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M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21                                                        
 

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Experimental analysis of the state of stress in a steel – titanium 
perforated plate loaded with concentrated force     
 
 
Mateusz Marcin Konieczny, Henryk Achtelik, Grzegorz Gasiak  
Opole University of Technology, Poland 
mateuszmarcinkonieczny@wp.pl, kmpkm@po.edu.pl, g.gasiak@po.edu.pl 
 
 
ABSTRACT. The paper presents an experimental analysis of the state of stress, 
free supported on the edge of a steel – titanium circular perforated plate 
loaded with a centrally concentrated force, created in the technological 
process of explosion welding. For this purpose, a special test stand was 
designed and a methodology for testing the perforated plate was developed. 
Resistance strain gauges were used to measure the state of strain. The load 
was applied in the center of the plate to a pressure stamp. As a result of the 
research, the values of radial, circumferential and equivalent von Mises stress 
were obtained as a function of the radius of the plate perforation circle and its 
load. The stress distribution topography revealed the zones of maximum 
stress of the steel – titanium perforated plate. The proposed method of 
experimental research can be used by engineers to verify the state of stress, 
e.g. in the designed tube sheet walls of reactors for ammonia synthesis. 
 
KEYWORDS. Perforated plate; Concentrated force; Stress analysis; 
Experimental research.  
 

 

 
 

Citation: Konieczny, M. M.,   N., Achtelik, H., 
Gasiak, G., Experimental analysis of the state 
of stress in a steel – titanium perforated plate 
loaded with concentrated force, Frattura ed 
Integrità Strutturale, 55 (2021) 277-288. 
 
Received: 12.12.2020  
Accepted: 23.12.2020  
Published: 01.01.2021  
 
Copyright: © 2021 This is an open access 
article under the terms of the CC-BY 4.0, 
which permits unrestricted use, distribution, 
and reproduction in any medium, provided the 
original author and source are credited. 

 

 
 
INTRODUCTION  
 

n the work of a designer, a frequent problem is the proper determination of the level of stresses and strains. 
Experimental tests are used to assess the correctness of the design of a given structure element in terms of its strength. 
The assessment is based on the material effort determined by the states of stress and strain. Research on these states 

can be carried out on real objects, as well as on their models made of various materials. On the basis of these tests, 
information is obtained that allows for a possible improvement of a structural element and for checking its behavior under 
operational loads [1]. 
In the literature, there are many works related to the analysis of the state of stress and strain in perforated plates [2, 3, 4, 5, 
6, 7, 8]. An experimental verification of the mathematical model obtained in [9] is presented in [10], where the methodology 
of experimental tests was developed, which would allow to determine the value of stresses in perforated plates loaded 
centrally by concentrated force. The diameters of the holes, as well as the topography of their arrangement in the plate 
prepared for the tests, ensured the stability of the section weakening coefficients. Resistance strain gauges were placed 
between the holes to measure the strain. The axially symmetrical perforated plate has been bent with a concentrated force 
applied centrally. Additionally, plate bending was monitored with a dial gauge during deformation measurements. Based on 
the measured deformation values, the values of radial, circumferential and equivalent von Mises stresses in the plate were 

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                                                      M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21 
 

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obtained. An experimental approach to the analysis of perforated plates was also proposed by the authors of [11], where 
they analyzed the state of stress and deflection of a circumferentially freely supported, circular-symmetric perforated plate, 
loaded with static pressure. For this purpose, a special test stand was designed and a methodology for testing the perforated 
plate was developed. The load on the perforated plate was carried out by means of a special elastic cushion, similar to that 
of Duncan [12]. Tensometric rosettes were used to measure the plate state of deformation. The load on the plate was 
determined by the deflection of its center. As a result of the research, the values of stresses were obtained as a function of 
the radius of the plate perforation circle and its load. In addition, the experimental approach related to the analysis of the 
state of deformation and stress in single-layer square perforated plates made of steel with specific geometric parameters was 
the subject of works [13, 14, 15]. 
Currently, more and more often in engineering structures are used elements consisting of many layers and of many materials, 
i.e. plated elements [16, 17]. Such structural elements may include layers made of structural steel, titanium, brass, aluminum, 
nickel, but also of non-metallic materials such as polyethylene, kevlar, glass fibers and carbon fibers. Elements of this type 
are most often used due to the improvement of thermal properties, chemical properties (e.g. corrosion resistance) as well 
as the mechanical parameters of the structure in which such elements are present. In the works [16, 17] an analytical solution 
was presented with the use of mathematical formulas enabling engineers to estimate the effort of the designed cladded 
perforated plates subjected to various types of load. It was found that both the finite element method and the analytical 
method make it possible to determine the stress values in plated perforated plates in the transition layers, i.e. in the transition 
layer on the titanium side and in the transition layer on the steel side. Experimental methods based on strain gauges do not 
offer such possibilities. 
The presented work proposes an experimental approach to determining the stress values in a steel – titanium circular 
perforated plate, freely supported on the edge and loaded centrally with a concentrated force Pi perpendicular to the plate 
surface. The research carried out at work was based on the use of resistance strain gauges. The results of the research 
presented in the paper can be used by engineers to design bimetallic perforated plates loaded perpendicular to their surface. 
 

 
Figure 1: Model of bimetallic perforated plate consisting of steel thickness perforated plate H and titanium perforated plate thickness a 
containing holes with diameters d1,…,d5. 
 



 

M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21                                                        
 

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SUBJECT OF THE RESEARCH    
 

he experimental research was based on a bimetallic circular axisymmetric perforated plate with dimensions: diameter 
D = 300 mm and comprising two layers, i.e. the base layer B in the form of structural steel with a thickness of H = 
10 mm and the applied layer (plating) in the form of titanium with the thickness of a = 2.5 mm. 100 holes with 

different radii located on the plate. These holes were arranged in five circles with 20 holes in each circle. On the first outer 
circle, the plate had holes d1 = 20.5 mm in diameter and on the fifth, inner circle holes d5 = 9.5 mm in diameter. The scheme 
of the plate is shown in Fig. 1, and the plate in fact in Fig. 2. The perforated plate adopted for experimental research was 
made of a metallic composite called a platter, obtained during the so-called explosive plating. Explosive plating, also known 
as bonding or welding, consists in joining two or more metal elements with the use of energy released during the detonation 
of an explosive (Fig. 2) [18]. This technology is mainly used for materials that are difficult to join or cannot be joined by 
other methods. In this case, it was a steel sheet with a titanium layer applied to it. The plate prepared in this way was 
subjected to a rolling process to obtain a circular plate. Then, holes were drilled in the plate, positioned as shown in Fig. 1. 
The base material of the plate was steel sheet of the S355J2 grade, and the applied material was titanium sheet with the 
following mechanical and material parameters (Tab. 1) [19]. 
 
 

 
Figure 2: Model of bimetallic perforated plate. 

 
 
 

S355J2 steel and titanium 

Applied layer A - titanium

Re [MPa] Rm [MPa] E [GPa] v  [-] G [GPa] A5 [%] 

189-215 308-324 100 0.37 36.5 43-56  

C Fe H N O Ti  

0.10 0.20 0.015 0.03 0.18 99.5  

Base layer B - S355J2 steel

Re [MPa] Rm [MPa] E [GPa] v  [-] G [GPa] A5 [%]  

382-395 598-605 220 0,30 84,6 24-34  

C Si Mn P S Cu Fe 

0.22 0.55 1.60 0.025 0.025 0.45 all

 

Table 1: Strength properties and chemical composition of S355J2 steel and titanium, where: Re – yield strength [MPa], Rm – tensile 
strength [MPa], E – Young’s modulus [GPa], v  – Poisson’ s ratio [-], A5 – tensile elongation [%]. 

T 



 

                                                      M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21 
 

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RESEARCH METHOD     
 

he aim of the experimental tests was to determine the state of stress in a steel – titanium circular perforated plate. 
This plate was loaded with a concentrated force Pi applied in its geometric center perpendicular to its surface, and 
the boundary conditions were assumed in the form of free support of the plate on its edge. On a previously prepared 

steel – titanium perforated plate, Tokyo Sokkia Kenkyujo Co Ltd, FLA-1-11 strain gauges with a measuring base of 1 mm 
and a strain gauge constant k = 2.14 (Fig. 3) were attached, on two plate layers, i.e. on base layer B - steel and on the applied 
layer A - titanium at 20 measuring points on the bridges between the holes in the circumferential direction, i.e. from AC1 
to AC5 and from BC1 to BC5, and in the radial direction, i.e. from AR1 to AR5 and from BR1 to BR5. This situation is 
illustrated in Figs. 4 and 5. Wooden pegs (Fig. 2), to which clamps are screwed, were placed in the appropriate holes of the 
experimental plate. In this way, the cables connecting the strain gauge with the measuring system of the Wheatstone bridge 
were immobilized and thus secured against breaking. As the plate is axially symmetrical with an axially-symmetrical 
distribution of holes (the hole spacing is 18 degrees), Fig. 5 show the actual arrangement of the strain gauges for a quarter 
of the plate. 
 

 
 

Figure 3: Strain gauges type: Tokyo Sokkia Kenkyujo Co Ltd, FLA-1-11. 
 
 

      
 

Figure 4: Arrangement of strain gauges on a bimetallic circular perforated plate: a) on the applied layer A – titanium; b) on the base layer 
B – steel (schematically). 
 

T 



 

M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21                                                        
 

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Figure 5: Arrangement of strain gauges on a bimetallic circular perforated plate: a) on the applied layer A – titanium; b) on the base layer 
B – steel (schematically). 
 

 
 

Figure 6: View of the testing machine prepared for testing in the case of plate loading with concentrated force P, where: 1 - computer, 
2 - universal testing machine, 3 - steel-titanium circular axially symmetrical perforated plate, 4 - annular support, 5 - strain gauge, 6 - 
sensor dial, 7 - pressure pin, 8 - distribution box, 9 - strain gauge bridge, 10 - dial gauge. 
 
 
RESEARCH POSITION     
 

 suitable test stand was prepared to measure the topography of deformations in a steel – titanium circular perforated 
plate. For this purpose, an appropriately designed annular support was made to ensure the boundary conditions of 
free support. The ZDM 10 universal testing machine from Werkstoff Preufmaschinnen Leipzig was used for the 

tests. The annular support was mounted on the machine in such a way that the axis of the loading pin passes through its 
axis of symmetry. The test plate with the strain gauges glued on was placed on the thus prepared support in such a way that 
the lower layer of the plate, i.e. the base layer B - steel, touched the support, while the upper layer, i.e. the layer A - titanium, 

A 



 

                                                      M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21 
 

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was in contact with the mandrel of the testing machine . The experimental plate was loaded in the form of a concentrated 
force. This type of load was realized directly by the mandrel of the testing machine, which corresponds to a case of 
concentrated force Pi applied at the geometric center of the plate normal to its surface. The test stand used for the experiment 
is shown in Fig. 6. The measurement of deformation in the plate was made with the use of a set consisting of a distribution 
box and a T2-type strain gauge bridge with a reading unit value of 0.005 ‰. However, the plate deflection was controlled 
with a dial gauge with an indication accuracy of 0.01 mm and a measuring range of 10 mm. The dial indicator was attached 
to the annular support in such a way that the axis of the stylus passes through the center of the experimental plate and lies 
in the axis of the loading pin of the testing machine. After the experimental plate was properly placed on a specialized 
support, the axiality of the sensor's measuring pin and the loading pin of the testing machine was checked. After resetting 
the measuring devices, the test stand was ready for the experiment. 

 

 

 
Figure 7:  Scheme of a steel – titanium circular perforated plate mounted on a ring support and loaded with a concentrated force Pi 
applied in the geometric center of the plate normally to its surface: a) from the layer of the applied plate A - titanium; b) from the side 
of the base layer of the B plate - steel, where: 1 – bimetallic circular perforated plate, 2 - the applied layer of the plate A - titanium, 3 - 
base layer of the plate B - steel, 4 - annular support, 5 - stand support, 6 - Pi load, 7 - dial gauge, 8 - pressure stamp. 
 
 
COURSE OF RESEARCH   
 

n the first case, a steel – titanium circular perforated plate was loaded with a concentrated force Pi applied in the 
geometric center of the plate perpendicularly to the surface of the applied A - titanium plate, and the boundary 
conditions were assumed in the form of free support of the plate on its edge. The diagram of fastening and loading of 

the perforated plate for the analyzed case is shown in Fig. 7a. In the second case, a steel – titanium circularsymmetrical 
I 



 

M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21                                                        
 

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perforated plate was loaded with a concentrated force Pi applied in the geometric center of the plate perpendicularly to the 
base surface of the B - steel plate, and the boundary conditions were assumed in the form of free support of the plate on 
its edge. The diagram of fastening and loading of the perforated plate for the analyzed case is shown in Fig. 7b. Then, the 
plate was initially subjected to a load P0 causing a deflection w0 in its center. After obtaining the initial load and deflection, 
readings of strain gauges on each of the radial circles in the radial and circumferential directions were read and recorded as 
the initial reading marked with the index "p". Then the plate was loaded with the force Pi, which caused the deflection. The 
readings of the strain gauges were read again and marked with the index "k" as the final reading. A similar measurement 
procedure was used for the successive forces P2, P3 and P4, which corresponded to the deflections w2, w3 and w4. The 
following values of the Pi load were adopted: P1 = 5 kN, P2 = 10 kN, P3 = 15 kN, P4 = 20 kN. The readings of strain gauges 
during measurements and the strains calculated on their basis in the circumferential direction εϴ and in the radial direction 
εr were used to determine the appropriate stresses.     

 
 
RESEARCH  RESULTS AND THEIR ANALYSIS   
 

t was assumed that a plane state of stress occurs in a steel – titanium circular perforated plate. For the elastic state of 
strains, the relationships between strains and stresses result from the generalized Hooke's law. If the principal directions 
1 and 2 are known, the relationship between the strains 1  and 2 , and the stresses 1 and  2 , takes the following 

form [20]: 
 

    


 
1 1 221
E

          (1) 

 

    


 


2 2 121

E
          (2) 

 
where:  
E – Young’s modulus [MPa]; 
v –  Poisson’s ratio [-]. 
In our case, the main directions of the axially symmetrical perforated plate are radial direction r and circumferential direction 
𝛳. Therefore, having determined the deformations in the radial direction r  and in the circumferential direction  , the 
main stress components in the radial direction  r  and in the circumferential direction   were determined from the 
following relationships: 
 

   
 

 21
r r

E
          (3) 

 

    
 

 21 r
E

          (4) 

 
After determining the radial stress values r and circumferential stresses values θ, these values were introduced into the 
formula for equivalent von Mises stress red , in the form: 
 

        
2 2

red r r           (5) 

 
Figs. 8 and 9 shown the values of stresses in the radial direction  r  and circumferential direction   and equivalent von 
Mises stress red  at the designated measurement points of the plate on the surface of the applied layer of the plate A - 
titanium (Fig. 4a and 5a) and on the surface of the base layer of the plate B - steel (Fig. 3b and 4b) with different loading 
forces, i.e. P1 = 5 kN, P2 = 10 kN,  P3 = 15 kN, P4 = 20 kN. In this case, the load was applied from the side of the titanium 
layer as shown in Fig. 7a. Figs. 10 and 11 shown the values of stresses in the radial direction  r  and circumferential direction 

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                                                      M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21 
 

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  and the equivalent von Mises stress red  at the designated measurement points of the plate on the surface of the applied 
layer of the plate A - titanium (Fig. 4a and 5a) and on the surface of the base layer of the plate B - steel (Fig. 4b and 5b) with 
different loading forces, i.e. P1 = 5 kN, P2 = 10 kN,  P3 = 15 kN, P4 = 20 kN. In this case, the load was applied from the 
side of the steel layer, as shown in Fig. 7b. 
 

 
Figure 8:  Summary of the stress values, respectively:  , r  red  determined on the surface of the applied layer of the plate A – 
titanium, in this case, the load was applied from the side of the titanium layer. 

 

 
Figure 9:  Summary of the stress values, respectively:  , r  red  determined on the surface of the base layer of the plate B - steel., 
in this case, the load was applied from the side of the steel layer. 



 

M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21                                                        
 

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Figure 10:  Summary of the stress values, respectively:  , r  red  determined on the surface of the applied layer of the plate A – 
titanium, in this case, the load was applied from the side of the titanium layer. 
 

 
Figure 11:  Summary of the stress values, respectively:  , r  red  determined on the surface of the base layer of the plate B – steel, 
in this case, the load was applied from the side of the steel layer. 

 
Fig. 12 shows the results of measurements of deflection w for a steel – titanium circular perforated plate, freely supported 
and loaded with a concentrated force Pi applied in the geometric center of the plate, determined experimentally in its 



 

                                                      M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21 
 

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geometric center, in the case where the load was applied from the side of the titanium layer – 1w  and if the load was applied 

from the steel layer  – 2w . 
 
 

 
Figure 12: Results of measurements of deflection in the center of the slab, at various loads with concentrated force Pi in the geometric 
center of the slab, normal to its surface, where: 1w  –  the load was applied from the side of the titanium layer, 2w  – the load was applied 
from the side of the steel layer. 
 
 
Figs. 8 – 11 summarize the stress values in a bimetallic perforated plate centrally loaded with a concentrated force Pi. The 
strains measurement concerned points on the bridges between the plate holes, arranged according to the diagrams shown 
in Figs. 4 and 5. These are points in zones with a significant stress concentration compared to a homogeneous plate.  
The comparison of the stress results presented in Figs. 8 – 11 shows that when the plate load is applied from the side of the 
applied layer, i.e. the titanium, stress values differ slightly from the stresses obtained for the same plate but loaded from the 
side of the base layer, i.e. steel . This is the result of residual stresses in the bimetallic perforated plate. In practice, such 
bimetallic plates are not subject to heat treatment due to their large size. In industry, such plates are used in the raw state 
[19], for example as heat exchanger tube sheets [10].  
The deformation measurements were made in the plate perforation zone (Figs. 4 and 5), where in the process of making 
holes, the residual stresses should be reduced. However, the conducted tests showed that the residual stresses cause 
discrepancies in the determination of stresses resulting from the load on the perforated plate. Moreover, it can be seen from 
Fig. 12 that when the load is applied from the side of the base layer, i.e. the steel layer, the deflection 1w  is greater than the 

deflection obtained when the load was applied from the side of the applied layer, i.e. the titanium layer 2w . It also indicates 
that residual stresses occur in the bimetallic perforated plate in the area where the titanium plates are connected to the steel 
plate [21]. The deflection concerns the point of the geometric center of the plate, which consists of a perforated zone  (60 
mm ⩽ r ⩽ 130.5 mm) and a homogeneous zone (6 mm ⩽ r ⩽ 60 mm) (Fig. 1). 
 
 
CONCLUSIONS 
 

he following conclusions can be drawn from the above analysis: 
1) The distribution of stresses in the plate perforation zone was determined in the places of stress 
concentration;  

2) It has been shown that despite the holes made in the plate, we deal with the presence of residual stresses arising in 
the process of explosive joining of steel sheet with titanium sheet;  

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M. M. Konieczny et alii, Frattura ed Integrità Strutturale, 55 (2021) 277-288; DOI: 10.3221/IGF-ESIS.55.21                                                        
 

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3) The proposed method of experimental research can be used by engineers to verify the state of stress, e.g. in the 
designed tube sheet walls of reactors for ammonia synthesis. 

 
 
REFERENCES  
 
[1] Niezgodziński, M.E. (1973). Obliczenia grubości ścian sitowych w zbiornikach ciśnieniowych, Przegląd Mechaniczny, 

3, ss. 102-105 (in Polish).  
[2] Chen, K.T., Ting, K. and Yang, W.S. (2000). Stress analysis of two-dimensional perforated plates using boundary 

element alternating method, Computers and Structures, 75,  pp. 515 – 527, DOI: 10.1016/S0045-7949(99)00103-0.  
[3] Kang, J. H. (2014). Exact solutions of stresses, strains, and displacements of a perforated rectangular plate by a central 

circular hole subjected to linearly varying inplane normal stresses on two opposite edges, International Journal of 
Mechanical Sciences, 84, pp. 18 – 24, DOI: 10.1016/j.ijmecsci.2014.03.023. 

[4] Mirji, P. (2013). Optimization of rectangular plate with two holes subjected to in plane static loading, International 
Journal of Scientific and Engineering Research, 4(6), pp. 1470 - 1473. 

[5] Bhattacharya, A. and Venkat, R. (2003). Peak stress multipliers for thin perforated plates with square arrays of circular 
hole, International Journal Pressure Vessels and Piping, 80, pp. 379 – 388, DOI: 10.1016/S0308-0161(03)00067-X. 

[6] Bhattacharya, A. and Venkat, R. (2004). Yield Surfaces for Perforated Plates with Square Arrays of Holes, Nuclear 
Engineering and Design, 231, pp. 219 – 233, DOI: 10.1016/j.nucengdes.2004.04.001. 

[7] Niezgodziński, M.E. and Zwoliński, W. (1973). Obliczenie den sitowych usztywnionych przez płaszcz zbiornika, 
Przegląd Mechaniczny, 8, (in Polish). 

[8] Konieczny, M., Achtelik, H. and Gasiak, G. (2020). Finite Element Analysis (FEA) and experimental stress analysis in 
circular perforated plates loaded with concentrated force, Frattura ed Integrità Strutturale, 51, pp. 164-173,  
DOI: 10.3221/IGF-ESIS.51.13. 

[9] Achtelik, H., Gasiak, G.and Grzelak, J. (2008). Strength tests of axially symmetric perforated plates for chemical 
reactors: Part 1—The simulation of stress state, International Journal of Pressure Vessels and Piping, 85, pp. 248 – 256, 
DOI: 10.1016/j.ijpvp.2007.08.009.  

[10] Achtelik, H., Gasiak, G. and Grzelak, J. (2008). Strength tests of axially symmetric perforated plates for chemical 
reactors: Part 2—Experiments, International Journal of Pressure Vessels and Piping, 85, pp. 257 – 264,  
DOI: 10.1016/j.ijpvp.2007.08.010.  

[11] Ledwoń ,W. and Achtelik, H. (2017). Experimental analysis of the state of stress of the axisymetric perforated plates 
loaded with hydrostatic pressure, Proceedings of the 13th International Scientific Conference: Computer Aided 
Engineering, pp. 331 - 341. 

[12] Duncan, J. P. (1955). The structural efficiency of tube – plates for head exchangers, Proceedings of Institute of 
Mechanical Engineers, 169, pp. 789-802. 

[13] Gasiak, G. and Sojka, M. (2005). Wytężenie płyt perforowanych, Studia i Monografie, 224, Politechnika Opolska, ss. 95 
– 108 (in Polish). 

[14] Andh, U., Chavan, S., Kulkarni, S. and Khurd, S. (2016). Stress analysis of perforated plates under uniaxial compression 
using FEA and photoelasticity, International Research Journal of Engineering and Technology, 3 (11), pp. 239 – 244, 
DOI: 10.1007/978-3-030-16848-3_90. 

[15] Andh, U., Chavan, S., Kulkarni, S. and Khurd, S. (2017). Stress analysis of perforated plates under uniaxial compression 
using experimentation and finite element analysis, International Journal of Current Engineering and Technology, 7(2),  
pp. 431 - 437. 

[16] Konieczny, M., Achtelik, H. and Gasiak, G. (2020). Stress distribution in plated perforated plate loaded centrally with 
concentrated force, Zmęczenie materiału w eksploatacji maszyn roboczych, PO, 2, pp. 47-62. 

[17] Konieczny, M., Achtelik, H. and Gasiak, G. (2021). Location of stress concentration zones in a two-layer axially 
symmetrical perforated plate with force applied normally to its surface, Engineering Structures, 226, pp. 1-14.  

[18] Walczak, W. (1989). Metal explosion welding, WTN, Warsaw (in Polish). 
[19] Data from Explomet Company research (Z.T.W. EXPLOMET, Gałka, Szulc, Sp. j. ul. Oświęcimska 100H, 45-641 

Opole, Poland). 
[20] Thimoshenko, S. Strengh of Materials, Princeton D. Van Nostrand Co, Inc. Part 1 (1956), Part 2 (1957). 
[21] Karolczuk, A. and Kowalski, M. (2013). Residual stress determination based on the hole drilling method in explosively 

welded bimetallic composite, 13th International Conference on Material Modelling, Warsaw, p. 140.