oSIST prEN 1991-1-5:2023

SLOVENSKI STANDARD
oSIST prEN 1991-1-5:2023
01-maj-2023
Evrokod 1 - Vplivi na konstrukcije - 1-5. del: Toplotni vplivi
Eurocode 1 - Actions on structures - Part 1-5: Thermal actions
Eurocode 1 - Einwirkungen auf Tragwerke - Teil 1-5: Allgemeine Einwirkungen -
Temperatureinwirkungen
Eurocode 1 - Actions sur les structures - Partie 1-5 : Actions thermiques
Ta slovenski standard je istoveten z: prEN 1991-1-5
ICS:
91.010.30 Tehnični vidiki Technical aspects
oSIST prEN 1991-1-5:2023 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN 1991-1-5:2023

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oSIST prEN 1991-1-5:2023


DRAFT
EUROPEAN STANDARD
prEN 1991-1-5
NORME EUROPÉENNE

EUROPÄISCHE NORM

March 2023
ICS 91.010.30 Will supersede EN 1991-1-5:2003
English Version

Eurocode 1 - Actions on structures - Part-1-5: General
actions - Thermal actions
Eurocode 1 - Actions sur les structures - Partie 1-5: Eurocode 1 - Einwirkungen auf Tragwerke - Teil 1-5:
Actions générales - Actions thermiques Allgemeine Einwirkungen - Temperatureinwirkungen
This draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee
CEN/TC 250.

If this draft becomes a European Standard, CEN members are bound to comply with the CEN/CENELEC Internal Regulations
which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.

This draft European Standard was established by CEN in three official versions (English, French, German). A version in any other
language made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC
Management Centre has the same status as the official versions.

CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia,
Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway,
Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Türkiye and
United Kingdom.

Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are
aware and to provide supporting documentation.

Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without
notice and shall not be referred to as a European Standard.


EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION

EUROPÄISCHES KOMITEE FÜR NORMUNG

CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2023 CEN All rights of exploitation in any form and by any means reserved Ref. No. prEN 1991-1-5:2023 E
worldwide for CEN national Members.

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Contents Page
European foreword . 4
Introduction . 5
1 Scope . 8
1.1 Scope of EN 1991-1-5 . 8
1.2 Assumptions . 8
2 Normative references . 8
3 Terms, definitions and symbols . 8
3.1 Terms and definitions . 8
3.2 Symbols and abbreviations . 9
3.2.1 Latin upper-case letters . 10
3.2.2 Latin lower case letters . 11
3.2.3 Greek lower-case letters . 11
4 Design situations . 11
5 Classification of actions . 11
6 Representation of actions . 11
7 Thermal actions on buildings . 12
7.1 General. 12
7.2 Determination of temperatures . 13
7.3 Determination of temperature profiles . 14
8 Thermal actions on bridges . 15
8.1 Bridge decks . 15
8.1.1 Bridge deck types . 15
8.1.2 Consideration of thermal actions . 15
8.1.3 Uniform temperature component . 16
8.1.4 Temperature difference components . 18
8.1.5 Simultaneity of uniform and temperature difference components . 24
8.1.6 Differences in the uniform temperature component between different structural
members . 24
8.2 Bridge piers . 25
8.3 Thermal actions due to hot paving . 25
9 Thermal actions on industrial chimneys, silos, tanks and cooling towers . 26
9.1 General. 26
9.2 Determination of temperature components . 26
9.3 Values of temperature components . 26
9.4 Simultaneity of temperature components . 27
Annex A (normative) Adjustment of shade air temperature for an annual probability p of
being exceeded . 29
A.1 Field of application . 29
A.2 Adjustment using extreme value distribution . 29
Annex B (normative) Vertical temperature differences with various surfacing thickness
using Approach 2 . 31
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B.1 Field of application . 31
B.2 Vertical temperature differences . 31
Annex C (informative) Temperature profiles in buildings and other construction works . 34
C.1 Use of this Informative Annex . 34
C.2 Field of application . 34
C.3 Thermal transmission theory . 34
Bibliography . 36

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European foreword
This document (prEN 1991-1-5:2023) has been prepared by Technical Committee CEN/TC 250
“Structural Eurocodes”, the secretariat of which is held by BSI.
CEN/TC 250 is responsible for all Structural Eurocodes and has been assigned responsibility for
structural and geotechnical design matters by CEN.
This document is currently submitted to the CEN Enquiry.
This document will supersede EN 1991-1-5:2005.
The first generation of EN Eurocodes was published between 2002 and 2007. This document forms
part of the second generation of the Eurocodes, which have been prepared under Mandate M/515
issued to CEN by the European Commission and the European Free Trade Association.
The Eurocodes have been drafted to be used in conjunction with relevant execution, material, product
and test standards, and to identify requirements for execution, materials, products and testing that are
relied upon by the Eurocodes.
The Eurocodes recognize the responsibility of each Member State and have safeguarded their right to
determine values related to regulatory safety matters at national level through the use of National
Annexes.
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Introduction
0.1 Introduction to the Eurocodes
The structural Eurocodes comprise the following standards generally consisting of a number of Parts:
— EN 1990, Eurocode: Basis of structural and geotechnical design
— EN 1991, Eurocode 1: Actions on structures
— EN 1992, Eurocode 2: Design of concrete structures
— EN 1993, Eurocode 3: Design of steel structures
— EN 1994, Eurocode 4: Design of composite steel and concrete structure
— EN 1995, Eurocode 5: Design of timber structures
— EN 1996, Eurocode 6: Design of masonry structures
— EN 1997, Eurocode 7: Geotechnical design
— EN 1998, Eurocode 8: Design of structures for earthquake resistance
— EN 1999, Eurocode 9: Design of aluminium structures
— < New parts >
The Eurocodes are intended for use by designers, clients, manufacturers, constructors, relevant
authorities (in exercising their duties in accordance with national or international regulations),
educators, software developers, and committees drafting standards for related product, testing and
execution standards.
NOTE Some aspects of design are most appropriately specified by relevant authorities or, where not
specified, can be agreed on a project-specific basis between relevant parties such as designers and clients. The
Eurocodes identify such aspects making explicit reference to relevant authorities and relevant parties.
0.2 Introduction to EN 1991
(1) EN 1991 provides the actions to be considered for the structural design of buildings, bridges and
other civil engineering works, or parts thereof, including temporary structures, in conjunction with
EN 1990 and the other Eurocodes.
(2) The actions on structures, including in some cases geotechnical structures in conjunction with
EN 1997 as appropriate, provided in EN 1991 are intended to be applied in conjunction with the other
Eurocodes for the verification of safety, serviceability and durability, as well as robustness of
structures, including the execution phase.
(3) The application of this document for the verifications mentioned in (2) follows the limit state
principle and is based on the partial factor method, unless explicitly prescribed differently.
(4) EN 1991 does not cover actions for structures in seismic regions, unless explicitly prescribed by
EN 1998. Provisions related to such requirements are given in EN 1998, which complements and is
consistent with EN 1991.
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(5) EN 1991 is also applicable to existing structures for their:
— structural assessment,
— retrofitting (strengthening, repair) design,
— assessment for changes of use.
NOTE In this case additional or amended provisions can be necessary.
(6) EN 1991 is applicable to the design of structures where materials or actions outside the scope of
the other Eurocodes are involved.
NOTE In this case additional or amended provisions can be necessary.
0.3 Introduction to EN 1991-1-5
EN 1991-1-5 gives design guidance for thermal actions arising from climatic and operational
conditions on buildings and civil engineering structures.
Information on thermal actions induced by fire is given in EN 1991-1-2.
EN 1991-1-5 is intended for clients, designers, contractors and relevant authorities.
EN 1991-1-5 is intended to be used with EN 1990, the other Parts of EN 1991 and EN 1992 to 1999 for
the design of structures.
0.4 Verbal forms used in the Eurocodes
The verb “shall” expresses a requirement strictly to be followed and from which no deviation is
permitted in order to comply with the Eurocodes.
The verb “should” expresses a highly recommended choice or course of action. Subject to national
regulation and/or any relevant contractual provisions, alternative approaches could be used/adopted
where technically justified.
The verb “may” expresses a course of action permissible within the limits of the Eurocodes.
The verb “can” expresses possibility and capability; it is used for statements of fact and clarification of
concepts.
0.5 National Annex for EN 1991-1-5
National choice is allowed in this standard where explicitly stated within notes. National choice
includes the selection of values for Nationally Determined Parameters (NDPs).
The national standard implementing EN 1991-1-5 can have a National Annex containing all national
choices to be used for the design of buildings and civil engineering works to be constructed in the
relevant country.
When no national choice is given, the default choice given in this standard is to be used.
When no national choice is made and no default is given in this standard, the choice can be specified by
a relevant authority or, where not specified, agreed for a specific project by appropriate parties.
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National choice is allowed in EN 1991-1-5 through notes to the following clauses:
7.3 (1) NOTE 1 8.1.3.3 (5) NOTE 8.1.6 (1) NOTE
7.3 (2) NOTE 1 8.1.4 (2) NOTE 8.2 (3) NOTE
7.3 (3) NOTE 8.1.4 (3) NOTE 8.2 (4) NOTE
7.3 (5) NOTE 8.1.4.2 (2) NOTE 1 8.2 (5) NOTE
7.3 (6) NOTE 8.1.4.2 (2) NOTE 2 9.3 (2) NOTE
8.1.1 (1) NOTE 2 8.1.4.3 (2) NOTE 1 9.3 (3) NOTE
8.1.3.1 (2) NOTE 8.1.4.3 (2) NOTE 3 9.3 (4) NOTE
8.1.3.2 (1) NOTE 8.1.4.4 (2) NOTE A.2 (2) NOTE 1
8.1.3.2 (5) NOTE 8.1.4.5 (1) NOTE A.2 (2) NOTE 3
8.1.3.3 (2) NOTE 8.1.5 (1) NOTE B.2 (1) NOTE 1
8.1.3.3 (3) NOTE 8.1.5 (2) NOTE
National choice is allowed in EN 1991-1-5 on the application of the following informative annex:
— Annex C (informative) Temperature profiles in buildings and other construction works
The National Annex can contain, directly or by reference, non-contradictory complementary
information for ease of implementation, provided it does not alter any provisions of the Eurocodes.
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1 Scope
1.1 Scope of EN 1991-1-5
(1) EN 1991-1-5 gives principles and rules for calculating thermal actions on buildings, bridges and
other structures including their structural members. Principles needed for cladding and other
attachments of buildings are also provided.
(2) This Part describes the changes in the temperature of structural members. Characteristic values of
thermal actions are presented for use in the design of structures which are exposed to daily and
seasonal climatic changes.
(3) This Part also gives principles for changes in the temperature of structural members due to the
paving of hot asphalt on bridge decks.
(4) This Part also provides principles and rules for thermal actions acting in structures which are
mainly a function of their use (e.g. cooling towers, silos, tanks, warm and cold storage facilities, hot and
cold services, etc.).
NOTE Supplementary guidance for thermal actions on chimneys is provided in EN 13084-1.
1.2 Assumptions
The assumptions given in FprEN 1990:2022, 1.2 apply to EN 1991-1-5.
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.
NOTE See the Bibliography for a list of other documents cited that are not normative references, including
those referenced as recommendations (i.e. in “should” clauses), permissions (“may” clauses), possibilities (“can”
clauses), and in notes.
FprEN 1990:2022, Eurocode — Basis of structural and geotechnical design
ISO 2394, General principles on reliability for structures
ISO 3898:2013, Bases for design of structures — Names and symbols of physical quantities and generic
quantities
ISO 8930, General principles on reliability for structures — Vocabulary
3 Terms, definitions and symbols
3.1 Terms and definitions
For the purposes of this European Standard, the definitions given in FprEN 1990:2022, ISO 2394,
ISO 3898:2013 and ISO 8930 and the following apply.
3.1.1
thermal actions
those actions on a structure or a structural member that arise from the changes of temperature fields
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3.1.2
shade air temperature
temperature measured by thermometers placed in a “Stevenson screen” (an instrument shelter which
is ventilated and protected from the solar radiation)
3.1.3
maximum shade air temperature
T
max
value of maximum shade air temperature with an annual probability of exceedance of 0,02 (equivalent
to a mean return period of 50 years), based on the maximum hourly values recorded
3.1.4
minimum shade air temperature
T
min
value of minimum shade air temperature with an annual probability of exceedance of 0,02 (equivalent
to a mean return period of 50 years), based on the minimum hourly values recorded
3.1.5
initial temperature
T
0
temperature of a structural member at the relevant stage of its restraint (completion) which should be
taken into account during the design to consider movements and /or restraining effects
3.1.6
cladding
parts of the building with protective and/or architectural function which are added after the main
structure is complete
3.1.7
uniform temperature component
temperature, constant over the cross section, which governs the expansion or contraction of a member
or structure
3.1.8
temperature difference component
part of a temperature profile in a structural member representing the temperature difference between
the outer face of the member and any in-depth point
3.2 Symbols and abbreviations
(1) For the purposes of this Part of Eurocode 1, the following symbols, specific to this Part, apply,
together with the general notations given in FprEN 1990:2022.
NOTE The notation used is based on ISO 3898:2013.
(2) A basic list of notations is provided in FprEN 1990:2022, and the additional notations below are
specific to this Part.
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3.2.1 Latin upper-case letters
R thermal resistance of structural member
R thermal resistance at the inner surface
in
R thermal resistance at the outer surface
out
T maximum shade air temperature with an annual probability of exceedance of 0,02
max
(equivalent to a mean return period of 50 years)
T minimum shade air temperature with an annual probability of exceedance of 0,02
min
(equivalent to a mean return period of 50 years)
T maximum shade air temperature with an annual probability of exceedance p (equivalent
max,p
to a mean return period of 1/p)
T minimum shade air temperature with an annual probability of exceedance p (equivalent
min,p
to a mean return period of 1/p)
T uniform temperature
N
T maximum uniform temperature
N.max
T minimum uniform temperature
N.min
T uniform night cooling temperature
N.night
T initial temperature when a structural member is restrained
0
T the minimum initial bridge temperature from which expansion is considered
0,inf
T the maximum initial bridge temperature from which contraction is considered
0,sup
T air temperature of the inner environment
in
T air temperature of the outer environment
out
ΔT range of initial bridge temperature
0
ΔT heating (cooling) temperature differences
i
ΔT range of uniform temperature component
N
ΔT maximum expansion range of uniform bridge temperature component
N, exp
ΔT maximum contraction range of uniform bridge temperature component
N, con
ΔT linear temperature difference component
M
ΔT linear temperature difference component (heating)
M,heat
ΔT linear temperature difference component (cooling)
M,cool
ΔT nonlinear part of the temperature difference component
E
ΔT sum of linear temperature difference component and nonlinear part of the temperature
difference component
ΔT difference in the coincident value of uniform temperature between different structural
p
members within a structure
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3.2.2 Latin lower case letters
h height of the cross-section
k coefficient for calculation of maximum (minimum) shade air temperature with an annual
probability of exceedance, p, other than 0,02
k surfacing factor for linear temperature difference component
sur
p annual probability of maximum (minimum) shade air temperature being exceeded
(equivalent to a mean return period of 1/p years)
u, mode and scale parameters of annual maximum (minimum) shade air temperature
c distribution
3.2.3 Greek lower-case letters
λ thermal conductivity
ω reduction factor of uniform temperature component for combination with temperature
N
difference component
ω reduction factor of temperature difference component for combination with uniform
M
temperature component
4 Design situations
(1) Thermal actions shall be determined for the relevant design situation identified in accordance with
FprEN 1990:2022.
(2) The effects of thermal actions shall be allowed for in the design of load bearing members of
structures, either by providing movement joints or by including the effects in design verifications.
5 Classification of actions
(1) Thermal actions shall be classified as variable and indirect actions, as defined within
FprEN 1990:2022.
(2) All values of thermal actions given in this Part are characteristic values, see FprEN 1990:2022.
(3) For design situations where the annual probability of exceedance is other than 0,02 the values of
thermal actions should be derived using the calculation method given in Annex A.
6 Representation of actions
(1) The temperature distribution within an individual structural member should be resolved into the
following four basic components, as illustrated in Figure 6.1:
a) A uniform temperature component, ∆T ;
N
b) A linearly varying temperature difference component about the z-z axis, ΔT ;
MZ
c) A linearly varying temperature difference component about the y-y axis, ΔT ;
MY
d) A nonlinear temperature difference component, ΔT . This results in a system of self-equilibrated
E
stresses which produce no net load effect on the member.
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NOTE 1 Daily and seasonal changes in shade air temperature, solar radiation, re-radiation, etc. result in
variations of the temperature fields within individual members of a structure.
NOTE 2 The magnitude of the thermal actions depends on local climatic conditions, the orientation of the
structure, its overall mass, effects of finishes (e.g. cladding in buildings), and in the case of building structures,
heating and ventilation regimes and thermal insulation.

Key
A Centroid of section
Figure 6.1 — Diagrammatic representation of components of a temperature profile
(2) When materials with different coefficients of linear expansion are used compositely, their
combined thermal response should be taken into account.
NOTE The thermal strains and any thermal stresses resulting from constraint or associated movements
depend on the geometry and boundary conditions of the member being considered and on the physical
properties of the material used.
(3) For the purpose of deriving thermal actions, the relevant material coefficient of linear expansion
should be used.
(4) Values for the coefficient of linear expansion should be obtained from the relevant material specific
Eurocode parts where available.
(5) Where not available in material specific Eurocode parts, values for the coefficient of linear
expansion may be as specified by the relevant authority or, where not specified, as agreed for the
specific project by the relevant parties using reliable published data or verified by tests or more
detailed studies.
7 Thermal actions on buildings
7.1 General
(1) Thermal actions on buildings due to environmental and operational temperatures shall be
considered in the design of buildings where there is a possibility of the ultimate or serviceability limit
states being exceeded due to thermal movements and/or stresses generated as a result of restraint.
NOTE Volume changes and/or stresses due to temperature changes can also be influenced by e.g.:
a) shading from adjacent buildings, effects of orientation (e.g. NE-SW, NW-SE);
b) use of different materials with different thermal expansion coefficients and heat transfer
characteristics;
c) use of different cross-sectional shapes with different uniform temperature.
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(2) In a multi-skin cladding system, the relative movement of the adjacent layers of the envelope
should be considered when specifying brackets, fasteners and other components of the system.
NOTE Where sandwich panels are used as wall or roof cladding, the temperature difference between the
inner and outer metal sheets can be significant giving rise to bending effects in the panels. Further information is
given in EN 14509.
7.2 Determination of temperatures
(1) Thermal actions on buildings due to environmental changes shall be determined by considering
the variation of shade air temperature and solar radiation. Operational effects (due to heating,
technological or industrial processes) shall also be considered where appropriate.
NOTE The location of the building and the structural detailing can also affect the determination of thermal
actions.
(2) Climatic and operational thermal actions on a structural member shall be specified using the
following basic temperature components:
a) A uniform temperature component ∆T is expressed as a uniform difference in temperature
N
∆T = TT – (7.1)
N N0
where
is a uniform temperature over the full area of a structural member due to climatic temperatures
T
N
in winter or summer season and/or due to
...