of mounting-hole patterns for attaching external devices to a laser device around the beam.
|
Withdrawn |
1993-09 |
Edition : 1 |
Number of pages : 2 |
Technical Committee |
31.260
Optoelectronics. Laser equipment
|
| ISO 12567-1:2010 |
Thermal performance of windows and doors — Determination of thermal transmittance by the hot-box method — Part 1: Complete windows and doors |
ISO 12567-1:2010 specifies a method to measure the thermal transmittance of a door or window system. It is applicable to all effects of frames, sashes, shutters, blinds, screens, panels, door leaves and fittings.
It is not applicable to edge effects occurring outside the perimeter of the specimen, energy transfer due to solar radiation on the specimen, effects of air leakage through the specimen, and roof windows and projecting products, where the external face projects beyond the cold side roof surface.
|
Published |
2010-07 |
Edition : 2 |
Number of pages : 53 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 12567-1:2010/Cor 1:2010 |
Thermal performance of windows and doors — Determination of thermal transmittance by the hot-box method — Part 1: Complete windows and doors — Technical Corrigendum 1 |
|
Published |
2010-11 |
Edition : 2 |
Number of pages : 2 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 12567-2:2005 |
Thermal performance of windows and doors — Determination of thermal transmittance by hot box method — Part 2: Roof windows and other projecting windows |
ISO 12567-2:2005 specifies a method to measure the thermal transmittance of roof windows and projecting windows. It does not include: edge effects occurring outside the perimeter of the specimen, energy transfer due to solar radiation on the specimen and effects of air leakage through the specimen.
|
Published |
2005-10 |
Edition : 1 |
Number of pages : 25 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 12569:2000 |
Thermal performance of buildings — Determination of air change in buildings — Tracer gas dilution method |
|
Withdrawn |
2000-11 |
Edition : 1 |
Number of pages : 22 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12569:2012 |
Thermal performance of buildings and materials — Determination of specific airflow rate in buildings — Tracer gas dilution method |
ISO 12569:2012 establishes an engineering standard by which to obtain the ventilation rate/specific airflow rate, using a tracer gas in a building space, which is considered to be of a single zone.
The measurement method is valid in spaces where the combined conditions concerning the uniformity of tracer gas concentration, measurement of the exhaust gas concentration, effective mixed zone and/or fluctuation of ventilation are satisfied.
ISO 12569:2012 provides three measurement methods using a tracer gas: (1) concentration decay method, (2) continuous dose method, and (3) constant concentration method.
|
Withdrawn |
2012-12 |
Edition : 2 |
Number of pages : 54 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12569:2017 |
Thermal performance of buildings and materials — Determination of specific airflow rate in buildings — Tracer gas dilution method |
ISO 12569:2017 establishes methods to obtain the ventilation rate or specific airflow rate in a building space (which is considered to be a single zone) using a tracer gas.
The measurement methods apply for spaces where the combined conditions concerning the uniformity of tracer gas concentration, measurement of the exhaust gas concentration, effective mixed zone and/or fluctuation of ventilation are satisfied.
ISO 12569:2017 provides three measurement methods using a tracer gas: concentration decay method, continuous dose method, and constant concentration method.
NOTE Specific measurement conditions are given in Table 1.
|
Published |
2017-08 |
Edition : 3 |
Number of pages : 53 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12572:2001 |
Hygrothermal performance of building materials and products — Determination of water vapour transmission properties |
|
Withdrawn |
2001-06 |
Edition : 1 |
Number of pages : 27 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12572:2016 |
Hygrothermal performance of building materials and products — Determination of water vapour transmission properties — Cup method |
ISO 12572:2016 specifies a method based on cup tests for determining the water vapour permeance of building products and the water vapour permeability of building materials under isothermal conditions. Different sets of test conditions are specified.
The general principles are applicable to all hygroscopic and non-hygroscopic building materials and products, including insulation materials and including those with facings and integral skins. Annexes give details of test methods suitable for different material types.
The results obtained by this method are suitable for design purposes, production control and for inclusion in product specifications.
|
Published |
2016-08 |
Edition : 2 |
Number of pages : 28 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 14857:2014 |
Thermal performance in the built environment — Determination of air permeance of building materials |
ISO 14857:2014 specifies the equipment and procedures to determine the air permeance of building materials at various pressure differentials and then assigning an air permeance rate at a reference pressure differential rate (ΔP) of 75 Pa.
This method is intended for testing materials independent of a substrate using a 1 m × 1 m specimen size. The results of this test method can be used to determine whether a material qualifies to function as an air barrier material.
|
Published |
2014-02 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12574-2:2008 |
Thermal insulation — Cellulose-fibre loose-fill for horizontal applications in ventilated roof spaces — Part 2: Principal responsibilities of installers |
ISO 12574-2:2008 gives the principal responsibilities of the installers of cellulose-fibre loose-fill thermal insulation products for buildings. If a product is manufactured and packaged according to ISO 12574-1 and then installed in ventilated roof spaces as described in ISO 9774, it is expected to provide the properties declared by the manufacturer.
ISO 12574-2:2008 gives the principal responsibilities of the installer in the installation of the product, in the documentation of the installation and in the declaration that all requirements of this part of ISO 12574 have been met.
ISO 12574-2:2008 does not specify fitness of the product for the intended use beyond those aspects relating to installation. Many aspects relating to the fitness for use are specified in government regulations. It is necessary that the installer ensure, when installing the product, that the product installed is suitable for the application, based on the government regulations and the manufacturer's recommendations.
The installer can be required to meet ancillary (additional) requirements that are specified in local regulations or the customer's requirements.
|
Withdrawn |
2008-09 |
Edition : 1 |
Number of pages : 12 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12575-1:2012 |
Thermal insulation products — Exterior insulating systems for foundations — Part 1: Material specification |
ISO 12575-1:2012 specifies the basic performance requirements for the insulating materials that form part of insulating systems used on the exterior of foundations and slabs where the insulation is in direct contact with the ground. ISO 12575-1:2012 does not address exterior insulating systems for foundations permanently immersed in water.
|
Published |
2012-10 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12575-2:2007 |
Thermal insulation products — Exterior insulating systems for foundations — Part 2: Principal responsibilities of installers |
ISO 12575-2:2007 specifies the responsibilities of the installers of exterior insulating systems for foundations such that a product that is manufactured and packaged in accordance with ISO 12575-1 is able to provide the properties declared by the manufacturer when installed according to ISO 12575-2:2007.
ISO 12575-2:2007 stipulates responsibilities of the installer in the installation of the exterior insulation system, documentation of the installation and a declaration by the installer that all requirements of ISO 12575-2:2007 have been met.
ISO 12575-2:2007 does not specify the fitness of the product for the intended use beyond those aspects relating to installation. Many aspects relating to the fitness for use are specified in ISO 12575-1.
The installer can be required to meet additional requirements specified in local regulations or the customer's requirements.
|
Published |
2007-10 |
Edition : 1 |
Number of pages : 3 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12631:2012 |
Thermal performance of curtain walling — Calculation of thermal transmittance |
|
Withdrawn |
2012-10 |
Edition : 1 |
Number of pages : 49 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12631:2017 |
Thermal performance of curtain walling — Calculation of thermal transmittance |
ISO 12631:2017 specifies a method for calculating the thermal transmittance of curtain walls consisting of glazed and/or opaque panels fitted in, or connected to, frames.
The calculation includes:
- different types of glazing, e.g. glass or plastic; single or multiple glazing; with or without low emissivity coating; with cavities filled with air or other gases;
- frames (of any material) with or without thermal breaks;
- different types of opaque panels clad with metal, glass, ceramics or any other material.
Thermal bridge effects at the rebate or connection between the glazed area, the frame area and the panel area are included in the calculation.
The calculation does not include:
- effects of solar radiation;
- heat transfer caused by air leakage;
- calculation of condensation;
- effect of shutters;
- additional heat transfer at the corners and edges of the curtain walling;
- connections to the main building structure nor through fixing lugs;
- curtain wall systems with integrated heating.
NOTE Table 1 in the Introduction shows the relative position of ISO 12631:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1.
|
Published |
2017-06 |
Edition : 2 |
Number of pages : 47 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 12655:2013 |
Energy performance of buildings — Presentation of measured energy use of buildings |
ISO 12655:2013 sets out a consistent methodology to present energy use in buildings, which is specified clearly with the energy usage, corresponding boundary and the energy data (presented with original energy carriers or equivalent energy).
ISO 12655:2013 is applicable to the presentation of energy use of civil buildings for data collection, metering, statistics, audit and analysis.
|
Published |
2013-03 |
Edition : 1 |
Number of pages : 14 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13370:1998 |
Thermal performance of buildings — Heat transfer via the ground — Calculation methods |
|
Withdrawn |
1998-10 |
Edition : 1 |
Number of pages : 47 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 18393-1:2012 |
Thermal insulation products — Determination of ageing by settlement — Part 1: Blown loose-fill insulation for ventilated attics |
ISO 18393-1:2012 specifies a test method for the determination of settlement of blown loose-fill insulation applied horizontally in ventilated attics.
|
Published |
2012-07 |
Edition : 1 |
Number of pages : 4 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13370:2007 |
Thermal performance of buildings — Heat transfer via the ground — Calculation methods |
ISO 13370:2007 provides methods of calculation of heat transfer coefficients and heat flow rates for building elements in thermal contact with the ground, including slab-on-ground floors, suspended floors and basements. It applies to building elements, or parts of them, below a horizontal plane in the bounding walls of the building situated
for slab-on-ground floors, suspended floors and unheated basements, at the level of the inside floor surface;
for heated basements, at the level of the external ground surface.
ISO 13370:2007 includes calculation of the steady-state part of the heat transfer (the annual average rate of heat flow) and the part due to annual periodic variations in temperature (the seasonal variations of the heat flow rate about the annual average). These seasonal variations are obtained on a monthly basis and, except for the application to dynamic simulation programmes in Annex D, ISO 13370:2007 does not apply to shorter periods of time.
|
Withdrawn |
2007-12 |
Edition : 2 |
Number of pages : 48 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13370:2017 |
Thermal performance of buildings — Heat transfer via the ground — Calculation methods |
ISO 13370:2017 provides methods of calculation of heat transfer coefficients and heat flow rates for building elements in thermal contact with the ground, including slab‐on‐ground floors, suspended floors and basements. It applies to building elements, or parts of them, below a horizontal plane in the bounding walls of the building situated
- at the level of the inside floor surface, for slab‐on‐ground floors, suspended floors and unheated basements;
NOTE 1 In some cases, external dimension systems define the boundary at the lower surface of the floor slab.
- at the level of the external ground surface, for heated basements.
ISO 13370:2017 includes calculation of the steady‐state part of the heat transfer (the annual average rate of heat flow) and the part due to annual periodic variations in temperature (the seasonal variations of the heat flow rate about the annual average). These seasonal variations are obtained on a monthly basis and, except for the application to dynamic simulation programmes in Annex D, ISO 13370:2017 does not apply to shorter periods of time.
NOTE 2 Table 1 in the Introduction shows the relative position of ISO 13370:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1.
|
Published |
2017-06 |
Edition : 3 |
Number of pages : 49 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13786:1999 |
Thermal performance of building components — Dynamic thermal characteristics — Calculation methods |
|
Withdrawn |
1999-09 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
91.060.01
Elements of buildings in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 13786:2007 |
Thermal performance of building components — Dynamic thermal characteristics — Calculation methods |
ISO 13786:2007 specifies the characteristics related to the dynamic thermal behaviour of a complete building component and provides methods for their calculation. It also specifies the information on building materials required for the use of the building component. Since the characteristics depend on the way materials are combined to form building components, ISO 13786:2007 is not applicable to building materials or to unfinished building components.
The definitions given in ISO 13786:2007 are applicable to any building component. A simplified calculation method is provided for plane components consisting of plane layers of substantially homogeneous building materials.
Annex A specifies simpler methods for the estimation of the heat capacities in some limited cases. These methods are suitable for the determination of dynamic thermal properties required for the estimation of energy use. These approximations are not appropriate, however, for product characterization.
Annex B gives the basic principle and examples of applications of the dynamic thermal characteristics defined in ISO 13786:2007.
Annex C provides information for programming the calculation method.
Annex D gives an example of calculation for a building component.
|
Withdrawn |
2007-12 |
Edition : 2 |
Number of pages : 22 |
Technical Committee |
91.060.01
Elements of buildings in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 13786:2017 |
Thermal performance of building components — Dynamic thermal characteristics — Calculation methods |
ISO 13786:2017 specifies the characteristics related to the dynamic thermal behaviour of a complete building component and provides methods for their calculation. It also specifies the information on building materials required for the use of the building component. Since the characteristics depend on the way materials are combined to form building components, ISO 13786:2017 is not applicable to building materials or to unfinished building components.
The definitions given in ISO 13786:2017 are applicable to any building component. A simplified calculation method is provided for plane components consisting of plane layers of substantially homogeneous building materials.
Annex C provides simpler methods for the estimation of the heat capacities in some limited cases. These methods are suitable for the determination of dynamic thermal properties required for the estimation of energy consumption. These approximations are not appropriate, however, for product characterization.
NOTE Table 1 in the Introduction shows the relative position of ISO 13786:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1.
|
Published |
2017-06 |
Edition : 3 |
Number of pages : 19 |
Technical Committee |
91.060.01
Elements of buildings in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 13788:2001 |
Hygrothermal performance of building components and building elements — Internal surface temperature to avoid critical surface humidity and interstitial condensation — Calculation methods |
|
Withdrawn |
2001-07 |
Edition : 1 |
Number of pages : 31 |
Technical Committee |
91.060.01
Elements of buildings in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 13788:2012 |
Hygrothermal performance of building components and building elements — Internal surface temperature to avoid critical surface humidity and interstitial condensation — Calculation methods |
ISO 13788:2012 gives simplified calculation methods for:
The internal surface temperature of a building component or building element below which mould growth is likely, given the internal temperature and relative humidity. The method can also be used to assess the risk of other internal surface condensation problems.
The assessment of the risk of interstitial condensation due to water vapour diffusion. The method used does not take account of a number of important physical phenomena including the variation of material properties with moisture content; capillary suction and liquid moisture transfer within materials; air movement from within the building into the component through gaps or within air spaces; the hygroscopic moisture capacity of materials.
The time taken for water, from any source, in a layer between two high vapour resistance layers to dry out and the risk of interstitial condensation occurring elsewhere in the component during the drying process.
|
Published |
2012-12 |
Edition : 2 |
Number of pages : 40 |
Technical Committee |
91.060.01
Elements of buildings in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 13789:1999 |
Thermal performance of buildings — Transmission heat loss coefficient — Calculation method |
|
Withdrawn |
1999-09 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13789:2007 |
Thermal performance of buildings — Transmission and ventilation heat transfer coefficients — Calculation method |
ISO 13789:2007 specifies a method and provides conventions for the calculation of the steady-state transmission and ventilation heat transfer coefficients of whole buildings and parts of buildings. It is applicable both to heat loss (internal temperature higher than external temperature) and to heat gain (internal temperature lower than external temperature). For the purpose of ISO 13789:2007, the heated or cooled space is assumed to be at uniform temperature.
|
Withdrawn |
2007-12 |
Edition : 2 |
Number of pages : 18 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13789:2017 |
Thermal performance of buildings — Transmission and ventilation heat transfer coefficients — Calculation method |
ISO 13789:2017 specifies a method and provides conventions for the calculation of the steady‐state transmission and ventilation heat transfer coefficients of whole buildings and parts of buildings. It is applicable both to heat loss (internal temperature higher than external temperature) and to heat gain (internal temperature lower than external temperature). For the purpose of ISO 13789:2017, the heated or cooled space is assumed to be at uniform temperature.
Annex C provides a steady‐state method to calculate the temperature in unconditioned spaces adjacent to conditioned spaces.
NOTE Table 1 in the Introduction shows the relative position of ISO 13789:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1.
|
Published |
2017-06 |
Edition : 3 |
Number of pages : 24 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13790:2004 |
Thermal performance of buildings — Calculation of energy use for space heating |
ISO 13790:2004 gives a simplified calculation method for assessment of the annual energy use for space heating of a residential or a non-residential building, or a part of it, which will be referred to as "the building".
It does not apply to buildings with air conditioning systems likely to provide space cooling during the heating season.
This method includes the calculation of: the heat losses of the building when heated to constant internal temperature; the annual heat required to maintain the specified set-point temperatures in the building; the annual energy required by the heating system of the building for space heating, using heating system characteristics which are to be found in specific European or International standards, or, by default, in national documents.
|
Withdrawn |
2004-06 |
Edition : 1 |
Number of pages : 59 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13790:2008 |
Energy performance of buildings — Calculation of energy use for space heating and cooling |
ISO 13790:2008 gives calculation methods for assessment of the annual energy use for space heating and cooling of a residential or a non-residential building, or a part of it, referred to as “the building”.
This method includes the calculation of:
the heat transfer by transmission and ventilation of the building zone when heated or cooled to constant internal temperature;
the contribution of internal and solar heat gains to the building heat balance;
the annual energy needs for heating and cooling, to maintain the specified set-point temperatures in the building – latent heat not included;
the annual energy use for heating and cooling of the building, using input from the relevant system standards referred to in ISO 13790:2008 and specified in Annex A.
ISO 13790:2008 also gives an alternative simple hourly method, using hourly user schedules (such as temperature set-points, ventilation modes or operation schedules of movable solar shading).
Procedures are given for the use of more detailed simulation methods to ensure compatibility and consistency between the application and results of the different types of method. ISO 13790:2008 provides, for instance, common rules for the boundary conditions and physical input data irrespective of the calculation approach chosen.
ISO 13790:2008 has been developed for buildings that are, or are assumed to be, heated and/or cooled for the thermal comfort of people, but can be used for other types of building or other types of use (e.g. industrial, agricultural, swimming pool), as long as appropriate input data are chosen and the impact of special physical conditions on the accuracy is taken into consideration.
The calculation procedures in ISO 13790:2008 are restricted to sensible heating and cooling. The energy use due to humidification is calculated in the relevant standard on the energy performance of ventilation systems, as specified in Annex A; similarly, the energy use due to dehumidification is calculated in the relevant standard on the energy performance of space cooling systems, as specified in Annex A.
ISO 13790:2008 is applicable to buildings at the design stage and to existing buildings. The input data directly or indirectly called for by ISO 13790:2008 should be available from the building files or the building itself. If this is not the case, it is explicitly stated at relevant places in ISO 13790:2008 that it may be decided at national level to allow for other sources of information. In this case, the user reports which input data have been used and from which source. Normally, for the assessment of the energy performance for an energy performance certificate, a protocol is defined at national or regional level to specify the type of sources of information and the conditions when they may be applied instead of the full required input.
|
Withdrawn |
2008-03 |
Edition : 2 |
Number of pages : 162 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 11254-1:2000 |
Lasers and laser-related equipment — Determination of laser-induced damage threshold of optical surfaces — Part 1: 1-on-1 test |
|
Withdrawn |
2000-06 |
Edition : 1 |
Number of pages : 23 |
Technical Committee |
31.260
Optoelectronics. Laser equipment
|
| ISO 13791:2004 |
Thermal performance of buildings — Calculation of internal temperatures of a room in summer without mechanical cooling — General criteria and validation procedures |
ISO 13791:2004 specifies the assumptions, boundary conditions, equations and validation tests for a calculation procedure, under transient hourly conditions, of the internal temperatures (air and operative) during the warm period, of a single room without any cooling/heating equipment in operation. No specific numerical techniques are imposed by this standard. Validation tests are included. An example of a solution technique is given in Annex A.
ISO 13791:2004 does not contain sufficient information for defining a procedure able to determine the internal conditions of special zones such as attached sun spaces, atria, indirect passive solar components (Trombe walls, solar panels) and zones in which the solar radiation may pass through the room. For such situations different assumptions and more detailed solution models are needed.
|
Withdrawn |
2004-11 |
Edition : 1 |
Number of pages : 84 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13791:2012 |
Thermal performance of buildings — Calculation of internal temperatures of a room in summer without mechanical cooling — General criteria and validation procedures |
ISO 13791:2011 specifies the assumptions, boundary conditions, equations and validation tests for a calculation procedure, under transient hourly conditions, of the internal temperatures (air and operative) during warm periods, of a single room without any cooling/heating equipment in operation.
|
Withdrawn |
2012-03 |
Edition : 2 |
Number of pages : 96 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13792:2005 |
Thermal performance of buildings — Calculation of internal temperatures of a room in summer without mechanical cooling — Simplified methods |
ISO 13792:2005 specifies the required input data for simplified calculation methods for determining the maximum, average and minimum daily values of the operative temperature of a room in the warm period to define the characteristics of a room in order to avoid overheating in summer at the design stage, and to define whether the installation of a cooling system is necessary or not.
The criteria to be met by a calculation method in order to satisfy this standard are also given.
|
Withdrawn |
2005-03 |
Edition : 1 |
Number of pages : 49 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13792:2012 |
Thermal performance of buildings — Calculation of internal temperatures of a room in summer without mechanical cooling — Simplified methods |
ISO 13792:2011 specifies the required input data for simplified calculation methods for determining the maximum, average and minimum daily values of the operative temperature of a room in warm periods:
a) to define the characteristics of a room at the design stage in order to avoid overheating in summer;
b) to define whether the installation of a cooling system is necessary or not.
|
Withdrawn |
2012-03 |
Edition : 2 |
Number of pages : 54 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 13793:2001 |
Thermal performance of buildings - Thermal design of foundations to avoid frost heave |
|
Published |
2001-03 |
Edition : 1 |
Number of pages : 42 |
Technical Committee |
93.020
Earthworks. Excavations. Foundation construction. Underground works
;
91.120.10
Thermal insulation of buildings
|
| ISO 14438:2002 |
Glass in building — Determination of energy balance value — Calculation method |
This European Standard specifies a calculation method to determine the energy balance value of glazing. This
European Standard applies to transparent materials such as glass and combinations of glass used to glaze
windows in buildings.
This method is intended to evaluate the balance of heat loss and useful heat gain by solar radiation entering the
building through the glazing for a given period by means of an average rate of loss (or gain) of heat called the
energy balance value.
The method enables producers to compare the performance of their glazing products. The energy balance value
should not be used for energy use or heating capacity calculations in buildings.
|
Published |
2002-06 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
81.040.20
Glass in building
;
91.120.10
Thermal insulation of buildings
|
| ISO 14683:1999 |
Thermal bridges in building construction — Linear thermal transmittance — Simplified methods and default values |
|
Withdrawn |
1999-07 |
Edition : 1 |
Number of pages : 24 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 14683:2007 |
Thermal bridges in building construction — Linear thermal transmittance — Simplified methods and default values |
ISO 14683:2007 deals with simplified methods for determining heat flows through linear thermal bridges which occur at junctions of building elements.
ISO 14683:2007 specifies requirements relating to thermal bridge catalogues and manual calculation methods.
Default values of linear thermal transmittance are given in Annex A for information.
|
Withdrawn |
2007-12 |
Edition : 2 |
Number of pages : 23 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 14683:2017 |
Thermal bridges in building construction — Linear thermal transmittance — Simplified methods and default values |
|
Published |
2017-06 |
Edition : 3 |
Number of pages : 25 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 11254-2:2001 |
Lasers and laser-related equipment — Determination of laser-induced damage threshold of optical surfaces — Part 2: S-on-1 test |
|
Withdrawn |
2001-09 |
Edition : 1 |
Number of pages : 28 |
Technical Committee |
31.260
Optoelectronics. Laser equipment
|
| ISO 15099:2003 |
Thermal performance of windows, doors and shading devices — Detailed calculations |
ISO 15099:2003 specifies detailed calculation procedures for determining the thermal and optical transmission properties (e.g., thermal transmittance, total solar energy transmittance) of window and door systems based on the most up-to-date algorithms and methods, and the relevant solar and thermal properties of all components.
Products covered by ISO 15099:2003 include windows and doors incorporating:
single and multiple glazed fenestration products with or without solar reflective, low-emissivity coatings and suspended plastic films;glazing systems with pane spacing of any width containing gases or mixtures of gases;metallic or non-metallic spacers;frames of any material and design;fenestration products tilted at any angle;shading devices;projecting products.
|
Published |
2003-11 |
Edition : 1 |
Number of pages : 71 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 15758:2004 |
Hygrothermal performance of building equipment and industrial installations — Calculation of water vapour diffusion — Cold pipe insulation systems |
ISO 15758:2004 specifies a method to calculate the density of water vapour flow rate in cold pipe insulation systems, and the total amount of water diffused into the insulation over time. This calculation method presupposes that water vapour can only migrate into the insulation system by diffusion, with no contribution from airflow. It also assumes the use of homogeneous, isotropic insulation materials so that the water vapour partial pressure is constant at all points equidistant from the axis of the pipe.
ISO 15758:2004 is applicable when the temperature of the medium in the pipe is above 0 °C. It applies to pipes inside buildings as well as in the open air.
|
Withdrawn |
2004-10 |
Edition : 1 |
Number of pages : 15 |
Technical Committee |
91.120.10
Thermal insulation of buildings
;
91.140.01
Installations in buildings in general
|
| ISO 15758:2014 |
Hygrothermal performance of building equipment and industrial installations — Calculation of water vapour diffusion — Cold pipe insulation systems |
ISO 15758:2014 specifies a method for calculating the density of the water vapour flow rate in cold pipe insulation systems, and the total amount of water diffused into the insulation over time. The calculation method presupposes that water vapour can only migrate into the insulation system by diffusion, with no contribution from airflow. It also assumes the use of homogeneous, isotropic insulation materials so that the water vapour partial pressure is constant at all points equidistant from the axis of the pipe.
ISO 15758:2014 is applicable when the temperature of the medium in the pipe is above 0 °C. It applies to pipes inside buildings as well as in the open air.
|
Published |
2014-05 |
Edition : 2 |
Number of pages : 15 |
Technical Committee |
91.120.10
Thermal insulation of buildings
;
91.140.01
Installations in buildings in general
|
| ISO 15927-1:2003 |
Hygrothermal performance of buildings — Calculation and presentation of climatic data — Part 1: Monthly means of single meteorological elements |
ISO 15927-1:2003 specifies procedures for calculating and presenting the monthly means of those parameters of climatic data needed to assess some aspects of the thermal and moisture performance of buildings. Numerical values for any locations should be obtained from the meteorological service in the relevant country.
ISO 15927-1:2003 covers the following single climate variables: air temperature; atmospheric humidity; wind speed; precipitation; solar radiation; longwave radiation.
Meteorological instrumentation and methods of observation are not covered; these are specified by the World Meteorological Organisation (WMO).
|
Published |
2003-11 |
Edition : 1 |
Number of pages : 26 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 15927-2:2009 |
Hygrothermal performance of buildings — Calculation and presentation of climatic data — Part 2: Hourly data for design cooling load |
ISO 15927-2:2009 gives the definition, and specifies methods of calculation and presentation of the monthly external design climate to be used in determining the design cooling load of buildings and the design of air conditioning systems.
|
Published |
2009-02 |
Edition : 1 |
Number of pages : 8 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 15927-3:2009 |
Hygrothermal performance of buildings - Calculation and presentation of climatic data — Part 3: Calculation of a driving rain index for vertical surfaces from hourly wind and rain data |
ISO 15927-3:2009 specifies two procedures for providing an estimate of the quantity of water likely to impact on a wall of any given orientation. It takes account of topography, local sheltering and the type of building and wall.
The first method, based on coincident hourly rainfall and wind data, defines the method of calculation of the annual average index, which influences the moisture content of an absorbent surface, such as masonry, and the spell index, which influences the likelihood of rain penetration through masonry and joints in other walling systems.
The second method, based on average wind data and a qualitative recording of the presence and intensity of rain (the present weather code for rain), defines a method for calculating the spell length during which an absorbent material such as masonry is moistened, having a 10 % probability of being exceeded in any year (commonly referred to as having a mean return period of 10 years).
ISO 15927-3:2009 provides a comparison between the two methods.
ISO 15927-3:2009 gives procedures to correct the results of both methods for topography, local sheltering and the type of building and wall.
The methods included in ISO 15927-3:2009 do not apply in mountainous areas with sheer cliffs or deep gorges, in areas in which more than 25 % of the annual rainfall comes from severe convective storms, and in areas and during periods when a significant proportion of precipitation is made up of snow or hail.
|
Published |
2009-03 |
Edition : 1 |
Number of pages : 17 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 5004:1987 |
Earth-moving machinery — Test method for measurement of tool movement time |
|
Withdrawn |
1987-04 |
Edition : 2 |
Number of pages : 3 |
Technical Committee |
53.100
Earth-moving machinery
|
| ISO 15927-4:2005 |
Hygrothermal performance of buildings — Calculation and presentation of climatic data — Part 4: Hourly data for assessing the annual energy use for heating and cooling |
ISO 15927-4:2005 specifies a method for constructing a reference year of hourly values of appropriate meteorological data suitable for assessing the average annual energy for heating and cooling. Other reference years representing average conditions can be constructed for special purposes. The procedures in this part of ISO 15927-4:2005 are not suitable for constructing extreme or semi-extreme years for simulation of, for example, moisture damage or energy demand in cold years.
Meteorological instrumentation and methods of observation are not covered.
|
Published |
2005-07 |
Edition : 1 |
Number of pages : 5 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 15927-5:2004 |
Hygrothermal performance of buildings — Calculation and presentation of climatic data — Part 5: Data for design heat load for space heating |
ISO 15927-5:2004 specifies the definition, method of calculation and method of presentation of the climatic data to be used in determining the design heat load for space heating in buildings. These include the winter external design air temperatures and the relevant wind speed and direction, where appropriate.
Heat loss through the ground, which also contributes to the heat load for buildings, depends on longer-term temperature changes; methods for calculating ground heat loss are given in ISO 13370.
|
Published |
2004-11 |
Edition : 1 |
Number of pages : 6 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 15927-5:2004/Amd 1:2011 |
Hygrothermal performance of buildings — Calculation and presentation of climatic data — Part 5: Data for design heat load for space heating — Amendment 1 |
|
Published |
2011-11 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 15927-6:2007 |
Hygrothermal performance of buildings — Calculation and presentation of climatic data — Part 6: Accumulated temperature differences (degree-days) |
ISO 15927-6:2007 specifies the definition, method of computation and method of presentation of data on accumulated temperature differences, used for assessing the energy used for space heating in buildings. These are normally expressed in degree‑hours or degree-days, and such data are often referred to simply as "heating degree-hours" or "heating degree-days".
ISO 15927-6:2007 includes approximate methods for calculating accumulated temperature differences based on hourly or daily mean temperatures and for estimating monthly values to any base temperature, for use when data computed directly from meteorological air temperature records are not available.
In some countries, a threshold temperature different from the base temperature is used. ISO 15927-6:2007 does not cover this.
|
Published |
2007-09 |
Edition : 1 |
Number of pages : 13 |
Technical Committee |
07.060
Geology. Meteorology. Hydrology
;
91.120.10
Thermal insulation of buildings
|
| ISO 16343:2013 |
Energy performance of buildings — Methods for expressing energy performance and for energy certification of buildings |
ISO 16346:2013 sets out ways of expressing the energy performance in an energy performance certificate of a building (including the technical building systems) and ways of expressing requirements as to the energy performance. This includes an overall numerical energy performance indicator and classes against benchmarks.
ISO 16346:2013 additionally includes numerical indicators at system or component level.
ISO 16346:2013 defines the different types of rating (such as calculated, measured, design, and tailored rating) and the energy uses to take into account (such as heating, cooling, domestic hot water, ventilation, and lighting).
ISO 16346:2013 defines
a) overall indicators to express the energy performance of whole buildings, including heating, ventilation, air conditioning, domestic hot water, and lighting systems (this includes different possible indicators),
b) ways to express energy requirements for the design of new buildings or renovation of existing buildings,
c) procedures to define reference values, and
d) ways to design a procedure for building energy certification.
Furthermore, it provides a (calculation) link between delivered energy and the energy performance indicators for buildings. Since a building generally uses more than one fuel (e.g. gas and electricity), the different energy sources are collected per energyware. The overall rating is based on a weighted sum of delivered energywares. The weightings can be related to, for instance, primary energy or CO2 emissions to provide the end result of the calculation of energy performance.
It also provides calculation procedures to assess the energy performance on the basis of measured energy use, including ways to convert the measured values to values under standardized conditions (environment, user).
Finally, it defines the system boundaries needed to make a distinction between building energy needs, technical building systems, energy supply systems on site, and distant energy supply systems.
|
Withdrawn |
2013-07 |
Edition : 1 |
Number of pages : 35 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO/TR 16344:2012 |
Energy performance of buildings — Common terms, definitions and symbols for the overall energy performance rating and certification |
ISO/TR 16344:2012 provides a coherent set of terms, definitions and symbols for concepts and physical quantities related to the overall energy performance of buildings and its components, including definitions of system boundaries, to be used in all standards elaborated within ISO on energy performance of buildings.
These terms and definitions are applicable to energy calculations in accordance with the Technical Report and standards on the overall energy performance of buildings and their components, to provide input to the Technical Report or using output from the Technical Report. They are based on existing terms and definitions from standards and other documents referenced in the bibliography.
|
Withdrawn |
2012-10 |
Edition : 1 |
Number of pages : 40 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO/DIS 18393-1 |
Thermal insulation products — Determination of ageing by settlement — Part 1: Blown loose fill insulation for ventilated attics simulating humidity and temperature cycling |
|
Under development |
|
Edition : 2 |
Number of pages : 4 |
Technical Committee |
91.120.10
Thermal insulation of buildings
;
91.120.10
Thermal insulation of buildings
|
| ISO 16346:2013 |
Energy performance of buildings — Assessment of overall energy performance |
ISO 16346:2013 defines the general procedures to assess the energy performance of buildings, including technical building systems, and defines the different types of ratings, and the building boundaries.
The purpose of ISO 16346:2013 is to
a) collate results from other International Standards that calculate energy use for specific services within a building,
b) account for energy generated in the building, some of which may be exported for use elsewhere,
c) present a summary of the overall energy use of the building in tabular form,
d) provide energy ratings based on primary energy, carbon dioxide emission, or other parameters defined by a national energy policy, and
e) establish general principles for the calculation of primary energy factors and carbon dioxide emission coefficients.
ISO 16346:2013 defines the energy services to be taken into account for setting energy performance ratings for planned and existing buildings and provides for
1) a method to compute the standard calculated energy rating, a standard energy use that does not depend on occupant behaviour, actual weather, and other actual (environment or indoor) conditions,
2) a method to assess the measured energy rating, based on the delivered and exported energy,
3) a method to improve confidence in the building calculation model by comparison with actual energy use, and
4) a method to assess the energy effectiveness of possible improvements.
ISO 16346:2013 is applicable to a part of a building (e.g. flat), a whole building, or several buildings.
|
Withdrawn |
2013-10 |
Edition : 1 |
Number of pages : 62 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 16956:2015 |
Thermal performance in the built environment — Determination of air flow rate in building applications by field measuring methods |
In the cooling and heating loads of a building, the air taken in from outside account for a large portion of the entire load; in order to estimate this load, it is necessary to correctly grasp the air flow rate of ventilation and air-conditioning systems. This International Standard stipulates the methods for measuring the rate of air flow through the ducts in a steadily operating ventilation and air-conditioning system and in the air control ports including air diffuser, suction opening, and exhaust opening.
|
Published |
2015-02 |
Edition : 1 |
Number of pages : 23 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 17772-1:2017 |
Energy performance of buildings — Indoor environmental quality — Part 1: Indoor environmental input parameters for the design and assessment of energy performance of buildings |
ISO 17772-1:2017 specifies requirements for indoor environmental parameters for thermal environment, indoor air quality, lighting and acoustics and specifies how to establish these parameters for building system design and energy performance calculations.
It includes design criteria for the local thermal discomfort factors, draught, radiant temperature asymmetry, vertical air temperature differences and floor surface temperature.
ISO 17772-1:2017 is applicable where the criteria for indoor environment are set by human occupancy and where the production or process does not have a major impact on indoor environment.
It also specifies occupancy schedules to be used in standard energy calculations and how different categories of criteria for the indoor environment can be used.
The criteria in ISO 17772-1:2017can also be used in national calculation methods. ISO 17772-1:2017 sets criteria for the indoor environment based on existing standards and reports (listed in Clause 2 and the Bibliography).
The document does not specify design methods, but gives input parameters to the design of building envelope, heating, cooling, ventilation and lighting.
|
Published |
2017-06 |
Edition : 1 |
Number of pages : 60 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO/TR 17772-2:2018 |
Energy performance of buildings — Overall energy performance assessment procedures — Part 2: Guideline for using indoor environmental input parameters for the design and assessment of energy performance of buildings |
ISO/TR 17772-2:2018 deals with the indoor environmental parameters for thermal environment, indoor air quality, lighting and acoustic. It explains how to use ISO 17772‑1 for specifying indoor environmental input parameters for building system design and energy performance calculations.
ISO/TR 17772-2:2018:
- specifies methods for long-term evaluation of the indoor environment obtained as a result of calculations or measurements;
- specifies criteria for measurements which can be used if required to measure compliance by inspection;
- identifies parameters to be used by monitoring and displaying the indoor environment in existing buildings.
ISO/TR 17772-2:2018 is applicable where the criteria for indoor environment are set by human occupancy and where the production or process does not have a major impact on indoor environment. It explains how different categories of criteria for the indoor environment can be used.
|
Published |
2018-04 |
Edition : 1 |
Number of pages : 70 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 18292:2011 |
Energy performance of fenestration systems for residential buildings — Calculation procedure |
ISO 18292:2011 specifies a procedure for calculation of the energy performance of fenestration systems used in residential buildings, for rating of fenestration systems, doors and skylights, including the effects of frame, sash, glazing, and shading components. ISO 18292:2011 specifies procedures for the calculation of the heating and cooling energy use in residential buildings, internal and external climatic conditions, and relevant building characteristics.
These procedures can accommodate all climatic conditions and installation details. It is the responsibility of the appropriate regulatory authority to identify the clauses of ISO 18292:2011 to be applied in their area of jurisdiction and the climatic data and reference building specification(s) to be used.
|
Published |
2011-04 |
Edition : 1 |
Number of pages : 33 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 18292:2011/Cor 1:2012 |
Energy performance of fenestration systems for residential buildings — Calculation procedure — Technical Corrigendum 1 |
|
Published |
2012-04 |
Edition : 1 |
Number of pages : 1 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 18523-1:2016 |
Energy performance of buildings — Schedule and condition of building, zone and space usage for energy calculation — Part 1: Non-residential buildings |
ISO 18523-1:2016 specifies the formats to present schedule and condition of building, zone and space usage, which is to be referred to as input data of energy calculations for non-residential buildings.
The schedule and condition include schedules of occupancy, operation of technical building systems, ventilation rate, hot water usage and internal heat gains due to occupancy, lighting and equipment.
ISO 18523-1:2016 also gives categories of building, zone and space according to differentiating schedule and condition.
Depending on necessary minuteness of the energy calculation, different levels of schedule and condition from the view point of time and space averaging are specified.
The values and categories for the schedule and condition are given in annexes for more information for the application when the users of this document do not have detailed information on the values and categories for the schedule and condition.
The schedule and condition in this document is basically different from assumptions in order to determine the size of technical building systems in the process of design, where possible largest values are to be assumed. Instead, most usual and average values, which are assumed for the building energy calculation, are dealt with in this document.
|
Published |
2016-11 |
Edition : 1 |
Number of pages : 253 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 18523-2:2018 |
Energy performance of buildings — Schedule and condition of building, zone and space usage for energy calculation — Part 2: Residential buildings |
ISO 18523-2:2018 specifies the formats to present the schedule and conditions of zone and space usage (referred to as input data of energy calculations) for residential buildings.
The schedule and conditions include schedules of occupancy, operation of technical building systems, ventilation rates, hot water usage, usage of appliances and internal heat gains due to occupancy, lighting and appliances. The schedule and conditions for lighting are applicable to fixed installed lighting fixtures.
ISO 18523-2:2018 also gives categories of residential building, zone and space according to differentiating schedule and condition. For residential buildings or its housing units which contain any category of space or zone of non-residential buildings, ISO 18523‑1 applies.
Depending on necessary minuteness of the energy calculation, different levels of schedule and condition from the view point of time and space averaging are specified.
The values and categories for the schedule and condition are included informatively.
NOTE The schedule and condition in this document is basically different from assumptions in order to determine the size of technical building systems in the process of design, where possible largest or smallest values are assumed. Instead, most usual and average values, which are assumed for the building energy calculation, are dealt with in this document.
|
Published |
2018-02 |
Edition : 1 |
Number of pages : 33 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 19467-2:2021 |
Thermal Performance of windows and doors — Determination of solar heat gain coefficient using solar simulator — Part 2: Centre of glazing |
This document specifies a method to measure the solar heat gain coefficient for the centre of glazing in fenestration systems (e.g. complete windows, doors or curtain walls with or without shading devices) for normal and off-normal irradiation on the surface.
This document applies to the centre of glazing in fenestration systems which might consist of:
a) various types of glazing (e.g. glass or plastic; single or multiple glazing; with or without low emissivity coatings, and with spaces filled with air or other gases; opaque or transparent glazing);
b) various types of shading devices (e.g. blind, screen, film or any attachment with shading effects);
c) various types of active solar fenestration systems [e.g. building-integrated PV systems (BIPV) or building-integrated solar thermal collectors (BIST)].
This document does not include:
a) shading effects of building elements (e.g. eaves, sleeve wall, etc.);
b) shading effects of fenestration attachments with overhang structures (e.g., awning, etc.) or similar;
c) shading effects of non-glazing elements in fenestration systems (e.g. window frame, etc.);
d) heat transfer caused by air leakage between indoors and outdoors;
e) ventilation of air spaces in double and coupled windows;
f) thermal bridge effects at the joint between the glazing and the rest of the fenestration parts (e.g. window frame, etc.).
|
Published |
2021-11 |
Edition : 1 |
Number of pages : 32 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 19467:2017 |
Thermal performance of windows and doors — Determination of solar heat gain coefficient using solar simulator |
ISO 19467:2017 specifies a method to measure the solar heat gain coefficient of complete windows and doors.
ISO 19467:2017 applies to windows and doors
a) with various types of glazing (glass or plastic; single or multiple glazing; with or without low emissivity coatings, and with spaces filled with air or other gases),
b) with opaque panels,
c) with various types of frames (wood, plastic, metallic with and without thermal barrier or any combination of materials),
d) with various types of shading devices (blind, screen, film or any attachment with shading effects),
e) with various types of active solar fenestration systems [building-integrated PV systems (BIPV) or building-integrated solar thermal collectors (BIST)].
ISO 19467:2017 does not include the following:
a) shading effects of building elements (e.g. eaves, sleeve wall, etc.);
b) heat transfer caused by air leakage between indoors and outdoors;
c) ventilation of air spaces in double and coupled windows;
d) thermal bridge effects at the rebate or joint between the window or door frame and the rest of the building envelope.
ISO 19467:2017 does not apply to the following:
a) non-vertical windows;
b) curtain walls;
c) industrial, commercial and garage doors.
|
Published |
2017-04 |
Edition : 1 |
Number of pages : 52 |
Technical Committee |
91.060.50
Doors and windows
;
91.120.10
Thermal insulation of buildings
|
| ISO 11807-1:2001 |
Integrated optics — Vocabulary — Part 1: Basic terms and symbols |
|
Withdrawn |
2001-07 |
Edition : 1 |
Number of pages : 21 |
Technical Committee |
31.260
Optoelectronics. Laser equipment
;
01.040.31
Electronics (Vocabularies)
|
| ISO 21105-1:2019 |
Performance of buildings — Building enclosure thermal performance verification and commissioning — Part 1: General requirements |
This document describes a building enclosure commissioning process to achieve a well performing, durable and maintainable building enclosure. This document includes procedures, methods and documentation requirements describing the application of the commissioning process to a building enclosure at each phase of a project. These project phases span from predesign through owner occupancy and operation. This process is referred to throughout this document as building enclosure commissioning (BECx).
This document applies to new building construction and building re-commissioning. This document is for use by an owner, commissioning provider, building developer, owner's representative, construction manager, architect, contractor, and/or consultant, etc. Its purpose is to determine and complete the required tasks and activities to deliver a building enclosure which meets the performance requirements of the owner. Requirements for the project are established by the owner and/or commissioning provider (CxP).
This document identifies steps necessary to perform a building enclosure risk analysis. The analysis will result in tasks that define the level of BECx, commensurate with the owner's tolerance for risk associated with building enclosure performance.
The BECx process covered by this document is applicable to an individual assembly, a combination of assemblies or a whole enclosure assembly. For example, an individual assembly can be the fenestration, the air barrier or the thermal insulation. A combination of assemblies would include the fenestration, the air barrier and the complete heat transfer system, (e.g. both the insulation and roof assembly). A whole building enclosure assembly would include all heat, air and moisture control layers of the building enclosure, on all six sides of the building.
This document describes requirements for any third-party consultants and/or building enclosure commissioning providers (BECxP) to document their technical qualifications, independence and knowledge of the BECx process, including their education, training, and experience.
|
Published |
2019-11 |
Edition : 1 |
Number of pages : 27 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 21129:2007 |
Hygrothermal performance of building materials and products — Determination of water-vapour transmission properties — Box method |
ISO 21129:2007 specifies a box method for determining the water-vapour permeability of building materials. The box method is used primarily to measure the water-vapour permeance of materials that have low water-vapour resistance, in which the influence of the surface-humidity transmission-resistance cannot be ignored.
|
Published |
2007-07 |
Edition : 1 |
Number of pages : 11 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 21773:2021 |
Methods of test and characterization of performance for energy recovery components |
This document specifies methods for testing and characterizing the performance of air-to-air heat/energy exchangers when used as devices to transfer heat or heat and water vapor between two airstreams used in ventilation systems. It also specifies methods to characterize the performance of exchangers for use in calculation of the energy performance of buildings. This document is applicable to:
— fixed-plate exchangers (also known as recuperators),
— rotary exchangers, including heat wheels and total energy wheels (also known as regenerators),
— heat pipe exchangers using a heat transfer medium, excluding those using mechanical pumping.
This document does not provide a method for measuring the response of exchangers to the formation of frost.
|
Published |
2021-06 |
Edition : 1 |
Number of pages : 44 |
Technical Committee |
23.120
Ventilators. Fans. Air-conditioners
;
91.120.10
Thermal insulation of buildings
|
| ISO/FDIS 22097 |
Thermal insulation for buildings — Reflective insulation products — Determination of thermal performance |
|
Under development |
|
Edition : 1 |
Number of pages : 30 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 23993:2008 |
Thermal insulation products for building equipment and industrial installations — Determination of design thermal conductivity |
ISO 23993:2008 gives methods to calculate design thermal conductivities from declared thermal conductivities for the calculation of the thermal performance of building equipment and industrial installations.
These methods are valid for operating temperatures from -200 °C to +800 °C.
The conversion factors, established for the different influences, are valid for the temperature ranges indicated in the relevant clauses or annexes.
|
Published |
2008-02 |
Edition : 1 |
Number of pages : 31 |
Technical Committee |
27.220
Heat recovery. Thermal insulation
;
91.100.60
Thermal and sound insulating materials
;
91.120.10
Thermal insulation of buildings
|
| ISO 24144:2023 |
Thermal insulation — Test methods for specific heat capacity of thermal insulation for buildings in the high temperature range — Differential scanning calorimetry (DSC) method |
This document specifies test methods for specific heat capacity under high temperature conditions from the normal temperature range to 1 600 K for insulation materials for buildings using the differential scanning calorimetry (DSC) method.
|
Published |
2023-01 |
Edition : 1 |
Number of pages : 21 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO/IEC 30134-7:2023 |
Information technology — Data centres key performance indicators — Part 7: Cooling efficiency ratio (CER) |
This document specifies the cooling efficiency ratio (CER) as a key performance indicator (KPI) for quantifying the efficient use of energy to control the temperature of spaces within a data centre (DC).
This document:
a) defines the CER of a DC;
b) describes the relationship of this KPI to a DC’s infrastructure, information technology equipment and information technology operations;
c) defines the measurement, the calculation and the reporting of the parameter; and
d) provides information on the correct interpretation of the CER.
Annex A describes the correlation of the CER and other KPIs.
Annex B provides examples of the usage of the CER.
Annex C introduces the parameters that affect the CER.
Annex D describes requirements and recommendations for derivatives of KPIs associated with the CER.
This document is not applicable to cooling systems that are not powered by electricity (e.g. heat-driven absorption chillers).
|
Published |
2023-03 |
Edition : 1 |
Number of pages : 16 |
Technical Committee |
35.020
Information technology (IT) in general
;
91.120.10
Thermal insulation of buildings
|
| ISO 52000-1:2017 |
Energy performance of buildings — Overarching EPB assessment — Part 1: General framework and procedures |
ISO 52000-1:2017 establishes a systematic, comprehensive and modular structure for assessing the energy performance of new and existing buildings (EPB) in a holistic way.
It is applicable to the assessment of overall energy use of a building, by measurement or calculation, and the calculation of energy performance in terms of primary energy or other energy-related metrics. It takes into account the specific possibilities and limitations for the different applications, such as building design, new buildings 'as built', and existing buildings in the use phase as well as renovation.
NOTE Table 1 in the Introduction shows the relative position of ISO 52000-1:2017 within the set of EPB standards in the context of the modular structure as set out in ISO 52000-1:2017.
|
Published |
2017-06 |
Edition : 1 |
Number of pages : 128 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO/TR 52000-2:2017 |
Energy performance of buildings — Overarching EPB assessment — Part 2: Explanation and justification of ISO 52000-1 |
ISO/TR 52000-2:2017 refers to the overarching EPB-standard, ISO 52000‑1[1].
It contains information to support the correct understanding, use and national implementation of ISO 52000‑1. This includes:
- explanation on the procedures and background information and justification of the choices that have been made;
- reporting on validation of calculation procedures given in the standard;
- explanation for the user and for national standards writers involved with implementation of the set of EPB standards, including detailed examples.
|
Published |
2017-06 |
Edition : 1 |
Number of pages : 180 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|
| ISO 52000-3:2023 |
Energy performance of buildings — Overarching EPB assessment — Part 3: General principles for determination and reporting of primary energy factors (PEF) and CO2 emission coefficients |
This document provides a transparent framework for reporting on the choices related to the procedure to determine primary energy factors (PEFs) and CO2 emission coefficients for energy delivered to and exported from the buildings as described in ISO 52000-1.
It does not include considerations on other topics, e.g. nuclear waste, atmospheric particulate matter, deforestation, food and bioenergy competition, depletion of raw material resources, depletion of the soil.
This document specifies the choices to be made to calculate the PEFs and CO2 emission coefficients related to different energy carriers. PEFs and CO2 emission coefficients for exported energy can be different from those chosen for delivered energy.
This document is primarily intended for supporting and complementing ISO 52000-1 as the latter requires values for the PEFs and CO2 emission coefficients to complete the EPB calculation, however it can also be used for other applications.
|
Published |
2023-03 |
Edition : 1 |
Number of pages : 36 |
Technical Committee |
91.120.10
Thermal insulation of buildings
|