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«Strength of the compressed thin-walled studs: tests and FEM-modelling»
Saint-Petersburg, Hämeenlinna
2014
Saint-Petersburg State Polytechnical University
HAMK University of Applied Sciences
Report at
«International Scientific Conference and Workshop «METNET»
Contributors: Nikolay I. Vatin , Alexey S. Sinelnikov
Jarmo Havula, Lassi Martikainen
Abstract This summary report is based on the experimental and numerical research of thin-
walled cross-section’s compression resistance carried out in St. Petersburg State
Polytechnical University and HAMK University of Applied Sciences, Sheet Metal
Centre. Current situation on the Russian market concerning the usage of cold-formed
thin-walled cross-sections is aimed to find out a base foundation to start up a stipulation
of the elements under discussion in the building industry. Some questions about the
compression resistance of such cross-sections were raised on different conferences by
scientific community and by companies such as Rautaruukki Oyj (Finland). Steel
galvanized C- and U-profiles and thermo-profiles are types of thin-walled cross-sections
are normally used in small houses construction. Thermo-profiles have slots in webs that
decrease the thermal flow through the web, but have a negative effect on strength of
the profiles. These profiles were object of the research. Investigations carried out
included tests to prove the compression resistance of the single thin-walled studs and
stud-to-rack joints. Numerical modeling of thin-walled cross-sections was done with
contemporary analysis software (SCAD Office) using the finite element method
(FEM).
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Researches Studies undertaken by the authors in recent years have revealed that today‘s
building market in Russia is looking for building materials and technologies that could
provide low-height housing industry with high-speed of construction, safety, ecological
compatibility and finance efficiency.
The lightweight thin-walled cold-formed steel structures allow getting advantages
that meet the requirements described above. Due to some reasons we, in Russia, do
not have current norms that could be applied by engineers who design houses using
the cold-formed steel structures. In this area a number of Doctoral theses have been
defended during recent years in Russia (G.I. Belyy, A.R.Tusnin, I.V. Astahov, A.U.
Kuznetsov). Theoretical research and laboratory tests were done only for specific
types of thin-walled cross-sections.
Jyrki Kesti contributed a good deal to the development of local and distortional
buckling of perforated steel wall studs (Espoo, 2000). Today thin-walled cold-formed
steel structures won a good place in the Finnish building area. Experience that Finnish
engineers have could help Russian science community to understand more exactly
behavior of such a structures and appropriate European norms.
Summary of the research described below concerns reticular-stretched thermo-
profiles. Reticular-stretched thermo-profile is a new type of thin-walled cross-sections
that found its place in Russian market.
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General
As an object of research reticular-stretched thermo-profiles and their joints were
analyzed (see figure 1). The following profiles are discussed:
1. Specimen S1 (stud) - АИ ТCс 200-45-2,0;
2. Specimen S2 (rack) - АИ ПН 200-50-2,0.
Steel used for specimen production has the following parameters:
1. Steel grade - 350 (yield strength not less than 350 H/mm2);
2. Coating mass, 350g/m2;
3. Coating thickness, 25 microns.
Fig. 1 Reticular-stretched thermo-profiles 4 of 23
The research goal was to form
the theoretical rationale for usage of
reticular-stretched thermo-profile
throughout buckling analysis based
on the laboratory tests.
Research tasks
Research tasks:
1. Laboratory tests:
− Compression test: single studs and stud-to-rack joints.
2. Numerical modeling (FEM):
− Buckling analysis.
3. Comparison of results.
5 of 23 Fig. 2 Compression test. Single stud and Stud-to-rack joint
Experimental investigations
Compression test 1. Test specimen:
• C–shaped thermo-slotted profiles АИ ТCс 200-45-2.0;
• Web height - 200mm, flange width - 45mm, single edge fold stiffener – 15mm,
steel thickness - 2,0mm;
• Total lengths of the specimen 350 and 1000 mm;
• Support blocks (thickness 40 mm; edge is positioned 3 mm from the end of the
profile) made of wood are placed inside the profile at the ends;
• 7 specimen (4 single studs and 3 stud-to-rack joints).
2. Test arrangement:
• The lower end of the specimen is placed on a hinged support made of steel or
on a floor;
• The load of a hydraulic cylinder is applied to the special hinged element through
a thick steel plate to the upper end of the specimen;
• Point of load application is 10mm from the outside surface of the web.
3. Test procedure:
• The specimen is loaded using the displacement control until the failure of the
specimen;
• The loading rate is different (1.0; 1.33; 2.0; 3.0; 4.0 mm/min).
4. Test results:
• Buckling form and force. 6 of 23
Experimental investigations
Test results. Photos
7 of 23
Fig.3 Compression test
Experimental investigations
Test results. Photos
8 of 23
Fig.4 Compression test
Experimental investigations
Test results. Photos
9 of 14 Fig.5 Stud-to-rack joint. Specimen C1…C3
Experimental investigations
Test results. Compression test diagram (S3)
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Fig. 6 Compression test diagram (S3)
Experimental investigations
Test results. Compression test diagram (S1,S2,S4)
11 of 23
Fig. 7 Compression test diagrams (S1,S2,S4)
Experimental investigations
Test results. Compression test diagram (C1,C2,C3)
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Fig. 8 Compression test diagrams (C1,C2,C3)
Experimental investigations
Test results
Table 1. Test results
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Type of profile/ Specimen number Compression test
Buckling force, kN
АИ ТCс 200-45-2,0 (S1) 84.35
АИ ТCс 200-45-2,0 (S2) 68.89
АИ ТCс 200-45-2,0 (S3) 53.82
АИ ТCс 200-45-2,0 (S4) 83.36
АИ ТCс 200-45-2,0 (C1) 90.82
АИ ТCс 200-45-2,0 (C2) 92.99
АИ ТCс 200-45-2,0 (C3) 99.88
Reticular-stretched VS. Usual web-slotted profile
14 of 23 Fig. 9 Reticular-stretched and usual web-slotted profiles
Reticular-stretched VS. Usual web-slotted profile
Test results
Table 2. Test results (mean values)
15 of 23
Type of profile Compression test Difference
Buckling force, kN %
АИ ТCс 200-45-2,0 78.19 96
АИ ТC 200-45-2,0 39.98
Numerical modeling (FEM)
Numerical modeling of thin-walled cross-sections and their stud-to-rack joint was
done with contemporary analysis software (SCAD Office) using finite element method
(FEM). FEM-models’ parameters were the same as for the tests described above.
During the modeling process the thin-walled profile based on shell-elements (see figure
10).
Fig. 10 FEM-model of reticular-stretched profile (shell-elements)
16 of 23
Characteristic of shell-element models:
• Finite element dimensions – 3 mm;
• Absolute solid body;
• Hinged and combined boundary
conditions.
Comparison test and FEM-modeling results
Table 3. Test and FEM analysis results
17 of 23
Type of profile Compression test Buckling analysis
350mm 1000mm Shell Difference
Buckling force, kN %
АИ ТCс 200-45-2,0 - 53.82 53.5 0.6
АИ ТCс 200-45-2,0 93.7 - 85.9 8.3
Numerical analysis (FEM)
Numerical modeling of reticular-stretched profile studs with length 1000, 2000 and
3000mm were done.
Fig. 11 FEM-model of reticular-stretched profile (shell-elements)
18 of 23
Characteristic of shell-element models:
• Finite element dimensions – 3 mm;
• Absolute solid body;
• Hinged boundary conditions.
Types of the cross-sections (see figure 11):
• АИ ТCс 150-45-1.5 (2.0);
• АИ ТCс 175-45-1.5 (2.0);
• АИ ТCс 200-45-1.5 (2.0);
• АИ ТCс 250-45-1.5 (2.0).
Accidental eccentricity (SNiP II-23-81*):
Numerical analysis (FEM).Results Table 4. FEM analysis results: critical load and buckling form
19 of 23
Critical load, kN Buckling form Critical load, kN Buckling form
1 1000 4,28 61 44,6 Local 37,7 Local
2 2000 5,61 122 42,9 Local 36,2 Local
3 3000 6,95 183 30,2 Overall 26,6 Overall
4 1000 4,27 62 83,9 Local 71,3 Local
5 2000 5,60 124 78,4 Overall 69,0 Local
6 3000 6,94 185 41,6 Overall 36,9 Overall
7 1000 4,71 62 36,6 Local 31,4 Local
8 2000 6,05 125 34,2 Local 29,1 Local
9 3000 7,38 187 29,0 Overall 25,1 Overall
10 1000 4,70 63 69,6 Local 60,2 Local
11 2000 6,04 126 65,8 Local 56,0 Local
12 3000 7,37 190 40,8 Overall 35,6 Overall
13 1000 5,14 64 29,2 Local 24,8 Local
14 2000 6,47 128 27,2 Local 22,8 Local
15 3000 7,80 192 26,2 Local 21,2 Local
16 1000 5,13 65 55,8 Local 47,7 Local
17 2000 6,46 130 53,1 Local 44,3 Local
18 3000 7,79 194 39,7 Overall 34,1 Overall
19 1000 5,96 67 19,8 Local 16,4 Local
20 2000 7,29 134 18,3 Local 14,7 Local
21 3000 8,62 201 17,9 Local 13,9 Local
22 1000 5,95 68 38,2 Local 31,8 Local
23 2000 7,28 136 36,9 Local 29,8 Local
24 3000 8,61 204 35,9 Overall 28,1 Local
Axial compression Eccentrical compression
ТСс 150-45-1.5 16,41
ТСс 150-45-2.0 16,19
Radius of
gyrationLength, m
Eccentricity
, mmSlenderness
ТСс 250-45-2.0 14,69
ТСс 175-45-1.5 16,04
ТСс 175-45-2.0 15,82
ТСс 200-45-1.5 15,65
Type of profile№
ТСс 200-45-2.0 15,44
ТСс 250-45-1.5 14,90
Conclusions 1. New type of thin-walled thermo-profile (reticular-stretched) were analyzed.
2. Laboratory tests of the reticular-stretched profile under compression showed that
local buckling appears before overall buckling for the profiles with small slenderness
(λmax = 60…70). It was experimentally proved flexural and torsion-flexural buckling
forms.
3. Comparative analysis of experimental data for reticular-stretched profile and usual
web-slotted profile showed that bearing capacity of the first one is more than the last
one by about 95%. Middle positioned stiffener with grooved form is good design
solution.
4. Numerical analysis (FEM) of the reticular-stretched profiles with parameters that
are the same as for the tested specimens showed good results with normalized
difference not more than 8%.
5. Numerical analysis (FEM) of the reticular-stretched profiles with different web
height (150, 175, 200 and 250mm) and steel thickness (1.5 and 2.0mm) showed that
dominant type of buckling form depends on slenderness of the cross-section.
6. Summary of the investigations should be taken as a step to apply finite element
method for modeling profile behavior without real tests.
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Acknowledgements
The experimental work was commented by Arto Ranta-Eskola, director of research,
Rautaruukki Oyj (Finland).
The authors also gratefully acknowledge the helpful comments and suggestions of
the reviewers, which have improved the presentation.
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