AP09_1.vp


1 Introduction
The behaviour of a steel structure under a fire situation

differs from its behaviour under ambient temperature. The
mechanical properties and the thermal expansion change
with increasing temperature. Especially the yield stress and
the modulus of elasticity have a significant influence on the
bearing capacity of steel members. This is significant espe-
cially for thin-walled elements. A corrugated sheet is able to
transfer the bending moments in the early phase of the fire.
The thermal expansion of steel extends the sheet and results
in increased deflection. At this stage, the bolted connection is
loaded by forces induced by thermal expansion. At higher
temperatures, the bending moment resistance is reduced and
a major part of the load is transferred by the tension mem-
brane. At this moment, the resistance and stiffness of the
bolted connection has a significant influence on the sheet
behaviour. The connections transfer the membrane force to
the supports. The performance of the connection is also
important in the cooling phase of the fire.

The resistance of the connection is expressively influenced
by the change in the mechanical properties of the corrugated
sheet. The increase in the temperature leads to a decrease in
the yield stress and the modulus of elasticity of thin-walled
cold formed steel members. The decrease in these mechani-
cal properties leads to a reduction in the load bearing capacity
of the structure. However, the ultimate strength is slightly in-
creased for higher temperatures. The maximum strength is
reached at 250 °C, and the original value is obtained at about
350 °C. An additional increase in temperature leads to a de-
crease in bearing capacity. For temperatures higher than
400 °C, the yield stress on the force-deformation diagram is
not visible. Buckling of thin walled elements is influenced by
the reduced modulus of elasticity value.

2 Description of experiment and
tested specimens

2.1 Experiments with screwed connections
Two sets of tests with screwed connections under ambient

and elevated temperatures were carried out in the laboratory

of the Faculty of Civil Engineering of the Czech Technical
University in Prague. In these experiments, the mechanical
properties of screwed connections at steady state conditions
were determined. Steady state tests (SST) are faster and sim-
pler than transient state tests. SSTs can be used for predicting
behaviour in fire situations, when the temperature changes in
time [1]. The experiments focused on the stiffness, resistance,
deformation capacity and collapse mode of the connections
during fire.

Four sets of experiments have been performed. In 2005,
two sets of tests were carried out [2]. In set A, E-VS BOHR
5-5.5×38 screws and a sealed washer �19 mm were used. In
set B, the same screws were used, but the sealed washer was
replaced by a steel washer 29 mm in diameter. The thickness
of the trapezoidal sheet for sets A and B was 0.75 mm. The
next two sets of experiments were carried out in 2007 [3]. The
screwed connections in the test were made with the use of
self-drilling carbon steel screws marked SD8-H15-5.5×25 (set
C and set D). The test specimens were cut out from a trape-
zoidal sheet with nominal thickness 0.75 mm. In test set C,
trapezoidal sheets with measured thickness 0.75 mm, width
75 mm and length 500 mm were tested. The specimens
for test set D were from measured sheet 0.80 mm in thick-
ness, 50 mm in width and 350 mm in length. The values
of the material properties of the trapezoidal sheet were ob-
tained by material experiments. For measured sheet thickness
0.75 mm, the yield stress was 338 MPa, and the ultimate
strength was 428 MPa. For measured sheet thickness
0.80 mm, these values were 327 MPa for the yield stress and
426 MPa for the ultimate strength.

In each set of tests, experiments were performed with two
specimens for ambient temperature 20 °C and for constant
elevated temperatures 200 °C, 400 °C, 500 °C, 600 °C and
700 °C. Steel sheets 10 mm in thickness simulated the bearing
roof structure and they were anchored into the grips of the
testing machine, see Fig. 1. Due to these thicker sheets, the
force from testing machine to the specimens was transferred.
The tested screwed joints were placed in the middle in the
electric furnace. The specimens tested in 2006 were heated
in an electric furnace with internal diameter 150 mm and
height 300 mm. The temperatures of the connection were
measured by a thermocouple attached to the steel sheet close

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Acta Polytechnica Vol. 49  No. 1/2009

Connections of Trapezoidal Sheets under
Fire
P. Kallerová, F. Wald, Z. Sokol

This paper describes two different experiments on connections of trapezoidal sheets under elevated temperatures. The first experiments were
tensile tests carried out on four sets of tests with screwed connections under ambient and elevated temperatures. One diameter of self-drilling
screws and three different thicknesses of trapezoidal sheets were used. The applied screws were without washers, or with sealed or steel wash-
ers. The second experiment was performed in a laboratory furnace to check the catenary action of a thin-walled trapezoidal sheet. The basic
theory tested in this experiment was that in the first phase of the fire the sheet behaves as a simply supported beam, while in the second phase
the load bearing is transferred by a tension membrane. These experiments will be used to develop a design model of connections at high tem-
peratures. High fire resistance of the trapezoidal sheet, dependent on suitable design of the screwed connection to the bearing structure, was
confirmed. The experiment with the simple beam also confirmed catenary action.

Keywords: Screwed connection, self-drilling screw, trapezoidal sheet, elevated temperature, catenary action.



to the bolt. The experiments from 2007 were carried out in a
smaller furnace with one opening and internal dimensions
50×130×125 mm, see Fig. 2. The thermocouple for measur-
ing the temperature of the connection was located in a hole
drilled in the screw head. The air temperatures in the fur-
naces and the temperatures of the tested connections were
measured by one thermocouple.

The electric furnace had one opening, which was filled
with glass with high temperature protection. During the fire
tests, the behaviour and the deformation of the tested con-
nections could be observed. In the course of the experiments,
photo documentation was provided at 5-second intervals.
Fig. 3 shows four photographs taken during one of the tests.
The edges of the specimens were marked at 5 mm spacings
for displacement measurement. The constant rate of move-
ment was established.

2.2 Experiment with a trapezoidal sheet and its
catenary action

In 2007, the PAVUS laboratory in Veselí nad Lužnicí
provided a fire experiment for checking the catenary effect of
a thin-walled trapezoidal sheet. The specimen for the fire
experiment was taken from a trapezoidal sheet with sheet
thickness 0.75 mm, and the waves were 55 mm in height.

This sheet was placed above a furnace with diesel burners.
The specimen was fastened by self-drilling SD8-H15–5.5×25
screws to the bearing steel frame, which was made from
HEB200 profiles. The inner dimension of this frame was
800×3000 mm. In each lower wave of trapezoidal sheet two

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Acta Polytechnica Vol. 49  No. 1/2009

Steel plate = 10 mmt

The tested connection in the furnace

Screw SD8 - H15 - 5.5 × 25

Test specimen = 0.75 mmt

fixed to testing machine

Bolted connection, standard bolt M12

Steel plate = 10 mmt

fixed to testing machine

Fig. 1: The test set up Fig. 2: Electric furnace for the tests in 2007

1 min 10 s 2 min 15 s 4 min 15 s 4 min 45 s

Fig. 3: The deformation of the connection

Fig. 4: The tested specimen before the fire experiment



self-drilling screws were used. Thermal insulation protected
the frame against the effect of high temperatures.

Four rectangular iron plates 30 mm in thickness, with di-
mensions 450×580 mm and weight 60 kg each were used as
the mechanical load. The total load on the tested specimen
was 240 kg, which corresponds to 1 kN/m2. The iron plates
were uniformly distributed on the trapezoidal sheet. The dis-
tance between the load and the edge of the specimen was 300
mm, and the distance from each other was 200 mm. Fig. 4
shows a view of the tested specimen before the fire experi-
ment. The trapezoidal sheet, the mechanical load, the bear-
ing frame and the thermal insulation of the whole specimen
can be seen.

The thermocouples and a vertical deflectometer in the
middle of the span of the simple beam were located directly
on the sheet. The thermocouples were placed in the midspan
and at the quarter distance of the span of the trapezoidal
sheet, three on the screws and three near the screws on the
sheet. Two thermocouples were used for measuring the gas
temperature in the furnace; they were placed at a distance of
350 mm from the upper surface of the upper wave of the
sheet.

3 Results of experiments

3.1 Experiments with screwed connections
The resistance of the connection with a sealed washer (set

A) was limited by the bearing resistance of the thin sheet. The
sealant washer has no influence on the behaviour, because the
sealant burns at higher temperatures. The stiffness of the con-
nection with steel washers (set B) was much higher and the re-
sistance was almost twice as high as for the previous set. The
thin sheet was deformed and accumulated in front of the
washer. This was accompanied by the formation of two shear
zones on both sides of the washer, see Fig. 6. This failure mode
is characterized by deformation capacity larger than 30 mm.
However, at temperatures higher than 500 °C shear failure of
the bolt was observed, see Fig. 7.

Fig. 8 is a force-deformation diagram of the connections
from set D, and the collapse mode for the connection from set
C is shown in Fig. 9. For all specimens with a measured sheet
thickness of 0.75 mm, failure in bearing was reached when the
trapezoidal sheet tore. Two modes of failure were observed
for sheet thickness 0.80 mm. For temperatures from 20 °C to
600 °C the sheet failed in bearing, whereas for a temperature
of 700 °C the mode of failure was shear failure of the screw.

In the initial phase of loading, elastic behaviour can be ob-
served. Then the force increased until the maximum bearing
capacity was achieved and the tearing of the sheet occurred.
In the next phase of the force-deformation diagram, a de-

84 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 49  No. 1/2009

N

N
H

N

N
H

q

�

�

l

Fig. 5: The catenary action on a simply supported beam

Fig. 6: The collapse mode of the connection from set B, tempera-
ture 200 °C

Force [kN]

Deformation [mm]

2.0

4.0

0

3.0

1.0

5.0

105 15 20 25 300 35

7.0

6.0

8.0

20 °C

200 °C

400 °C

500 °C 600 °C
700 °C

Fig. 7: Force-displacement diagrams of the screwed connections
from set B

300 °C

400 °C

500 °C

600 °C

700 °C

200 °C

Force [kN]

2.0

4.0

0

3.0

1.0

5.0

105 15 20 25 300 35

6.0 20 °C

Deformation [mm]

Fig. 8: Force-displacement diagrams of the screwed connection
from set D

Fig. 9: Collapse mode of the connection from set C, temperature
200 °C



crease in force can be observed. The increase and subsequent
decrease in force due to the accumulation of deformed sheet
in front of the screw can be seen in the diagram. The defor-
mation capacities of the connections were high. Due to the
dimension limits of the electrical furnace, all the experiments
were terminated before their ultimate failure, but after ex-
haustion of the residual bearing capacity.

The results of these experiments show how the tempera-
ture increase leads to a decrease in the bearing capacity of
the connections. For a temperature of 550 °C, the bearing
capacity of the connection is reduced to approximately one
half of the bearing capacity under ambient temperature, and
for a temperature of 700 °C the bearing capacity is less than
20 % of the bearing capacity under ambient temperature. A
reduction of 45 % for temperature 500 °C and of 90 % for
700 °C is used for calculations of connections with bolts and
nuts. The experiments confirm a greater reduction in the
resistance of the self-drilling screws in bearing in the initial
phase of heating (up to temperature 550 °C), and a smaller
reduction for higher temperatures. These two factors lead to
unfavourable brittle failure of the connection in shear [4].

Temperatures lower than 500 °C have no significant influence
on the initial stiffness of the connection. The deformation
capacity for higher temperatures is reduced by failure of the
screw in shear. This mode of failure occurred only for the
screwed connection with sheet thickness 0.80 mm and tem-
perature 700 °C.

3.2 Experiment on the trapezoidal sheet and its
catenary action

The fire load was modelled by a multilinear fire curve sim-
ulating the fire load used for the fire tests in Cardington. The
usage of similar fire curves is helpful for subsequent com-
parison of the results from different fire experiments. The
maximum measured gas temperature in the furnace was
1096 °C. This value was reached in the 55th minute, and the
total length of the fire experiment was 2 hours. The tempera-
ture of the trapezoidal sheet above the support was 447 °C,
and this temperature is about 58% lower than the tempera-
ture of the trapezoidal sheet in the midspan (1084 °C), see
Fig. 10. In the case of an unprotected load-bearing structure
the temperature would be higher.

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Acta Polytechnica Vol. 49  No. 1/2009

Time [min]

Temperature [°C]

0 15 30 45 60 75 90 105 120

100

200

300

400

500

600

700

800

900

1000

1100

Gas temperature

Temperature of sheet

in midspan

Temperature of sheet

near screw

Temperature of screw

Fig. 10: Measured temperature on the specimen

�220

�200

�180

�160

�140

�120

�100

�80

�60

�40

�20

0

20

10 20 30 40 50 60 70 80 90 100 110 120

Time [min]

Deflection [mm]

Calculation

Experiment

Fig. 11: Vertical deformations in the midspan of the trapezoidal sheet



The behaviour of the trapezoidal sheet during the fire ex-
periment was similar to the behaviour of a simple beam on
which the elongation is restrained. At the beginning of the fire
test, the temperatures are low and the trapezoidal sheet is not
deflected by the influence of the temperature. The sheet elon-
gates in its plane, and the screws in the supports are loaded in
shear. As the temperature increases, an extension occurs as a
result of the thermal expansion of the material, and the yield
stress and the modulus of elasticity decrease. As a result of
these effects, the deflection is increased. The increase in the
deflection and the decrease in bending stiffness lead to a
change in the tensile forces in the supports, and the sheet
starts to behave like a tensile membrane. This effect is known
as catenary action. Fig. 5 shows a scheme of the catenary
action on a simply supported beam.

The collapse of the structure depends on the bearing
capacity of the connections and on the ability of the load
bearing structure to carry the tensile forces. Fig. 11 compares
the deflection as a function of time for values calculated by
equations and for values obtained during the experiment.
The comparison of the maximum deflections and the times
where the deflection are obtained are in a good agreement.
The maximum measured deflection of the trapezoidal sheet
was 229 mm, and the calculated vertical deformation was
222 mm.

4 Summary
The resistance of the connection in relation to tempera-

ture is shown in Fig. 12. Resistance is reduced at higher
temperatures; the reduction is small at temperatures up to
400 °C but significant at temperatures higher than 500 °C.
The diameter of the washer or of the screw head has a signifi-
cant influence on the resistance. The resistance of the screwed
connection from set A is approximately 40 % lower than the
resistance of the screwed connection from set D. When the
connection from set B is used, the resistance is similar to the
connection from set C. Shear failure of the screw may lead to
low deformation capacity at temperatures higher than 500 °C.
These experiments will be used for developing a design
model of connections at high temperatures.

The experiment with a trapezoidal sheet supported like a
simple beam confirmed the catenary action. High fire resis-
tance of the trapezoidal sheet, depending on suitable design
of the screwed connection to the bearing structure, was also
confirmed.

Acknowledgment
This outcome has been achieved with financial support

from the Ministry of Education, Youth and Sports, under pro-
ject no. 1M0579.

References
[1] Outinen, J.: Mechanical Properties of Structural Steels at

High Temperatures and after Cooling Down. Espoo, 2007.
[2] Sokol, Z.: Design of Corrugated Sheets Exposed to Fire,

Progress in Steel, Composite and Aluminium Structures, 2006.
[3] Kallerová, P.: Experiments with Bolted Connections – Ex-

periments at Normal and Elevated Temperatures. Research
report CTU in Prague, 2007.

[4] Wald, F. et al.: Calculation of the Fire Resistance of Struc-
tures. CTU in Prague, 2005.

Petra Kallerová
e-mail: petra.kallerova@fsv.cvut.cz

František Wald

Zdeněk Sokol

Department of Steel and Timber Structures

Czech Technical University in Prague
Faculty of Civil Engineering
Thákurova 7
166 29 Prague 6, Czech Republic

86 ©  Czech Technical University Publishing House http://ctn.cvut.cz/ap/

Acta Polytechnica Vol. 49  No. 1/2009

Resistance [kN]

Temperature [°C]

2.0

4.0

0

3.0

1.0

5.0

200100 300 400 500 6000 700

7.0

6.0

8.0
The set tests C

The set tests A

The set tests B

The set tests D

Fig. 12: Resistance of the connections


	Table of Contents
	Influence of Brick Walls on the Temperature Distribution in Steel Columns in Fire 5
	António J. P. Moura Correia, Joao Paulo C. Rodrigues, Valdir Pignatta e Silvac

	Incorporation of Load Induced Thermal Strain in Finite Element Models 11
	A. Law, M. Gillie, P. Pankaj
	Thermal Conductivity of Gypsum at High TemperaturesA Combined Experimental and Numerical Approach 16
	I. Rahmanian, Y. Wang



	Structural Analysis of Steel Structures under Fire Loading 21
	C. Crosti

	Compressive behaviour at High Temperatures of Fibre Reinforced Concretes 29
	S. O. Santos, J. P. C. Rodrigues, R. Toledo, R. V. Velasco
	Experimental Analysis of Concrete Strength at High Temperatures and after Cooling 34
	E. Klingsch, A. Frangi, M. Fontana



	Fire Resistance of Axially Loaded Slender Concrete Filled Steel Tubular ColumnsDevelopment of a Three-Dimensional Numerical Model and Comparison with Eurocode 4 39
	A. Espinós, A. Hospitaler, M. L. Romero
	Calculation of a Tunnel Cross Section Subjected to Firewith a New Advanced Transient Concrete Model for Reinforced Structures 44
	U. Schneider, M. Schneider, J.-M. Franssen

	A New Design Method for Industrial Portal Frames in Fire 56
	Y. Song, Z. Huang, I. Burgess, R. Plank

	Decomposition of Intumescent Coatings: Comparison between a Numerical Method and Experimental Results 60
	L. M. R. Mesquita, P. A. G. Piloto, M. A. P. Vaz, T. M. G. Pinto

	Simulation and Study of Natural Fire in a Wide-Framed Multipurpose Hall with Steel Roof Trusses 66
	D. Pada



	Investigation into Methods for Predicting Connection Temperatures 71
	K. Anderson, M. Gillie
	Connection Temperatures during the Mokrsko Fire Test 76
	J. Chlouba, F. Wald

	Connections of Trapezoidal Sheets under Fire 82
	P. Kallerová, F. Wald, Z. Sokol