SIST-TP CEN ISO/TR 52022-2:2017

SLOVENSKI STANDARD
01-september-2017
Energijske lastnosti stavb - Lastnosti gradbenih komponent in elementov glede
toplote, sončnega obsevanja in dnevne svetlobe - 2. del: Obrazložitev in
utemeljitev (ISO/TR 52022-2:2017)
Energy performance of buildings - Thermal, solar and daylight properties of building
components and elements - Part 2: Explanation and justification (ISO/TR 52022-2:2017)
Energieeffizienz von Gebäuden - Wärmetechnische, solare und tageslichtbezogene
Eigenschaften von Bauteilen und Bauelementen - Teil 2: Erklärung und Begründung
(ISO/TR 52022-2:2017)
Performance énergétique des bâtiments - Propriétés thermiques, solaires et lumineuses
des composants et éléments du bâtiment - Partie 2: Explication et justification (ISO/TR
52022-2:2017)
Ta slovenski standard je istoveten z: CEN ISO/TR 52022-2:2017
ICS:
27.015 Energijska učinkovitost. Energy efficiency. Energy
Ohranjanje energije na conservation in general
splošno
91.120.10 Toplotna izolacija stavb Thermal insulation of
buildings
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

CEN ISO/TR 52022-2
TECHNICAL REPORT
RAPPORT TECHNIQUE
July 2017
TECHNISCHER BERICHT
ICS 91.120.10
English Version
Energy performance of buildings - Thermal, solar and
daylight properties of building components and elements -
Part 2: Explanation and justification (ISO/TR 52022-
2:2017)
Performance énergétique des bâtiments - Propriétés Energieeffizienz von Gebäuden - Wärmetechnische,
thermiques, solaires et lumineuses des composants et solare und tageslichtbezogene Eigenschaften von
éléments du bâtiment - Partie 2: Explication et Bauteilen und Bauelementen - Teil 2: Erklärung und
justification (ISO/TR 52022-2:2017) Begründung (ISO/TR 52022-2:2017)

This Technical Report was approved by CEN on 24 February 2017. It has been drawn up by the Technical Committee CEN/TC 89.

CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia,
Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania,
Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland,
Turkey and United Kingdom.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2017 CEN All rights of exploitation in any form and by any means reserved Ref. No. CEN ISO/TR 52022-2:2017 E
worldwide for CEN national Members.

Contents Page
European foreword . 3
European foreword
This document (CEN ISO/TR 52022-2:2017) has been prepared by Technical Committee ISO/TC 163
"Thermal performance and energy use in the built environment" in collaboration with Technical
Committee CEN/TC 89 “Thermal performance of buildings and building components” the secretariat of
which is held by SIS.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN shall not be held responsible for identifying any or all such patent rights.
This document has been prepared under a mandate given to CEN by the European Commission and the
European Free Trade Association.
This document is part of the set of standards on the energy performance of buildings (the set of EPB
standards) and has been prepared under a mandate given to CEN by the European Commission and the
European Free Trade Association (Mandate M/480, see reference [EF1] below), and supports essential
requirements of EU Directive 2010/31/EC on the energy performance of buildings (EPBD, [EF2]).
In case this standard is used in the context of national or regional legal requirements, mandatory
choices may be given at national or regional level for such specific applications, in particular for the
application within the context of EU Directives transposed into national legal requirements.
Further target groups are users of the voluntary common European Union certification scheme for the
energy performance of non-residential buildings (EPBD art.11.9) and any other regional (e.g. Pan
European) parties wanting to motivate their assumptions by classifying the building energy
performance for a dedicated building stock.
References:
[EF1] Mandate M480, Mandate to CEN, CENELEC and ETSI for the elaboration and adoption of
standards for a methodology calculating the integrated energy performance of buildings and promoting
the energy efficiency of buildings, in accordance with the terms set in the recast of the Directive on the
energy performance of buildings (2010/31/EU) of 14th December 2010
[EF2] EPBD, Recast of the Directive on the energy performance of buildings (2010/31/EU) of 14th
December 2010
Endorsement notice
The text of ISO/TR 52022-2:2017 has been approved by CEN as CEN ISO/TR 52022-2:2017 without any
modification.
TECHNICAL ISO/TR
REPORT 52022-2
First edition
2017-06
Energy performance of buildings —
Thermal, solar and daylight properties
of building components and
elements —
Part 2:
Explanation and justification
Performance énergétique des bâtiments — Propriétés thermiques,
solaires et lumineuses des composants et éléments du bâtiment —
Partie 2: Explication et justification
Reference number
ISO/TR 52022-2:2017(E)
©
ISO 2017
ISO/TR 52022-2:2017(E)
© ISO 2017, Published in Switzerland
All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized otherwise in any form
or by any means, electronic or mechanical, including photocopying, or posting on the internet or an intranet, without prior
written permission. Permission can be requested from either ISO at the address below or ISO’s member body in the country of
the requester.
ISO copyright office
Ch. de Blandonnet 8 • CP 401
CH-1214 Vernier, Geneva, Switzerland
Tel. +41 22 749 01 11
Fax +41 22 749 09 47
copyright@iso.org
www.iso.org
ii © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
Contents Page
Foreword .v
Introduction .vi
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Symbols and subscripts . 2
5 Brief description of the methods . 2
5.1 Outputs of the method. 2
5.2 General description of the methods . 2
6 ISO 10077-1 Thermal performance of windows, doors and shutters – Calculation of
thermal transmittance – Part 1: General . 2
6.1 General . 2
6.2 Thermal transmittance of the glazing . 3
6.3 Additional thermal resistance of windows with closed shutters . 3
7 ISO 10077-2 Thermal performance of windows, doors and shutters – Calculation of
thermal transmittance – Part 2: Numerical method for frames.3
7.1 General . 3
7.2 Calculation principle . 3
8 ISO 12631 Thermal performance of curtain walling – Calculation of
thermal transmittance . 4
8.1 General . 4
8.2 Calculation examples . 4
9 ISO 52022-1 Energy performance of buildings — Thermal, solar and daylight
properties of building components and elements — Part 1: Simplified calculation
method of the solar and daylight characteristics for solar protection devices
combined with glazing . 4
9.1 General . 4
9.2 Data for typical glazing and solar protection devices . 5
9.3 Solar transmittance of solar protection devices . 5
9.4 Calculation example. 5
10 ISO 52022-3 Energy performance of buildings — Thermal, solar and daylight
properties of building components and elements — Part 3: Detailed calculation
method of the solar and daylight characteristics for solar protection devices
combined with glazing . 6
10.1 General . 6
10.2 Equivalent solar and light optical characteristics for louvres or venetian blinds . 6
10.3 Calculation example. 6
Annex A (informative) ISO 10077-1: Thermal transmittance of double and triple glazing .7
Annex B (informative) ISO 10077-1: Additional thermal resistance for windows with
closed shutters . . 9
Annex C (informative) ISO 12631: Component method: Calculation example .12
Annex D (informative) ISO 12631: Single assessment method: Calculation example .17
Annex E (informative) ISO 52022-1: Data for typical glazing and solar protection devices .20
Annex F (informative) ISO 52022-1: Example of calculation of a solar protection device in
combination with glazing .21
Annex G (informative) Extended methodology for the determination of equivalent solar
and light optical characteristics for louvres or venetian blinds .23
ISO/TR 52022-2:2017(E)
Annex H (informative) ISO 52022-3: Calculation example .45
Bibliography .47
iv © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www .iso .org/ directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www .iso .org/ patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation on the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO’s adherence to the
World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT) see the following
URL: w w w . i s o .org/ iso/ foreword .html.
ISO 52022-2 was prepared by the European Committee for Standardization (CEN) Technical Committee
CEN/TC 89, Thermal performance of buildings and building components, in collaboration with ISO
Technical Committee ISO/TC 163, Thermal performance and energy use in the built environment,
Subcommittee SC 2 Calculation methods, in accordance with the Agreement on technical cooperation
between ISO and CEN (Vienna Agreement).
A list of all parts in the ISO 52022 series can be found on the ISO website.
ISO/TR 52022-2:2017(E)
Introduction
The set of EPB standards, technical reports and supporting tools
In order to facilitate the necessary overall consistency and coherence, in terminology, approach,
input/output relations and formats, for the whole set of EPB-standards, the following documents and
tools are available:
a) a document with basic principles to be followed in drafting EPB-standards:
[1]
CEN/TS 16628:2014 ;
b) a document with detailed technical rules to be followed in drafting EPB-standards;
[2]
CEN/TS 16629:2014 .
The detailed technical rules are the basis for the following tools:
1) a common template for each EPB-standard, including specific drafting instructions for the
relevant clauses;
2) a common template for each technical report that accompanies an EPB standard or a cluster of
EPB standards, including specific drafting instructions for the relevant clauses;
3) a common template for the spreadsheet that accompanies each EPB (calculation) standard, to
demonstrate the correctness of the EPB calculation procedures.
Each EPB-standards follows the basic principles and the detailed technical rules and relates to the
[3]
overarching EPB-standard, ISO 52000-1 .
One of the main purposes of the revision of the EPB-standards is to enable that laws and regulations
directly refer to the EPB-standards and make compliance with them compulsory. This requires that
the set of EPB-standards consists of a systematic, clear, comprehensive and unambiguous set of energy
performance procedures. The number of options provided is kept as low as possible, taking into account
national and regional differences in climate, culture and building tradition, policy and legal frameworks
(subsidiarity principle). For each option, an informative default option is provided (Annex B).
Rationale behind the EPB technical reports
There is a risk that the purpose and limitations of the EPB standards will be misunderstood, unless
the background and context to their contents – and the thinking behind them - is explained in some
detail to readers of the standards. Consequently, various types of informative contents are recorded
and made available for users to properly understand, apply and nationally or regionally implement the
EPB standards.
If this explanation would have been attempted in the standards themselves, the result is likely to be
confusing and cumbersome, especially if the standards are implemented or referenced in national or
regional building codes.
Therefore each EPB standard is accompanied by an informative technical report, like this one, where
all informative content is collected to ensure a clear separation between normative and informative
[2]
contents (see CEN/TS 16629 ):
— to avoid flooding and confusing the actual normative part with informative content;
— to reduce the page count of the actual standard, and
— to facilitate understanding of the set of EPB standards.
[5]
This was also one of the main recommendations from the European CENSE project that that laid the
foundation for the preparation of the set of EPB standards.
vi © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
This technical report
This technical report accompanies the suite of EPB standards on thermal transmission properties
windows, doors and curtain wallings and the standards for solar and daylight characteristics for solar
[6] [7] [8]
protection devices combined with glazing. It relates to ISO 10077-1 , ISO 10077-2 , ISO 12631 ,
[9] [10]
ISO 52022-1 and ISO 52022-3 which form part of a set of standards related to the evaluation of
the energy performance of buildings (EPB).
The role and the positioning of the accompanied standard(s) in the set of EPB standards is defined in
the introductions to ISO 10077-1, ISO 10077-2, ISO 12631, ISO 52022-1 and ISO 52022-3.
Accompanying spreadsheets
Concerning ISO 10077-1, ISO 10077-2, ISO 12631, ISO 52022-1 and ISO 52022-3, spreadsheets were
produced for:
— ISO 10077-1;
— ISO 12631;
— ISO 52022-1.
No accompanying calculation spreadsheets were prepared on:
— ISO 10077-2: The calculation method of ISO 10077-2 cannot be implemented in a spreadsheet.
— ISO 52022-3: The calculation method of ISO 52022-3 cannot be implemented in a spreadsheet.
These spreadsheets are available at www .epb .center.
TECHNICAL REPORT ISO/TR 52022-2:2017(E)
Energy performance of buildings — Thermal, solar
and daylight properties of building components and
elements —
Part 2:
Explanation and justification
1 Scope
This document contains information to support the correct understanding and use of ISO 10077-1,
ISO 10077-2, ISO 12631, ISO 52022-1 and ISO 52022-3.
This technical report does not contain any normative provision.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 6946, Building components and building elements — Thermal resistance and thermal transmittance –
Calculation methods
ISO 7345, Thermal insulation — Physical quantities and definitions
ISO 10077-1, Thermal performance of windows, doors and shutters — Calculation of thermal
transmittance — Part 1: General
ISO 10077-2, Thermal performance of windows, doors and shutters — Calculation of thermal
transmittance — Part 2: Numerical method for frames
ISO 12631:2017, Thermal performance of curtain walling — Calculation of thermal transmittance
ISO 52022-1, Energy performance of buildings— Thermal, solar and daylight properties of building
components and elements Part 1: Simplified calculation method of the solar and daylight characteristics for
solar protection devices combined with glazing
ISO 52022-3, Energy performance of buildings— Thermal, solar and daylight properties of building
components and elements Part 3: Detailed calculation method of the solar and daylight characteristics for
solar protection devices combined with glazing
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 6946, ISO 7345, ISO 10077-1,
ISO 10077-2, ISO 12631, ISO 52022-1 and ISO 52022-3 apply.
More information on some key EPB terms and definitions is given in ISO/TR 52000-2.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— IEC Electropedia: available at http:// www .electropedia .org/
— ISO Online browsing platform: available at http:// www .iso .org/ obp
ISO/TR 52022-2:2017(E)
4 Symbols and subscripts
For the purposes of this document, the symbols and subscripts given in ISO 7345, ISO 6946, ISO 10077-1,
ISO 10077-2, ISO 12631, ISO 52022-1 and ISO 52022-3 apply.
5 Brief description of the methods
5.1 Outputs of the method
The main outputs of these standards are:
— thermal transmittance of windows, doors, curtain walls, shutter boxes and frames;
— solar and daylight characteristics (solar energy transmittance, daylight transmittance) for solar
protecting devices combined with glazing.
5.2 General description of the methods
ISO 10077-1, ISO 10077-2, ISO 12631, ISO 52022-1 and ISO 52022-3 provide the methodology to obtain
the energy losses due to transmission and the energy gains due to solar radiation for windows, doors
and curtain walls.
The calculation of the thermal transmittance of windows, doors according to ISO 10077-1 and curtain
walls according to ISO 12631 is calculated as a function of the thermal transmittance of the components
and their geometrical characteristics, plus the thermal interactions between the components.
The calculation of the thermal transmittance of frame profiles, shutter boxes and the linear thermal
transmittance according to ISO 10077-2 is carried out using a two dimensional numerical method.
There are two separate standards for the calculation of the solar and daylight characteristics for solar
protection devices combined with glazing. ISO 52022-1 defines a simplified method based on the thermal
transmittance and total solar energy transmittance of the glazing and on the light transmittance and
reflectance of the solar protection device to estimate the total solar energy transmittance of a solar
protection device combined with glazing. The results generally tend to lie on the safe side for cooling
load estimations. The results are not intended to be used for calculating beneficial solar gains or
thermal comfort criteria. The calculations according to ISO 52022-1 can in principle be performed by a
pocket calculator.
For cases not covered by ISO 52022-3 more exact calculations based on the optical properties (in
general the spectral data) of glass and solar protection device can be carried out in accordance with
ISO 52022-3. The total solar energy transmittance, the total solar direct transmittance and the
total light transmittance is calculated as a function of the thermal resistance and spectral “optical”
properties (transmittance, reflectance) of the individual layers. To solve the system of equations defined
in ISO 52022-3 the use of an iterative procedure and therefore in general a software tool is necessary.
6 ISO 10077-1 Thermal performance of windows, doors and shutters –
Calculation of thermal transmittance – Part 1: General
6.1 General
ISO 10077-1 provides a calculation method to obtain the thermal transmittance of windows and
pedestrian doors consisting of glazed and/or or opaque panels fitted in a frame, with and without
shutters.
In general, the thermal transmittance or U-value of the window or door product or assembly is calculated
as a function of the thermal transmittance of the components and their geometrical characteristics,
plus the thermal interactions between the components.
2 © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
An alternative to calculation according to ISO 10077-1 is testing of the complete window or door
according to ISO 12567-1 or, for roof windows, according to ISO 12567-2.
The following subclauses provide information in addition to that given in ISO 10077-1.
6.2 Thermal transmittance of the glazing
If measured or calculated data are not available, the values in Annex A may be used.
6.3 Additional thermal resistance of windows with closed shutters
A shutter or blind on the outside of a window introduces an additional thermal resistance ΔR, resulting
from both the air layer enclosed between the shutter and the window, and the shutter itself. ΔR depends
on the thermal transmission properties of the shutter/blind and on its air permeability and is evaluated
according to ISO 10077-1.
Annex B of this document gives some typical values of shutter thermal resistance and the corresponding
values of ΔR, which can be used in the absence of values of R obtained from measurement or
sh
calculation.
7 ISO 10077-2 Thermal performance of windows, doors and shutters –
Calculation of thermal transmittance – Part 2: Numerical method for frames
7.1 General
ISO 10077-2 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
also gives criteria for the validation of numerical methods used for the calculation.
7.2 Calculation principle
The calculation is carried out using a two-dimensional numerical method conforming to ISO 10211. The
elements are divided such that any further division does not change the calculated result significantly.
ISO 10211 gives criteria for judging whether sufficient sub-divisions have been used.
Two different approaches for the calculation of the heat transfer through cavities are given:
1. the radiosity method and;
2. the single equivalent thermal conductivity method.
The radiosity method considers that the heat transfer through an air cavity occurs simultaneously
through conduction/convection and through radiation. The two phenomena are happening in parallel
so that the calculation of each contribution is done separately.
When using the single equivalent thermal conductivity method the heat flow rate in cavities is
represented by a single equivalent thermal conductivity λ . This equivalent thermal conductivity
eq
includes the heat flow by conduction, by convection and by radiation, and depends on the geometry of
the cavity and on the adjacent materials.
The single equivalent thermal conductivity method is equal to the calculation method given in
ISO 10077-2:2012.
ISO/TR 52022-2:2017(E)
8 ISO 12631 Thermal performance of curtain walling – Calculation of thermal
transmittance
8.1 General
ISO 12631 provides a calculation method to obtain the thermal transmittance of curtain walls
consisting of glazed and/or or opaque panels fitted in a frame.
In general, the thermal transmittance or U-value of the curtain walling is calculated as a function of
the thermal transmittance of the components and their geometrical characteristics, plus the thermal
interactions between the components.
Two methods of calculating the thermal transmittance of curtain wall systems are specified:
— the single assessment method; and
— the component assessment method.
The single assessment method is based on detailed computer calculations of the heat transfer through
a complete construction including mullions, transoms, and filling elements (e.g., glazing unit, opaque
panel). The heat flow rate (between two adiabatic lines) is calculated by modelling each thermal joint
between two filling elements (opaque panel and/or glazing unit) using two-dimensional or three-
dimensional finite element analysis software. By area weighting the U-values of thermal joints and
filling elements, the overall façade U-value can be calculated. This method can be used for any curtain
walling system (i.e. unitised systems, stick systems, patent glazing, structural sealant glazing, rain
screens, structural glazing).
The component assessment method divides the representative element into areas of different thermal
properties, e.g., glazing units, opaque panels and frames. By area weighting the U-values of these
elements with additional correction terms describing the thermal interaction between these elements
(Ψ-values), the overall façade U-value can be calculated. This method can be used for curtain walling
systems such as unitised systems, stick systems and patent glazing. Structural silicone glazing, rain
screens and structural glazing are excluded from the component assessment method.
Both methods result in the same value for the thermal transmittance of a curtain wall.
8.2 Calculation examples
Annex C gives an example for the calculation of a curtain walling module according to the
component method.
Annex D gives an example for the calculation of a curtain walling module according to the single
assessment method.
9 ISO 52022-1 Energy performance of buildings — Thermal, solar and daylight
properties of building components and elements — Part 1: Simplified calculation
method of the solar and daylight characteristics for solar protection devices
combined with glazing
9.1 General
ISO 52022-1 defines a simplified method for the calculation of:
— the total solar energy transmittance;
— the total solar direct transmittance;
— the total light transmittance; and
4 © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
— a glazing in combination with an external or internal or integrated solar protection device.
These characteristics are calculated as a function of the “optical” properties of the solar protection device
and the glazing, the thermal transmittance of the glazing and the position of the solar protection device.
The formulae given in ISO 52022-1 are based on a simple physical model and the values of the notional
parameters G are mathematically fitted to a more precise reference calculation, following the principles
of ISO 52022-3.
The results generally tend to lie on the safe side for cooling load estimations. The results are not
intended to be used for calculating beneficial solar gains during heating period or thermal comfort
criteria.
9.2 Data for typical glazing and solar protection devices
Annex E gives some typical values for the characteristics of glazing and solar protection devices which
can be used in the absence of values obtained from measurement or calculation.
9.3 Solar transmittance of solar protection devices
Figure 1 shows the principles of solar transmittance of solar protection devices.
The simplified equations in ISO 52022-1 for venetian blinds open to 45° to not take into account direct
solar transmittance and diffuse radiation. The reflection of the slats is to be considered diffuse. If
diffuse irradiation has to be considered the relevant properties of louvre or Venetians blinds should be
calculated in accordance with ISO 52022-3.
a)
b) c)
Key
1 blinds 45°
a) transmittance, absorptance and reflectance of a solar protection device
b) no direct penetration in the case of louvre or Venetian blinds open to 45°
c) principle of the correction of the transmittance in the case of blinds open to 45°
Figure 1 — Principles of solar transmittance of solar protection devices
9.4 Calculation example
Annex F gives an example of calculation for the three positions of a solar protection device in
combination with a double clear glazing.
ISO/TR 52022-2:2017(E)
10 ISO 52022-3 Energy performance of buildings — Thermal, solar and daylight
properties of building components and elements — Part 3: Detailed calculation
method of the solar and daylight characteristics for solar protection devices
combined with glazing
10.1 General
ISO 52022-3 defines a procedure for a detailed calculation of the solar and daylight characteristics for
solar protection devices combined with glazing.
The procedure is based on the spectral transmission and reflection data of the materials, comprising
the solar protection devices and the glazing, to determine the total solar energy transmittance and
other relevant solar-optical data of the combination. If spectral data are not available the methodology
can be adapted to use integrated data.
In the physical model the glass panes and blinds are considered as parallel, solid layers. In general, the
total solar energy transmittance, the total solar direct transmittance and the total light transmittance
is calculated as a function of the thermal resistance and spectral “optical” properties (transmittance,
reflectance) of the individual layers.
Two sets of boundary conditions are given for the vertical position of the glazing and the blind.
Reference conditions:
These boundary conditions are consistent with the general assumptions of EN 410 and ISO 10292 and
to be used for product comparison and average solar gain calculations during the heating period.
Summer conditions:
These boundary conditions are representative of more extreme conditions and are used for comfort
evaluations and cooling load calculations.
10.2 Equivalent solar and light optical characteristics for louvres or venetian blinds
ISO 52022-3:2017, Annex D defines a method for the determination of equivalent solar and light optical
characteristics for louvres or venetian blinds. The method is restricted to the assumptions stated in
ISO 52022-3:2017, Annex D.
Annex G report defines an extended method which may be applied as an alternative method.
10.3 Calculation example
Annex H gives an example of calculation for the three positions of a solar protection device in
combination with a double clear glazing.
6 © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
Annex A
(informative)
ISO 10077-1: Thermal transmittance of double and triple glazing
Table A.1 gives the thermal transmittance, U , of double and triple glazing filled with different gases,
g
calculated in accordance with EN 673. The values of the thermal transmittance in Table A.1 apply to the
emissivities and gas concentration given.
Table A.1 — Thermal transmittance of double and triple glazing filled with different gases for
vertical glazing
Thermal transmittance for different
a
Glazing types of gas space
U
g
Normal Dimensions
b
Type Glass Air Argon Krypton SF Xenon
emissivity mm
4–6-4 3,3 3,0 2,8 3,0 2,6
Uncoated
4–8-4 3,1 2,9 2,7 3,1 2,6
glass
0,89 4–12–4 2,8 2,7 2,6 3,1 2,6
(normal
4–16–4 2,7 2,6 2,6 3,1 2,6
glass)
4–20–4 2,7 2,6 2,6 3,1 2,6
4–6-4 2,7 2,3 1,9 2,3 1,6
4–8-4 2,4 2,1 1,7 2,4 1,6
One pane
≤ 0,2 4–12–4 2,0 1,8 1,6 2,4 1,6
coated glass
4–16–4 1,8 1,6 1,6 2,5 1,6
4–20–4 1,8 1,7 1,6 2,5 1,7
4–6-4 2,6 2,3 1,8 2,2 1,5
4–8-4 2,3 2,0 1,6 2,3 1,4
Double One pane
≤ 0,15 4–12–4 1,9 1,6 1,5 2,3 1,5
glazing coated glass
4–16–4 1,7 1,5 1,5 2,4 1,5
4–20–4 1,7 1,5 1,5 2,4 1,5
4–6-4 2,6 2,2 1,7 2,1 1,4
4–8-4 2,2 1,9 1,4 2,2 1,3
One pane
≤ 0,1 4–12–4 1,8 1,5 1,3 2,3 1,3
coated glass
4–16–4 1,6 1,4 1,3 2,3 1,4
4–20–4 1,6 1,4 1,4 2,3 1,4
4–6-4 2,5 2,1 1,5 2,0 1,2
4–8-4 2,1 1,7 1,3 2,1 1,1
One pane
≤ 0,05 4–12–4 1,7 1,3 1,1 2,1 1,2
coated glass
4–16–4 1,4 1,2 1,2 2,2 1,2
4–20–4 1,5 1,2 1,2 2,2 1,2
NOTE  The values of thermal transmittance in the table were calculated using EN 673. They apply to the emissivities and
gas concentration given.
a
Gas concentration ≥ 90 %.
b
The use of SF is prohibited in some jurisdictions.
ISO/TR 52022-2:2017(E)
Table A.1 (continued)
Thermal transmittance for different
a
Glazing types of gas space
U
g
Normal Dimensions
b
Type Glass Air Argon Krypton SF Xenon
emissivity mm
4–6-4–6-4 2,3 2,1 1,8 1,9 1,7
Uncoated
(normal) 0,89 4–8-4–8-4 2,1 1,9 1,7 1,9 1,6
glass
4–12–4-12–4 1,9 1,8 1,6 2,0 1,6
4–6-4–6-4 1,8 1,5 1,1 1,3 0,9
Two panes
≤ 0,2 4–8-4–8-4 1,5 1,3 1,0 1,3 0,8
coated
4–12–4-12–4 1,2 1,0 0,8 1,3 0,8
4–6-4–6-4 1,7 1,4 1,1 1,2 0,9
Triple Two panes
≤ 0,15 4–8-4–8-4 1,5 1,2 0,9 1,2 0,8
glazing coated
4–12–4-12–4 1,2 1,0 0,7 1,3 0,7
4–6-4–6-4 1,7 1,3 1,0 1,1 0,8
Two panes
≤ 0,1 4–8-4–8-4 1,4 1,1 0,8 1,1 0,7
coated
4–12–4-12–4 1,1 0,9 0,6 1,2 0,6
4–6-4–6-4 1,6 1,2 0,9 1,1 0,7
Two panes
≤ 0,05 4–8-4–8-4 1,3 1,0 0,7 1,1 0,5
coated
4–12–4-12–4 1,0 0,8 0,5 1,1 0,5
NOTE  The values of thermal transmittance in the table were calculated using EN 673. They apply to the emissivities and
gas concentration given.
a
Gas concentration ≥ 90 %.
b
The use of SF is prohibited in some jurisdictions.
8 © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
Annex B
(informative)
ISO 10077-1: Additional thermal resistance for windows with
closed shutters
B.1 Additional thermal resistance
When the thermal resistance of the shutter itself, R , is known (by calculation or by measurement),
sh
the additional thermal resistance, ΔR, can be obtained using the appropriate expression in Table B.1,
depending on the air permeability of the shutter (see B.2).
Table B.1 — Additional thermal resistance for windows with closed shutters
Additional thermal resistance
a
Air permeability of shutter
ΔR
m ⋅K/W
Very high 0,08
High 0,25 R + 0,09
sh
Average 0,55 R + 0,11
sh
Low 0,80 R + 0,14
sh
Tight 0,95 R + 0,17
sh
a
The definition of the air permeability of shutters is given in B.2.
Average air permeability applies typically to solid wing shutters, wooden Venetian shutters with solid
overlapping slats, roller shutters with connecting slats made of wood, plastic or metal.
Table B.2 gives some typical values of shutter thermal resistance and the corresponding values of ΔR,
which can be used in the absence of values of R obtained from measurement or calculation.
sh
Table B.2 — Additional thermal resistance for windows with closed shutters
Additional thermal resistances
a
at specific air permeability of the shutters
Typical thermal
ΔR
resistance of shutter
Shutter type
m ⋅K/W
R
sh
m ⋅K/W
High or very high Average Tight or low
air permeability air permeability air permeability
Roller shutters of 0,01 0,09 0,12 0,15
aluminium
Roller shutters of wood 0,10 0,12 0,16 0,22
and plastic without foam
filling
Roller shutters of plastic 0,15 0,13 0,19 0,26
with foam filling
Shutters of wood, 25 mm 0,20 0,14 0,22 0,30
to 30 mm thickness
a
The definition of the air permeability of shutters is given in B.2.
ISO/TR 52022-2:2017(E)
B.2 Permeability of shutters
For the different types of shutter, the permeability criterion can be expressed in terms of an effective
total gap, b , between the shutter and its surround as given in Formula (B.1):
sh
bb=+ bb+ (B.1)
sh 12 3
where
b , b and b are the average edge gaps at the bottom, top and side on the shutter (see Figure B.1);
1 2 3
b is included for one side only, since gaps at the side influence the permeability less than
the gaps at the top and bottom.
Key
1 shutter
a
internal
b
external
Figure B.1 — Definition of edge gaps
10 © ISO 2017 – All rights reserved

ISO/TR 52022-2:2017(E)
Table B.3 — Relationship between permeability and effective total edge gap between
shutter and its surround
b
sh
Class Air permeability of shutter
mm
1 Very high b ≥ 35
sh
2 High 15 ≤ b < 35
sh
3 Average 8 ≤ b < 15
sh
4 Low b ≥ 8
sh
5 Tight b ≤ 3 and (b + b = 0 or b + b = 0)
sh 1 3 2 3
NOTE 1  For permeability classes 2 and above, there should be no openings within the shutter itself.
NOTE 2  For shutters of permeability class 5 the following criteria apply:
a  roller shutters:
The edge gaps at the sides and the bottom are considered equal to 0 if strip gaskets are supplied in the
guide rails and the final lath,
...