SIST EN 13445-3:2014/A5:2018

SLOVENSKI STANDARD
SIST EN 13445-3:2014/A5:2018
01-december-2018
1HRJUHYDQHQHNXUMHQHWODþQHSRVRGHGHO.RQVWUXLUDQMH'RSROQLOR$
Unfired pressure vessels - Part 3: Design
Unbefeuerte Druckbehälter - Teil 3: Konstruktion
Récipients sous pression non soumis à la flamme - Partie 3 : Conception
Ta slovenski standard je istoveten z: EN 13445-3:2014/A5:2018
ICS:
23.020.32 7ODþQHSRVRGH Pressure vessels
SIST EN 13445-3:2014/A5:2018 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 13445-3:2014/A5:2018

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SIST EN 13445-3:2014/A5:2018


EN 13445-3:2014/A5
EUROPEAN STANDARD

NORME EUROPÉENNE

November 2018
EUROPÄISCHE NORM
ICS 23.020.30
English Version

Unfired pressure vessels - Part 3: Design
Récipients sous pression non soumis à la flamme - Unbefeuerte Druckbehälter - Teil 3: Konstruktion
Partie 3 : Conception
This amendment A5 modifies the European Standard EN 13445-3:2014; it was approved by CEN on 4 June 2018.

CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for inclusion of
this amendment into the relevant national standard without any alteration. Up-to-date lists and bibliographical references
concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to any CEN
member.

This amendment exists 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, 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: Rue de la Science 23, B-1040 Brussels
© 2018 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN 13445-3:2014/A5:2018 E
worldwide for CEN national Members.

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
Contents Page
European foreword . 3
1 Modification to 5.4.2, Vessels of all testing groups, pressure loading predominantly
of non-cyclic nature . 4
2 Modifications to Clause 6, Maximum allowed values of the nominal design stress for
pressure parts . 4
3 Modifications to 17.1, Purpose . 5
4 Modifications to 17.2, Specific definitions . 5
5 Modification to 17.3, Specific symbols and abbreviations . 7
6 Modifications to 17.4, Conditions of applicability . 9
7 Modification to 17.5, General . 10
8 Modifications to 17.6, Determination of allowable number of pressure cycles . 16
9 Modifications to 17.9, Testing . 23
10 Addition of a new Annex U (informative), Guidance on negligibility of additional
thermal cycles in fatigue and ratcheting assessment . 23

2

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
European foreword
This document (EN 13445-3:2014/A5:2018) has been prepared by Technical Committee CEN/TC 54
“Unfired pressure vessels”, the secretariat of which is held by BSI.
This European Standard shall be given the status of a national standard, either by publication of an
identical text or by endorsement, at the latest by May 2019, and conflicting national standards shall be
withdrawn at the latest by May 2019.
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, and supports essential requirements of EU Directive(s).
For relationship with EU Directive, see informative Annex ZA, which is an integral part of
EN 13445-3:2014.
According to the CEN-CENELEC Internal Regulations, the national standards organisations of the
following countries are bound to implement this European Standard: 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 the United Kingdom.
3

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
1 Modification to 5.4.2, Vessels of all testing groups, pressure loading
predominantly of non-cyclic nature
Replace the whole subclause with the following one:
“
5.4.2 Vessels of all testing groups, pressure loading predominantly of non-cyclic nature
The DBF requirements specified in Clauses 7 to 16, Annexes G and J, and in Clause 19 (for testing sub-
groups 1c and 3c only) and the DBA requirements of Annex B and Annex C provide satisfactory designs
for pressure loading of non-cyclic nature, i.e. when the number of full pressure cycles or equivalent full
pressure cycles is less than or equal to 500.
n ≤ 500 (5.4-1)
eq
The equivalent number of full pressure cycles n is given by:
eq
3
 
∆P
i
 
nn⋅ (5.4-2)
∑
eq i
 
P
 max 
In the above equation, P is the maximum permissible pressure P calculated for the whole vessel
max max
(see 3.16) in the normal operating load case (see 5.3.2.1).
For simplification, P may be replaced by the calculation pressure P.
max
NOTE The value of 500 equivalent full pressure cycles is only a rough indication. It can be assumed that for
components with irregularities of profile, strongly varying local stress distributions, subjected to additional non-
pressure loads, fatigue damage can occur before 500 cycles.
Cyclic thermal loads can be neglected if:
— for start-up and shutdown cycles, the number shall not exceed 2 000 and the rate of temperature
change at the surface shall be less than 60 °C per hour for ferritic steel sections. The designer can
specify a higher rate of surface temperature change based on favourable/good industry experience
and practice;
— if the requirements of Annex U are satisfied for operating conditions.
If these conditions on pressure and thermal loads are met, then no fatigue analysis is necessary and the
standard requirements of non-destructive testing given in EN 13445-5 shall be applied.
If these conditions cannot be met, then a fatigue assessment is necessary according to either Clause 17
or Clause 18.”.
2 Modifications to Clause 6, Maximum allowed values of the nominal design
stress for pressure parts
In 6.1.3 delete the following:
“For testing group 4 vessels, the maximum value of the nominal design stress for the normal operating
load cases shall be multiplied by 0,9.”.
a
In Table 6-1, delete the following Footnote :
a
" For testing group 4 the nominal design stress shall be multiplied by 0,9.”;
and re-name the following footnotes accordingly.
4
=

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
3 Modifications to 17.1, Purpose
Replace the whole subclause with the following one:
“
17.1.1 This clause specifies:
— an alternative to the 500 cycles rule stated in 5.4.2 for vessels predominantly subjected to pressure
fluctuations,
— a substitute to the 500 cycles rule stated in 5.4.2 for vessels subjected additionally to thermal
gradient fluctuations, and
— rules for the simplified assessment of fatigue damage due to both pressure and thermal gradients
fluctuations.
NOTE The rules in this clause are based on simplified and conservative assumptions. More precise, less
conservative results will usually be obtained by application of Clause 18.”.
In 17.1.2, replace the first sentence with the following one:
“
17.1.2 Other cyclic loads, e.g. due to variation of external loads, are normally to be assessed according
to Clause 18. However, it is permitted to take non-pressure cyclic loads into account in this clause by:”.
In 17.1.2, replace the NOTE with the following one:
“
NOTE This clause gives information for estimating the stress ranges due to pressure and thermal loads only.
When other loads are taken into account, the determination of the corresponding stress ranges is under the
responsibility of the Manufacturer.”.
4 Modifications to 17.2, Specific definitions
Replace Definition 17.2.7 by the following:
“
17.2.7
equivalent number of full pressure cycles
number n of full pressure cycles that cause the same damage as all the applied cycles of various
eq
sources and ranges
Note 1 to entry: For pressure loading only, n is given by Formula (17.5–1).
eq
Note 2 to entry: For pressure + thermal loading, is given by Formula (17.5–4).”.
n
eq
5

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
Replace Definition 17.2.9 by the following:
“
17.2.9
range
value from maximum to minimum (stress or load) in the cycle (twice the amplitude)”.
Replace Definition 17.2.10 by the following:
“
17.2.10
pseudo-elastic stress
stress calculated assuming purely linear elastic material behaviour”.
Replace Definition 17.2.13 by the following:
“
17.2.13
pressure stress factor
factor for determination of the maximum structural stress that may occur under pressure loading in a
vessel detail, due to the geometrical configuration of component(s)”.
Add the following new definitions after Definition 17.2.13:
“
17.2.14
thermal stress factor
factor for determination of the maximum structural stress that may occur under some thermal gradient
type in a vessel detail, due to the geometrical configuration of component(s)
17.2.15
adjacent point
point to be considered for determination of the metal temperature difference on which thermal stresses
are estimated.
Note 1 to entry: They are defined as any two points:
— on the inside and outside surfaces, for a gradient through the thickness;
— along the surface within a distance for a gradient along the longitudinal and/or circumferential
1,75 D ⋅ e
directions of a shell;
— along the surface within a distance 3,5R, for a gradient along the longitudinal and/or circumferential
directions of a flat end, where R is the radius of the point at the highest temperature in the flat end.
6

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
17.2.16
metal temperature difference between adjacent points
temperature difference between adjacent points, determined by reference to the metal temperature at
these points (not the fluid temperature at these points)
17.2.17
theoretical stress concentration factor
ratio of notch stress, calculated on purely elastic basis, to structural stress at same point".
Change accordingly the numbering for Definitions 17.2.14 to 17.2.17.
Replace Definitions 17.2.16 (to be renumbered as 17.2.20) with the following one:
“
17.2.20
critical area
area where the total cumulative fatigue damage (usage factor) exceeds the value D = 0,5”.
max
5 Modification to 17.3, Specific symbols and abbreviations
Replace the whole table with the following one:
"
Symbol Description Unit
C fatigue class C (see Table 17–4) MPa
lowest fatigue class C (see 17.5.4.1) MPa
C
min

allowable number of full pressure cycles
N
eq

D total fatigue damage index, see Formula (17.7–1)
maximum allowable value of total fatigue damage index in non-critical areas
D
max

correction factor to account for influence of wall thickness on fatigue resistance
C
e

CT correction factor to account for influence of temperature on fatigue resistance
E Young's modulus of the material MPa
effective stress concentration factor
K
f

theoretical stress concentration factor
K
t

k number of pressure ranges which together form the loading specification
N allowable number of cycles obtained from the relevant fatigue design curve (suffix i
th
refers to number for i stress range, ik= 1,. )
n number of applied stress cycles
(suffix i refers to number for i th stress range, iq= 1,. )
7

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
Symbol Description Unit
equivalent number of full pressure cycles
n
eq

number of applied pressure cycles
n
P

(suffix i refers to number for i th pressure range, iq= 1,. )
i
number of applied cycles of temperature difference
n
T

(suffix j refers to number for j th range of temperature difference, kq= 1,. )
k
number of applied cycles of combined pressure + temperature difference
n
PT

(suffix k refers to number for k th range of pressure + temperature difference,
kq= 1,. )
k
R radius of the point at the highest temperature in the flat end mm
r transition radius at junction of walls mm
metal temperature difference between adjacent points (see 17.2.15) °C
T
diff

minimum operating temperature during a cycle °C
T
min

maximum operating temperature during a cycle °C
T
max

T* assumed mean cycle temperature °C
u ovality (of circular cross section of a vessel)
α thermal expansion coefficient of the material (°C)-1
δ parameter for measure of misalignment, peaking or flat mm
∆P
pressure range calculated from the algebraic difference of the maximum and MPa

minimum pressures which apply in the cycle under consideration. Vacuum and
other external pressures stress shall be considered negative
NOTE  In that case, some cycles may have a range ΔP greater than the maximum
calculation pressure Pmax of the vessel or part thereof.
∆T range of metal temperature difference between adjacent points (adjacent points are °C
defined at 17.2.15)
2
∆σ
pseudo-elastic stress range N/mm

2
fictitious stress range for insertion into the fatigue design curves N/mm
∆σ *

2
reference stress range of fatigue design curves N/mm
∆σ
R

2
endurance limit at constant stress range N/mm
∆σ
D

2
cut-off limit N/mm
∆σ
Cut

κ thermal stress factor for a vessel detail, given in Table 17–2
η
pressure stress factor for a vessel detail, given in Table 17–1

maximum pressure stress factor found throughout the vessel
η
max

NOTE The pressure P used in Clause 17 is defined in 3.16, NOTE 3.
max
”.
8

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
6 Modifications to 17.4, Conditions of applicability
Replace the Subclause 17.4.1 with the following one:
“
17.4.1 This clause applies to pressure-bearing components and junctions of pressure vessels designed
in accordance with Clauses 7 to 16 without Clause 15, Clauses 20 and 21 and Annex G (i.e. those clauses
and annexes where design by formula applies), with the exception of:
— bellows;
— heat exchanger tubesheets.
NOTE 1 Fatigue assessment of heat exchanger tubesheets can be performed using Annex J of this Standard.
Application of this clause to jacketed vessels is permitted if subjected to pressure cycles only. For
jacketed vessels subjected to both pressure and thermal cycles, application is limited to the non-
jacketed parts.
NOTE 2 It is not necessary to check flanges and their bolts if the adjacent shells are designed according to this
Clause.
It is assumed that the vessels have been designed, manufactured and tested in accordance with all other
requirements of this standard.”.
Replace Entry 17.4.4 with the following one:
“
17.4.4 This clause applies only to components operating below the creep range. Thus, the fatigue
design curves are applicable up to 375 °C for ferritic steels and 425 °C for austenitic steels.”.
Replace Entry 17.4.5 with the following one:
“
17.4.5 As regards weld defects:
For application of this clause, the following conditions (as required by EN 13445-5:2014, Annex G) shall
be met in addition to the general acceptance criteria for weld imperfections given in EN 13445-5:2014:
— no undercut,
— no root concavity,
— no lack of penetration for full penetration welds, except as permitted by Table 17-4,
— 100 % inspection, visually and by NDT, with acceptance criteria as specified in EN 13445-5:2014,
Annex G, of all critical areas.”.
Replace Entry 17.4.8 with the following one:
“
17.4.8 Vessels which fulfil the requirements of 17.5.3 or 17.5.4 or 17.5.5 are of non-cyclic nature and
the standard requirements of non-destructive testing given in EN 13445-5 shall be applied.”.
9

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
Add the following new numbered entries:
“
17.4.9 For application of 17.6, instructions for appropriate maintenance shall be included in the
operating instructions.
NOTE Recommendations on appropriate maintenance are given in Annex M.
17.4.10 Guidance for metal temperature estimates:
For cases where significant thermal loading occurs, attention is drawn to the importance of
approximating as closely as possible the temperature distributions that appear in the vessel walls
during service, in order to reduce as much as possible the conservatism of the thermal stress estimate
and resulting fatigue assessment.
In this respect, the quite common approach which consists in taking the fluid temperature variations as
representative of the temperature variations of the vessel wall surface is not recommended because it
generally leads to strong over-estimates of the real thermal gradients. As far as possible these gradients
should be determined from thermal calculations (even simple ones based on analytic models) in which
the thermal exchange which takes place at the fluid-metal interface is taken into account.
To enable such calculations, enough information on the thermodynamic conditions attached to the
process should be obtained from the Purchaser (e.g.: fluid heating or cooling rate, thermal exchange
coefficient at fluid-metal interface, etc.).”.
7 Modification to 17.5, General
Replace the whole subclause with the following one (Figures 17.5-1, 17.5-2 and 17.5-3 are thereby
deleted):
“
17.5 General
17.5.1 Pressure and temperature ranges to be considered for the fatigue assessment:
The various ranges ()∆P to be considered for the fatigue assessment shall be obtained by applying a
i
cycle counting method described in Annex NB and considering fluctuations of the pressure P instead of
fluctuations of stress.
The various ()∆T to be considered for the fatigue assessment shall be obtained by applying the same
diff i
cycle counting methods but considering fluctuations of the metal temperature difference T instead of
diff
fluctuations of stress.
To distinguish whether the pressure and the thermal cycles act simultaneously or not simultaneously
the load history (variation with time) of the both loads shall be considered. When the duration time of
the cycle (time from minimum value via maximum value to minimum value) from one load type (e.g.
pressure) is overlapped with the duration time of the other load type (e.g. temperature differences)
then these cycles act simultaneously. On the contrary, if during the complete cycle time of one load type
the other load type does not change then the cycles act not simultaneously.
The ∆P ranges are normally valid for assessment of all vessel parts subjected to the same pressure
fluctuations. In case where pressure fluctuations result (at least partly) from hydrostatic pressure or
from pressure differences between adjacent vessel chambers, the pressure ranges may be different
from part to part.
10

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
The ∆T ranges are valid only for assessment of the vessel detail where the particular metal
diff
temperature difference fluctuations considered take place. If the most critical detail for fatigue under
combined pressure + thermal loading is not known at first, all candidate details should be investigated
and the corresponding sets of ∆T established.
diff
17.5.2 The calculations according to 17.6 shall be performed for the various components of the vessels.
The lowest life obtained is the fatigue life of the vessel.
17.5.3 Pressure and temperature ranges which may be neglected for the fatigue assessment:
When designs meet the requirements:
η ≤ 3,
f ≤ 160 MPa with f taken at the calculation temperature T,
CC⋅
e T
pressure fluctuations of range ∆P lower than the following percentages of P can be neglected,
max
regardless of their number:
for C = 40
3,5 % of P
max
for C = 56
4,5 % of P
max
for C = 63
P
5,5 % of
max
for C = 71
6 % of P
max
for C = 80
7 % of P
max
for C = 90 and Class UW
7,5 % of P
max
Otherwise, if the number of start-up and shut-down cycles at operating pressure is smaller than 500
and if no cycle of intermediate range between operating pressure and the neglected fluctuations occur:
for C = 40
6 % of P
max
for C = 56
8,5 % of P
max
for C = 63
9,5 % of P
max
for C = 71
11 % of P
max
for C = 80
12,5 % of P
max
for C = 90 and Class UW
14 % of P
max
480
For other values of η and f, the above percentages shall be multiplied by the ratio .
η ⋅ f
This rule for neglecting pressure ranges is applicable:
— for the vessel as a whole if the same ΔP acts on all vessel parts,
— component by component if different ΔP act on different parts (see 17.5.1, fourth paragraph).
11

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
For simplification, P may be replaced by the calculation pressure P.
max
For guidance on negligible thermal cycles ()∆T see Annex U.
diff i
17.5.4 Alternative to the 500 cycles rule stated in 5.4.2:
Provided the conditions required in 17.5.4.2 are fulfilled, the condition stated in 5.4.2, Formula (5.4-1),
for checking the number of full pressure cycles (or equivalent number of full pressure cycles) against
the uniform 500 cycles limit valid for any vessel designed according to EN 13445-3 may be disregarded
and replaced by condition (17.5-1):
3
 
∆P
i
nn= ⋅≤  N (17.5-1)
∑
eq P,i eq
 
P
 max 
i
where:
is the equivalent number of full pressure cycles,
n
eq
is the number of pressure cycles at pressure ranges ΔP lower than or equal to the full
n i
P,i
pressure P
is the maximum permissible pressure calculated in the normal operating load case
P
max
(see 5.3.2.1)
NOTE 1
In Formula (17.5–1), n is defined as in Formula (5.4–2).
eq
is the allowable number of full pressure cycles defined in 17.5.4.1.
N
eq
Condition (17.5-1) may be checked:
— for the vessel as a whole, with calculated using for ∆P the pressure fluctuations acting at the
n
eq i
location where their range is maximum and for P the maximum permissible pressure of the
max
vessel (see 3.16),
∆P
— component by component, with n calculated using for the pressure fluctuations acting on the
i
eq
component and for P the maximum permissible pressure of the same component.
max
NOTE 2 The check component by component is of interest only if the range of the pressure fluctuations varies
along the vessel due to additional hydrostatic pressure, or if the vessel has parts which separate different pressure
chambers.
For simplification, P may be replaced by the calculation pressure P.
max
Use of Formula (17.5-1) to calculate is valid under the condition that the contribution of non-
n
eq
pressure loads to cyclic loading can be neglected.
When this condition is not met, a fatigue life assessment of the vessel is necessary and shall be
performed using the rule given in 17.5.5 (if applicable), a simplified fatigue analysis according to the
rest of Clause 17 (Subclauses 17.6 to 17.7) or a detailed fatigue analysis according to Clause 18.
NOTE 3 The rule given in 17.5.5 allows taking into account additional cycles of thermal origin only. The rest of
Clause 17 is mainly devoted to pressure and thermal cycles, but can take into account loading cycles of other
origins (see 17.1.2). Clause 18 enables consideration of all types of loading cycles.
12

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
17.5.4.1 Allowable number of full pressure cycles based on nominal design stress, weld types
and maximum stress factor:
The allowable number of full pressure cycles is given by:
3
 
C ⋅⋅C C
6 min e T
N =2⋅ 10 ⋅   (17.5-2)
eq
η ⋅ f
 
 max 
where
is the lowest fatigue class C among all welded joints of the vessel or the class of the
C
min
component if a check component by component is made, or C = 40 MPa alternatively as
min
a conservative assumption.

The value C = 40 MPa shall be used if the vessel includes welded details which cannot be
min
found (directly or by assimilation) in Table 17–4 and are likely to present a low fatigue
resistance.

For vessels which do not contain any welded zone, the C = 90 shall be used.
min
is the thickness correction for e > 25 mm , as defined in 17.6.2.1
C
e
is the temperature correction for >°100 C , as defined in 17.6.2.2.
T *
C
T
is the maximum pressure stress factor found throughout the vessel:
η
max
In looking for the maximum pressure stress factor η , shape deviations (mainly peaking)
max
at longitudinal seam welds should always be considered, because they often may be source
of high values of η.
f
is the nominal design stress at calculation temperature of the load case for which P is
max
calculated.
If, for simplification, n is calculated using the calculation pressure P instead of P , as permitted by
eq
max
5.4.2, f is the nominal design stress, at the corresponding calculation temperature.
When applying this formula:
— η shall be selected according to Table 17-1.
max
In case where the vessel comprises details for which no η value is given in Table 17-1 and no
conservative value of η can be safely estimated, Formula (17.5-2) is not applicable and condition (17.5-
1) shall not be used.
— the thickness to be considered for calculation of C shall be the largest of all components involved
e
in the welded joints of the fatigue class C .
min
— the temperature T * to be considered for calculation of C shall be calculated taking for T and
max
T
T respectively the maximum and minimum temperatures occurring during the whole cycling
min
period.
13

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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
— the nominal design stress f to be considered shall be the largest of all materials involved in the
welded joints of the fatigue class C . In case of uncertainty, the largest among all vessel
min
components shall be used.
In case where the allowable number of full pressure cycles N given by Formula (17.5-2) is lower than
eq
500, the design should be modified to reach that number.
The curves showing the number of cycles N given by Formula (17.5-2) greater than or equal to 500
eq
η = 3 and where no correction is needed (i.e. when
are plotted in Figure 17.5-1 for the case where
max
C = 1 and C = 1 ).
e t

Key
1 = class 90 5 = class 56
2 = class 80 6 = class 40
3 = class 71 7 = 500 cycles
4 = class 63
Figure 17.5–1 — Allowable number of equivalent full pressure cycles (assuming η = 3 and
max
CC 1
)
eT
17.5.4.2 Conditions of application of Formula (17.5-2):
3.P
max
— No pressure cycle range ∆P shall be greater than ;
i
η
max
— No welded flat end shall be designed using the alternative rule of 10.4.4.4;
— No flat end shall have pairs of adjacent openings designed as a fictitious single opening using the
alternative calculation given at end of 10.6.2.1.
14
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SIST EN 13445-3:2014/A5:2018
EN 13445-3:2014/A5:2018 (E)
17.5.5 Substitute to the 500 cycles rule stated in 5.4.2 or to the alternative rule stated in 17.5.4,
for cases where thermal cycles cannot be neglected
17.5.5.1 Global assessment
When the 500 cycles rule stated in 5.4.2 or the alternative rule stated in
...