EN 13480-3:2024
(Main)Metallic industrial piping - Part 3: Design and calculation
Metallic industrial piping - Part 3: Design and calculation
This document specifies the design and calculation of industrial metallic piping systems, including supports, covered by EN 13480 series.
Metallische industrielle Rohrleitungen - Teil 3: Konstruktion und Berechnung
Dieses Dokument legt die Konstruktion und Berechnung von metallischen industriellen Rohrleitungen einschließlich ihrer Halterungen, soweit durch EN 13480 abgedeckt, fest.
Tuyauteries industrielles métalliques - Partie 3: Conception et calcul
Le présent document spécifie la conception et le calcul des réseaux de tuyauteries industrielles métalliques, supports inclus, couverts par la série EN 13480.
Kovinski industrijski cevovodi - 3. del: Konstruiranje in izračun
Ta dokument določa konstruiranje in izračun kovinskih industrijskih cevovodov, vključno z nosilci, iz skupine standardov EN 13480.
General Information
- Status
- Published
- Publication Date
- 23-Jul-2024
- Technical Committee
- CEN/TC 267 - Industrial piping and pipelines
- Drafting Committee
- CEN/TC 267/WG 3 - Design and calculation
- Current Stage
- 6060 - Definitive text made available (DAV) - Publishing
- Start Date
- 24-Jul-2024
- Due Date
- 09-Aug-2024
- Completion Date
- 24-Jul-2024
Relations
- Effective Date
- 31-Jul-2024
- Effective Date
- 31-Jul-2024
- Effective Date
- 31-Jul-2024
- Effective Date
- 31-Jul-2024
- Effective Date
- 31-Jul-2024
- Effective Date
- 18-Jan-2023
Overview
EN 13480-3:2024 - Metallic industrial piping: Part 3 - Design and calculation (CEN) defines the principles, rules and calculation methods for the structural design of metallic industrial piping systems (including supports) covered by the EN 13480 series. Approved by CEN (9 July 2024) and adopted in national versions (e.g., Slovenia, December 2024), this part supersedes earlier editions of EN 13480-3. It is published in the three CEN languages (EN/FR/DE).
Key topics and technical requirements
EN 13480-3:2024 addresses the technical aspects required for safe, code-compliant piping design:
- Scope, terms and symbols - definitions, notation and units used throughout the design rules.
- Basic design criteria - design principles, load types and combinations, and design conditions.
- Loadings - internal/external pressure, thermal loads, weight, seismic and wind effects, combination rules.
- Thickness and tolerances - required wall thickness calculation, manufacturing tolerances and joint coefficients.
- Design stresses - time-independent and time-dependent nominal design stresses for various metallic materials (steels, austenitic steels, nickel/chromium alloys, castings).
- Components under internal pressure - detailed rules for straight pipes, bends/elbows, mitre bends, reducers, flexible components, bolted flanges and special forged items.
- Ends and closures - design of dished, torispherical, ellipsoidal, and flat ends including reinforcement rules.
- Openings and branches - limits, reinforcement methods, isolated and adjacent openings, and special branch geometries (Y-pieces, triforms).
- External pressure design - methods for components subject to vacuum or external compression.
- Supports - inclusion of piping supports within the scope of design and calculation rules.
Note: EN 13480-3 provides procedural requirements and calculation methods rather than specific fabrication instructions.
Practical applications
This standard is used to perform structural design and strength verification of process piping in industries such as oil & gas, chemical, petrochemical, power generation and heavy manufacturing. Typical uses:
- Calculating wall thicknesses and reinforcing requirements for pressurized pipelines.
- Verifying flange, reducer and branch connection integrity.
- Assessing stresses for thermal expansion and combined loading cases.
- Designing openings and reinforcements for vessels and piping assemblies.
Who should use this standard
- Piping and mechanical engineers performing design and stress analysis
- Plant designers and EPC contractors preparing piping specifications and drawings
- Fabricators and welding inspectors for design verification and acceptance criteria
- Asset owners and safety/maintenance teams for compliance and inspection planning
Related standards
- Other parts of the EN 13480 series (material, fabrication, inspection) and national implementations. Use EN 13480-3 alongside applicable codes and project specifications for complete piping design compliance.
Keywords: EN 13480-3, metallic industrial piping, piping design and calculation, pipe stress, internal pressure, pipe supports, flange design, reducer calculation.
Frequently Asked Questions
EN 13480-3:2024 is a standard published by the European Committee for Standardization (CEN). Its full title is "Metallic industrial piping - Part 3: Design and calculation". This standard covers: This document specifies the design and calculation of industrial metallic piping systems, including supports, covered by EN 13480 series.
This document specifies the design and calculation of industrial metallic piping systems, including supports, covered by EN 13480 series.
EN 13480-3:2024 is classified under the following ICS (International Classification for Standards) categories: 23.040.01 - Pipeline components and pipelines in general. The ICS classification helps identify the subject area and facilitates finding related standards.
EN 13480-3:2024 has the following relationships with other standards: It is inter standard links to EN 13480-3:2017/A3:2020, EN 13480-3:2017/A1:2021, EN 13480-3:2017/A5:2022, EN 13480-3:2017/A2:2020, EN 13480-3:2017/A4:2021, EN 13480-3:2017. Understanding these relationships helps ensure you are using the most current and applicable version of the standard.
EN 13480-3:2024 is associated with the following European legislation: EU Directives/Regulations: 2014/68/EU; Standardization Mandates: M/071, M/601. When a standard is cited in the Official Journal of the European Union, products manufactured in conformity with it benefit from a presumption of conformity with the essential requirements of the corresponding EU directive or regulation.
You can purchase EN 13480-3:2024 directly from iTeh Standards. The document is available in PDF format and is delivered instantly after payment. Add the standard to your cart and complete the secure checkout process. iTeh Standards is an authorized distributor of CEN standards.
Standards Content (Sample)
SLOVENSKI STANDARD
01-december-2024
Nadomešča:
SIST EN 13480-3:2018
SIST EN 13480-3:2018/A1:2021
SIST EN 13480-3:2018/A2:2020
SIST EN 13480-3:2018/A3:2020
SIST EN 13480-3:2018/A4:2021
SIST EN 13480-3:2018/A5:2023
Kovinski industrijski cevovodi - 3. del: Konstruiranje in izračun
Metallic industrial piping - Part 3: Design and calculation
Metallische industrielle Rohrleitungen - Teil 3: Konstruktion und Berechnung
Tuyauteries industrielles métalliques - Partie 3: Conception et calcul
Ta slovenski standard je istoveten z: EN 13480-3:2024
ICS:
23.040.10 Železne in jeklene cevi Iron and steel pipes
77.140.75 Jeklene cevi in cevni profili Steel pipes and tubes for
za posebne namene specific use
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
EN 13480-3
EUROPEAN STANDARD
NORME EUROPÉENNE
July 2024
EUROPÄISCHE NORM
ICS 23.040.01 Supersedes EN 13480-3:2017
English Version
Metallic industrial piping - Part 3: Design and calculation
Tuyauteries industrielles métalliques - Partie 3: Metallische industrielle Rohrleitungen - Teil 3:
Conception et calcul Konstruktion und Berechnung
This European Standard was approved by CEN on 9 July 2024.
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. 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 European Standard 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, 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.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION
EUROPÄISCHES KOMITEE FÜR NORMUNG
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2024 CEN All rights of exploitation in any form and by any means reserved Ref. No. EN 13480-3:2024 E
worldwide for CEN national Members.
Contents Page
European foreword . 10
1 Scope . 12
2 Normative references . 12
3 Terms, definitions, symbols and units . 13
3.1 Terms and definitions . 13
3.2 Symbols and units . 13
4 Basic design criteria . 15
4.1 General . 15
4.2 Loadings. 15
4.2.1 General . 15
4.2.2 Combination of loads . 16
4.2.3 Loads for dimensioning . 16
4.2.4 Other loads to be taken into account . 18
4.2.5 Design conditions . 19
4.3 Thickness . 21
4.4 Tolerances . 24
4.5 Joint coefficient . 24
4.6 Dimensioning of piping components subject to pressure . 25
5 Design stresses . 25
5.1 General . 25
5.2 Time-independent nominal design stress . 26
5.2.1 Steels other than austenitic steels . 26
5.2.2 Austenitic steels . 26
5.2.3 Nickel and / or chromium alloy steels . 27
5.2.4 Steels castings . 27
5.2.5 Additional requirements for steels with no specific control . 27
5.3 Time-dependent nominal design stress . 28
5.3.1 General . 28
5.3.2 Steels . 28
5.3.3 Nickel and/or chromium alloy steels. 29
6 Design of piping components under internal pressure . 29
6.1 Straight pipes . 29
6.2 Pipe bends and elbows . 29
6.2.1 General . 29
6.2.2 Symbols . 30
6.2.3 Required wall thicknesses . 30
6.3 Mitre bends. 31
6.3.1 General . 31
6.3.2 Symbols . 31
6.3.3 Effective radius of mitre bend . 32
6.3.4 Multiple mitre bends . 32
6.3.5 Single mitre bends . 33
6.3.6 Adjacent straight pipe sections of mitre bends . 33
6.4 Reducers . 33
6.4.1 Conditions of applicability . 33
6.4.2 Specific definitions . 34
6.4.3 Specific symbols and abbreviations . 34
6.4.4 Conical shells . 36
6.4.5 Junctions - general . 36
6.4.6 Junction between the large end of a cone and a cylinder without a knuckle . 37
6.4.7 Junction between the large end of a cone and a cylinder with a knuckle . 39
6.4.8 Junction between the small end of a cone and a cylinder . 41
6.4.9 Offset reducers . 43
6.4.10 Special forged reducers . 43
6.5 Flexible piping components . 44
6.5.1 General . 44
6.5.2 Expansion joints . 44
6.5.3 Corrugated metal hose assemblies . 46
6.6 Bolted flange connections . 47
6.6.1 General . 47
6.6.2 Symbols . 47
6.6.3 Standard flange . 47
6.6.4 Non-standard flange . 48
7 Design of ends under internal pressure . 48
7.1 Dished ends . 48
7.1.1 Symbols . 48
7.1.2 Hemispherical ends . 49
7.1.3 Torispherical ends . 50
7.1.4 Ellipsoidal ends . 51
7.1.5 Calculation of β . 52
7.2 Circular flat ends . 56
7.2.1 General . 56
7.2.2 Symbols . 56
7.2.3 Unstayed flat circular ends welded to cylindrical shells/pipes . 58
7.2.4 Unstayed flat circular bolted ends . 65
7.2.5 Reinforcements of openings in unstayed flat ends. 71
8 Openings and branch connections . 74
8.1 General . 74
8.2 Symbols . 74
8.3 Limitations . 75
8.3.1 Thickness ratio . 75
8.3.2 Openings in the vicinity of discontinuities . 77
8.3.3 Types of reinforcement . 79
8.3.4 Calculation method . 79
8.3.5 Elliptical openings and oblique branch connections . 80
8.3.6 Reinforcing pads . 81
8.3.7 Dissimilar material of shell and reinforcements . 81
8.3.8 Extruded outlets . 82
8.3.9 Forged tee . 82
8.3.10 Branches in bends or elbows . 83
8.3.11 Screwed-in branches . 83
8.4 Isolated openings . 84
8.4.1 General . 84
8.4.2 Unreinforced openings . 87
8.4.3 Reinforced openings with d /D < 0,8 . 87
i i
8.4.4 Reinforced single openings with 0,8< d /D ≤ 1,0 . 93
i i
8.5 Adjacent openings . 93
8.5.1 Unreinforced openings. 93
8.5.2 Reinforced openings with d /D ≤ 0,8 . 93
i i
8.6 Design of special piping components . 94
8.6.1 Cylindrical Y-pieces . 94
8.6.2 Spherical Y-pieces . 95
8.6.3 Triform reinforced branches . 96
9 Design of piping components under external pressure . 97
9.1 General . 97
9.1.1 External calculation pressure . 97
9.1.2 Exception from verification against external pressure . 98
9.1.3 General acceptance criteria . 98
9.2 Symbols and elastic stress limits . 99
9.2.1 Symbols . 99
9.2.2 Stress limits . 101
9.3 Cylindrical pipes, elbows and mitre bends . 102
9.3.1 Determination of lengths . 102
9.3.2 Interstiffener collapse . 104
9.3.3 Overall collapse of stiffened pipes . 105
9.3.4 Stiffener stability . 106
9.3.5 Heating/cooling channels . 109
9.4 Reducers (conical shells) . 110
9.5 Dished ends . 112
9.5.1 Hemispherical ends . 112
9.5.2 Torispherical ends . 113
9.5.3 Ellipsoidal ends . 113
10 Design for cyclic loading . 113
10.1 General . 113
10.2 Exemption from detailed fatigue analysis . 113
10.3 Fatigue design for cyclic pressure . 114
10.3.1 Equivalent full load cycles. 114
10.3.2 Simplified fatigue analysis . 114
10.4 Fatigue design for thermal gradients. 129
10.4.1 General . 129
10.4.2 Design guidance . 129
10.5 Fatigue design for combined loads . 129
11 Integral attachments . 130
11.1 General . 130
11.2 Allowable stresses . 130
11.3 Symbols . 131
11.4 Hollow circular attachments . 133
11.4.1 Limitations . 133
11.4.2 Preliminary calculations . 133
11.4.3 Analysis of attachments welded to pipe with a full penetration weld . 135
11.4.4 Analysis of attachments welded to pipe with fillet or partial penetration weld . 136
11.5 Rectangular attachments . 136
11.5.1 Limitations . 136
11.5.2 Preliminary calculations . 136
11.5.3 Analysis of attachments welded to pipe with a full penetration weld . 138
11.5.4 Analysis of attachments welded to pipe with fillet or partial penetration weld . 139
11.6 Stress analysis of the run pipe . 139
11.7 Shear stress analysis in attachment . 141
11.7.1 Hollow circular attachments . 141
11.7.2 Rectangular attachments . 141
11.8 Alternative calculation methods . 141
12 Flexibility analysis and acceptance criteria . 142
12.1 Basic conditions . 142
12.1.1 General . 142
12.1.2 Loading conditions . 142
12.1.3 Allowable stresses . 142
12.2 Piping flexibility . 144
12.2.1 General . 144
12.2.2 Basic conditions . 144
12.2.3 Displacement strains . 144
12.2.4 Displacement stresses . 145
12.2.5 Stress range . 146
12.2.6 Cold pull . 146
12.2.7 Properties for flexibility analysis . 146
12.2.8 Supporting conditions. 147
12.2.9 Expansion joints . 148
12.2.10 Flexibility analysis . 149
12.3 Flexibility analysis. 151
12.3.1 General . 151
12.3.2 Stress due to sustained loads . 152
12.3.3 Stress due to sustained and occasional or exceptional loads . 153
12.3.4 Stress range due to thermal expansion and alternating loads. 155
12.3.5 Additional conditions for the creep range . 157
12.3.6 Stresses due to a single non-repeated support movement . 157
12.3.7 Determination of resultant moments . 158
12.3.8 Reactions . 160
12.4 Fatigue analysis . 160
12.5 Vibration . 160
13 Pipe Supports . 161
13.1 General requirements . 161
13.1.1 General . 161
13.1.2 Classification of supports . 162
13.1.3 Additional definitions . 162
13.1.4 Boundaries . 164
13.1.5 Pipe supports welded to the pipe . 166
13.2 Selection of pipe supports . 167
13.2.1 General . 167
13.2.2 Detail design of pipe supports . 168
13.2.3 Support location . 169
13.3 Constant hangers/base mounted (pedestal) constant supports . 169
13.3.1 General . 169
13.3.2 Load deviation from calibrated load . 169
13.3.3 Site adjustment of the calibrated load . 169
13.3.4 Travel reserve (Overtravel) . 169
13.3.5 Blocking . 169
13.3.6 Identification Marking/Name plate . 169
13.4 Variable load spring hangers and base mounted (pedestal) variable load spring
supports . 170
13.4.1 General . 170
13.4.2 Tolerance on spring rate . 171
13.4.3 Travel reserve (Overtravel) . 171
13.4.4 Blocking . 171
13.4.5 Name plate . 171
13.5 Rigid struts . 171
13.6 Shock arrestors, shock absorber (snubber) . 172
13.7 Sliding supports . 172
13.8 Anchors . 173
13.9 Documentation of supports . 173
13.10 Marking of supports . 173
13.11 Design and manufacture of pipe supports . 173
13.11.1 Material requirements . 173
13.11.2 Design temperatures for support components . 173
13.11.3 Design details . 175
13.11.4 Determination of component sizes . 175
13.11.5 Welded connections . 177
13.11.6 Bolted connections . 179
13.11.7 Additional requirements on springs . 182
13.11.8 Design details for rigid struts. 182
13.11.9 Design details for shock arrestors, shock absorbers (snubbers) . 182
13.11.10 Clamps for shock arrestors, rigid struts . 183
13.11.11 Alternative rules for design and manufacture of pipe supports. 184
Annex A (informative) Dynamic effect. 185
A.1 General . 185
A.1.1 Introduction . 185
A.1.2 Vibration design guidelines . 185
A.2 Analysis by calculation . 191
A.2.1 General . 191
A.2.2 Seismic events . 192
A.2.3 Rapid valve closure . 197
A.2.4 Flow induced vibration . 200
A.2.5 Safety valve discharge . 203
A.2.6 Allowable stresses . 205
A.2.7 Structural vibration properties . 205
A.3 Alternative means of design verification. 207
A.3.1 Comparative studies . 207
A.3.2 Full scale testing . 208
A.3.3 Reduced scale testing . 208
A.4 Validation (measuring) . 208
Annex B (normative) More accurate calculation of bends and elbows . 209
B.1 General . 209
B.2 Symbols and units . 209
B.3 Required wall thickness . 210
B.4 Calculation . 211
B.4.1 Calculation of wall thickness . 211
B.4.2 Stress calculation . 213
Annex C (informative) Expansion joints . 217
C.1 Incorporation of expansion joints into piping systems . 217
C.1.1 General . 217
C.1.2 Types of expansion joints . 218
C.1.3 Design of expansion joints . 218
C.1.4 Designing with expansion joints . 219
C.1.5 Analyses and calculation . 221
C.1.6 Cold pull . 221
C.2 Maximum spacing for unrestrained axially compensated straight runs . 222
C.2.1 General . 222
C.2.2 Calculation rules . 222
C.2.3 Maximum spacing for specified conditions . 223
C.3 Indication for the design of expansion joints . 224
C.3.1 General . 224
C.3.2 Information for the system analyst . 224
Annex D (normative) Flanges . 225
D.1 Purpose . 225
D.2 Specific terms and definitions . 225
D.3 Specific symbols and abbreviations .
...
EN 13480-3:2024は、産業用金属配管システムの設計および計算に関する標準を示しています。この文書は、EN 13480系列の一部として、金属製配管の設計時に考慮すべき重要な要素を明確に定義しています。 この標準の範囲は非常に広く、産業用配管システムの設計に必要な概念、原則、および計算方法を包括的にカバーしています。特に、配管の耐久性や安全性を確保するための設計基準が詳細に記載されており、設計者にとって不可欠なリソースとなっています。加えて、支持構造に関するガイダンスも提供されており、実際の設計における実用性が高いのが特徴です。 また、EN 13480-3:2024は、国際的に認知されている標準であり、業界全体での一貫性を促進します。この標準を適用することで、設計者は高い信頼性を持つ配管システムを構築することができ、事故や故障のリスクを低減することが可能です。 全体として、EN 13480-3:2024は、産業用金属配管の設計と計算のための基準として非常に重要であり、その強みは、明確な設計基準と包括的なガイダンスにあります。この標準を活用することで、業界内での効率的な設計プロセスを支援し、製品の安全性と信頼性を向上させることができます。
The SIST EN 13480-3:2024 standard provides a comprehensive framework for the design and calculation of metallic industrial piping systems, establishing essential guidelines that ensure safety, reliability, and efficiency in the construction and maintenance of these systems. This standard is pivotal for engineers and designers involved in the piping industry, as it defines detailed methodologies for the structural integrity and operational performance of piping installations. One of the key strengths of EN 13480-3:2024 is its thorough approach to the various design elements that govern the behavior of industrial metallic piping systems. By incorporating a range of parameters such as temperature fluctuations, pressure levels, and material characteristics, the standard ensures that the piping systems can withstand the operational stresses they are subject to in real-world applications. Additionally, it emphasizes the importance of supports within piping systems, providing guidelines that promote both mechanical stability and functionality. This standard also highlights the relevance of compliance with the broader EN 13480 series, which ensures a harmonized approach across different aspects of piping design, construction, and maintenance. By aligning with other sections within this series, EN 13480-3:2024 fosters integration and coherence in the standards applied to various piping materials and configurations, enhancing overall project quality and safety. Moreover, the standard’s focus on design calculations empowers engineers to make informed decisions during the planning phase, optimizing resource allocation while minimizing risks. The emphasis on clear, structured methodologies streamlines the design process, promoting consistency in the design of metallic industrial piping systems. In summary, the SIST EN 13480-3:2024 standard stands out for its expansive scope, thorough design requirements, and its critical alignment with the overall EN 13480 framework. Its emphasis on detailed calculation procedures and structural integrity makes it a vital reference for professionals in the field looking to ensure safe and effective industrial piping systems.
La norme SIST EN 13480-3:2024 est un document crucial pour le secteur des pipelines industriels en métal, car elle fournit des lignes directrices détaillées sur la conception et le calcul de ces systèmes de tuyauterie. Son domaine d'application est clairement défini, couvrant l'ensemble des systèmes de tuyauterie métallique industriels et incluant les supports, ce qui permet une approche intégrée et cohérente dans le processus de conception. L'un des points forts de cette norme est sa capacité à standardiser les méthodes de calcul. Cela garantit que toutes les parties prenantes, des ingénieurs aux fabricants, puissent suivre des procédures uniformes, minimisant ainsi les risques d'erreurs de conception. En outre, la norme intègre des exigences de sécurité et de fiabilité essentielles, répondant aux normes européennes en matière de qualité et de durabilité des installations. Ce document est particulièrement pertinent dans le contexte actuel où les industries cherchent à optimiser la performance de leurs systèmes tout en respectant les réglementations environnementales. En fournissant des bases solides pour la conception de tuyauteries, la norme SIST EN 13480-3:2024 permet de garantir la sécurité et l'efficacité des installations industrielles tout en favorisant des pratiques durables. En résumé, cette norme se positionne comme un outil indispensable pour la conception et le calcul des tuyauteries industrielles en métal, en offrant un cadre robuste qui favorise l'harmonisation des pratiques au sein de l'industrie. Sa portée, ses forces et sa pertinence font de la SIST EN 13480-3:2024 un document essentiel pour tous les acteurs impliqués dans la conception de systèmes de tuyauterie métalliques.
Die Norm EN 13480-3:2024 ist ein entscheidendes Dokument, das sich mit dem Design und der Berechnung von metallischen Industriepipelines befasst. Der zentrale Umfang dieser Norm umfasst nicht nur die Designanforderungen, sondern auch die Berechnungsmethoden für industrielle Rohrleitungssysteme und ihre Unterstützungen. Durch die explizite Abgrenzung zu anderen Teilen der EN 13480-Serie wird sichergestellt, dass Anwender eine klare und umfassende Grundlage für die Umsetzung ihrer Projekte erhalten. Ein herausragendes Merkmal dieser Norm ist ihre Fähigkeit, eine solide Grundlage für die Sicherheit und Effizienz von Rohrleitungssystemen zu schaffen. Die spezifischen Anforderungen an das Design helfen Ingenieuren, potenzielle Schwachstellen in den frühen Phasen der Planung zu identifizieren und zu beheben, was letztendlich zu einer höheren Betriebssicherheit führt. Darüber hinaus werden in der EN 13480-3:2024 auch moderne Ansätze zur Berechnung der Belastungen berücksichtigt, die durch unterschiedliche Betriebsbedingungen entstehen können. Dies steigert die Relevanz der Norm in einem sich kontinuierlich weiterentwickelnden industriellen Umfeld. Die Stärken der Norm liegen in ihrer umfassenden Abdeckung der verschiedenen Aspekte des Rohrleitungsdesigns, einschließlich der Materialauswahl und der Berücksichtigung von thermischen und mechanischen Belastungen. Die Standardisierung dieser Prozesse ermöglicht eine einheitliche und qualitativ hochwertige Auslegung von Systemen, die internationalen Maßstäben entspricht. Wartbarkeit und Langlebigkeit von metallischen Rohrleitungssystemen werden ebenfalls durch die Norm gefördert, was zu geringeren langfristigen Kosten für Betreiber führt. Insgesamt ist die EN 13480-3:2024 ein unverzichtbares Dokument für Fachleute im Bereich des industriellen Rohrleitungsbaus. Die Norm vereint technisches Wissen mit best practices und bietet so eine wertvolle Ressource, um den spezifischen Anforderungen der Branche gerecht zu werden. Die Relevanz dieser Norm wird durch die zunehmenden Herausforderungen in der Industrie, wie Nachhaltigkeit und Energieeffizienz, zusätzlich verstärkt.
SIST EN 13480-3:2024는 금속 산업 배관 시스템의 설계 및 계산을 규정하는 문서로, EN 13480 시리즈에 포함된 다양한 구성 요소들, 특히 지지 구조물에 대한 명확한 지침을 제공합니다. 이 표준은 산업 배관 시스템의 구조적 안전성을 확보하기 위한 중요한 역할을 하며, 각기 다른 산업 분야에서의 적용 가능성을 고려한 포괄적인 접근 방식을 채택하고 있습니다. 이 표준의 강점은 그 세부적인 설계 요건과 계산 방법에 있습니다. SIST EN 13480-3:2024는 최신 품질 기준과 기술 발전을 반영하여, 기술적 신뢰성을 보장합니다. 또한, 핵심적인 요소들에 대한 비판적인 검토를 통해, 실제 적용 과정에서 발생할 수 있는 다양한 문제점들에 대한 예방책을 제시합니다. 또한, 이 표준은 금속 배관 시스템의 설계 시 필수적으로 고려해야 할 요소들을 체계적으로 정리하여, 엔지니어들에게 실용적인 가이드를 제공합니다. 이러한 점에서 SIST EN 13480-3:2024는 산업 전반에 걸쳐 매우 중요한 문서로, 특히 에너지, 화학, 제약 등 밀접하게 관련된 분야에서의 배관 설계 및 계산에 중대한 영향을 미칠 것으로 기대됩니다. 결론적으로, SIST EN 13480-3:2024는 금속 산업 배관 시스템의 설계와 계산을 위한 필수적이고도 실용적인 표준으로, 산업 안전과 품질을 유지하는 데 기여할 중요한 참고 자료입니다.
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