
This article explains Hiltiβs offering when it comes to EN 13480-3 with regards to the latest version from 2024. It will help to answer specific questions in comparison with EN 1993-1-1 (Eurocode 3 referred later in this document as EC 3).

EN 13480-3 is part of the European standard EN 13480, which specifies the requirements
for the design and calculation of industrial metallic piping systems, including primary pipe
fasteners such as pipe shoes. The standard ensures that piping systems are designed to
operate safely under various conditions such as pressure, temperature, and mechanical
stress.
This standard was published at the end of 2002 and has undergone several revisions to
keep up with technological advancements and industry needs, leading to the latest version
published on 2024-12-31 with specific updates regarding.
- Eurocode as normative references
- Modifications to manufacturing of pipe supports β how to design and calculate in
accordance with Eurocode.
- Updates in Annex N regarding Documentation of supports.
- Updates in Annex Y where all changes from EN 13480-3:2017/A5:2022 to EN 13480-
3:2024 are shown.
The standard is crucial for engineers and professionals involved in the design, construction,
inspection, and maintenance of industrial piping systems. In our comparison we primarily
focus on Chapter 13 βPipe supportsβ and applicable Annexes.
Difference of EN 13480-3 vs EN 1993-1-1
We as Hilti, do support on European Standards referring to primary pipe supports two
norms, EN 1993-1-1 which is also known as EC 3 as well as EN 13480-3.
The decision about which standard shall be used, lays with engineering companies and
owners for new or existing facilities. With the latest update of EN 13480-3:2024 design and
calculation based on EC 3 are also now accepted but only under specific boundaries. EN
13480-3 added a note at the end of chapter 13.11.11 where βAlternative rules for design and
manufacture of pipe supportsβ are included stating that Annex J which covers βType testing
of support componentsβ is not applicable for supports designed with the alternative route
according to Eurocode. You can find this nicely confirmed in the below added statement
from CEN under question 3-007-2021.1
To be fully transparent in this regard, we do offer technical data for both codes separately
from each other while all data is based on test results identified in Laboratories. The
identified failure modes out of test results are then taken as a foundation to use them according to standard specific regulations including established and defined safety factors.
All these details are included in our locally published tech guides.
Detailed information about products and the entire portfolio can be found in here.
Equal to our support system and base fastener portfolio, we publish in our tech guide loads
for single directional use only. Whenever three-dimensional loads are to be considered, a
specific interaction formula needs to be included.
Graph 1: Scheme of Axes in use for primary pipe fasteners
Under EC 3 we use here a normal linear interaction formula.
Under EN 13480-3 which is a more conservative standard compared to EC 3, we use
Interaction formula based on βvon Misesβ yield criterion2
Another element which needs to be considered are temperature reduction factors in
correlation with media temperature inside the pipe.
EC 3 does not require a reduction factor up to 300Β°C while EN 13480-3:2024 provides
material properties for carbon steel according to EN 10025 series (S235, S275 and S355) in
the range from 0Β°C up to 350Β°C directly in Appendix G.4. In here a graph is included which
shows temperature reduction factors from 100Β°C media temperature onwards.
In addition to that Table 13.11.2-1 shows βDesign temperature of components within the
insulationβ. In general, all support components shall be designed with at least 80Β°C design
temperature. For βcomponents without direct contact with the pipeβ the design temperature
can be reduced by 20Β°C if the final value is still above 80Β°C overall.
This means for our offering that Hilti pipe shoes where manufactured pipe clamps bows are
based on S235 steel can be used according to graph in Appendix G.4. Whenever our
complementary offered inlay bands are used between the pipe and pipe clamps bows, the mentioned reduction of 20Β°C out of Table 13.11.2-1 can be considered prior to the
identification of the final used temperature reduction factor. So, in such combination no
reduction factor is being needed until 120Β°C media design temperature at all with our
offering in alignment with EN 13480-3.
Further transfer of media temperature towards components in the entire support structures
must be assessed based on being inside or outside of insulation to ensure that all used
components can withstand the specific temperatures at their locations. (Table 13.11.2.2 and
Figure 13.11.2.1)
Overall EN 13480-3, even in the latest version in most real-life cases, tends to be more
conservative than EC 3. On the other side there are also options to exceed published loads
whenever stress levels in the pipe described do include so called βoccasional loadsβ as
defined in chapter 13.1.3.16. This means that a support designer, not the pipe support
manufacturer like Hilti, can assess if any loads at the specific facility and isometric can be
assessed like being treated as occasional. As an example, this could be a higher short
notice temperature during maintenance or wind / snow loads depending on specific
circumstances on site.
As it is quite comprehensive to cover all these needs and challenges in one calculation, Hilti
started to cover this in our established FixPoint Calculator software.
Hilti FixPoint Calculator covers EN 13480-3
Hilti FixPoint Calculator is a specialized software tool designed for engineers and
professionals working with piping systems. It adheres to the EN 13480-3 standard, which is
crucial for the design and calculation of metallic industrial piping. Hilti FixPoint Calculator
simplifies these complex calculations, providing detailed reports and intermediate results that
help engineers validate their designs and ensure compliance with the stringent requirements
of EN 13480-3. This makes it an invaluable tool to help ensure safety and efficiency in piping
projects.
The EN 13480-3 standard can be found in the direct load input application.
Graph 2: Starting page in FixPoint Calculator Software
In this application you can enter support loads in all three directions. No additional reduction
factor is applied.
The maximum working temperature and temperature reduction factor according EN 13480-3
are applied to the entire pipe shoes and their connection elements uniformly.
Graph 3: Specific input fields in alignment with EN 13480-3
The following interaction formula is used in FixPoint Calculator for all pipe-shoes MP-PS 1-1
single pipe shoes and MP-PS 4-2 two leg double pipe shoes and the clamps:
With π» = π β 1/ππThe following interaction formula is used in FixPoint Calculator for all pipe-shoes MP-PS 1-1
single pipe shoes and MP-PS 4-2 two leg double pipe shoes and the clamps:
Documentation under EN 13480-3
Proper documentation is key in process piping industries. Now the standard includes two
tables in Annex N, under Table N.1 for pipe supports fabricated according to EN 13480-
3:2014 and Table N.2 pipe supports according to EN 1090-2:2018 +A1:2024
In both tables three support classes from S1-S3 are included to clarify in depth which
documents must be supplied or made available for review if required.
Conclusion and Recommendations
Hilti is happy to support you during your piping projects which specific details and technical
support upfront as well as physical support on site to ensure smooth project progress.
For more information, please contact your local HILTI experts and check out other article on
this topic.