12 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 12-16 
 
 

Submitted  : September 3, 2018  
Accepted  : October 10, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19544 

 

Analysis of Tensile Strenght and Shear Modulus of GRE Pipe using 
Ansys  

 

Dita Puspita
1,a

, Siti Lailatul Arofah
1
, Elok Hidayah

1
, Lutfi Rohman

1
 and 

Ratna Dewi Syarifah
1
  

1
Department of Physics, Faculty of Mathematics and Natural Sciencs, University of Jember, 

Jalan Kalimantan No 37 Jember 68121, Indonesia 

a
ummusafiyah88@gmail.com 

 
 
Abstract. Composite materials (GRE pipe) had been applied in various industries. These kind application 
are based on the advantages of composite properties, that are lightweight, high corrosion resistance and 
low cost. In order to make a lightweight and strong materials, some materials that light and stiff had been 
widely used, lie fiber glass, epoxy and the other. These materials (fiber glass and epoxy) are synthetic 
and non-biodegradable, but give some advantages in composite to make composite more stiff, light and 
strong. Mechanical properties of fiber glass composites had been doing based on theory through 
modeling. Theoretical results obtained showed that maximum stress and shear modulus value of GRE 
pipe are less than each components (glass fiber and epoxy resin). Each value of maximum stress and 
shear modulus are 584.57 MPa and 46.15 MPa. 

Keywords: composite material, Ansys, GRE pipe 

Introduction 

Composite material is a material consisting of two or more constituent materials which 
physically and mechanically can be distinguished from one another [1]. Composite material 
consists of two main components, namely reinforcement and matrix. Reinforcement is a 
component that determines the strength and stiffness of the composite material. While the 
matrix is a material that functions to bind and protect the composite material from external 
influences [2]. Composite materials have been widely applied in various industrial fields [3,1] 
because of their relatively cheap production costs, strength, light weight, and resistance to 
corrosion [4]. One of the applications of composite materials is the oil and gas industry pipes. 
 
Metal pipe is a pipe that is often used in the oil and gas industry because of its excellent 
strength. However, metal pipes also have disadvantages, namely low corrosion resistance. 
Especially for the offshore oil and gas industry, corrosion problems in pipes often occur both 
inside and outside the pipe. Corrosion of the inner pipe usually occurs due to the reaction 
between the pipe building materials and gases such as carbon dioxide (CO2) and hydrogen 
sulfide (H2S) [5]. Due to corrosion in pipes causing several operational and health problems 
which are commonly referred to as the cases of CAPEX and OPEX (capital and operational 
expenditures) and HSE (health, safety, and the environment) in the oil and gas industry. Most of 
the reported corrosion was due to carbon dioxide gas and caused a 25% safety incident 
problem, 2.2% real assets, an 8.5% increase in capital expenditure, a 5% loss / deferred 
production, and an 11.5% increase in pipeline lifting costs [6]. Therefore a pipe with strong 
mechanical properties and corrosion resistance is needed.  
 



  
 
 
 
 

13 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 12-16 
 
 

Submitted  : September 3, 2018  
Accepted  : October 10, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19544 

One type of pipe that suits these conditions is a pipe made of GRE (glass reinforced epoxy) 
composite material, which is a composite material with a matrix in the form of epoxy and a glass 
fiber reinforcement [7]. Epoxy is used as a matrix because it has the best chemical resistance 
among other resins (isophatalic polyester, vinyl ester, and phenolics) [8]. GRE pipes are 
designed to withstand high pressure, light weight, and have high strength so that they can be 
properly applied to the oil and gas industry.  
 
The use of GRE composite materials for the manufacture of oil and gas industry pipes needs to 
pay attention to its mechanical properties. Mechanical properties are parameters used to 
determine the strength and suitability of a material before it is applied as a product. The test 
used is the tensile test. Through the tensile test it can be seen the tensile strength and modulus 
of elasticity of the material [9]. Tensile strength is the maximum tensile stress a material can 
accept without causing local fracture [10]. While the modulus of elasticity is a mechanical 
property that shows the stiffness of a material. The greater the modulus of elasticity, with the 
application of the same force, the material will experience a slight change compared to 
materials with a small modulus of elasticity [11]. 
 
GRE pipe testing is done using Ansys software. Ansys is a program used to model finite 
elements to solve cases related to mechanics, including static, dynamic, fluid structural analysis, 
as well as cases related to acoustics and electromagnetics. Testing is done by making the pipe 
geometry and then inputting the GRE material parameters. Testing by means of modeling is 
carried out to obtain an estimate of the material and its mechanical properties before the 
experiment is carried out, so that the results of the modeling can be used as a consideration 
when conducting experiments. 

Method  

The first step is making a model by inputting data in the form of pipe geometry and GRE 
material parameters in ANSYS 18.2 software, input parameters such as modulus of elasticity. 
Poisson ration, thickness, radius, length, and density are inputted. Then do the meshing 
process. Because the method used in Ansys is the finite element method, when meshing the 
geometric surface it will be divided into small squares (1835 nodes and 1518 elements). The 
next step is to input the boundary conditions on the pipe geometry that has been made. Then 
tested and then analyzed the results. 

Results and Discussion  

Composite material synthesis is one of the methods used to improve the mechanical properties 
of each component of the composite material. analysis of the mechanical properties of 
composite materials can be done directly through experiments, and indirectly by modeling. 
Modeling is one way that can be done to estimate the shape and mechanical properties of the 
materials to be made, so that the determination of materials for certain applications becomes 
easier. In this research, glass fiber and epoxy resin are combined to manufacture GRE (Glass 
Reinforce Epoxy) pipes. The geometry obtained based on the modeling results is shown in 
Figure 1. 

 



  
 
 
 
 

14 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 12-16 
 
 

Submitted  : September 3, 2018  
Accepted  : October 10, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19544 

 
Figure 1. The geometry of the GRE pipe the resulting GRE pipe has an inner diameter of 20 cm, 

an outer diameter of 22 cm, a height of 30 cm and a thickness of 2 cm. 

 
The tensile test is carried out by determining the points on the pipe as the location to be drawn, 
the direction of pull and the static point of the pipe. The static point is the part of the pipe that is 
fixed or not moving, because in this simulation the pulling force is only applied to one end of the 
material, while the other end is fixed. There are several mechanical properties produced by 
modeling this GRE pipe, including maximum tensile stress, maximum strain, maximum 
deformation and shear modulus.   
 
Modeled GRE pipe has a maximum tensile stress of 584.57 MPa, as shown in Figure 2. This 
value is still smaller than the maximum tensile stress possessed by glass fiber and epoxy resin. 
Some things that may affect the maximum tensile stress value are the meshing size that is too 
large, so it does not represent all elements in the pipe. Another factor is the geometry of the 
material in the form of a hollow pipe. The presence of a cavity may contribute to the reduced 
mechanical properties of the synthesized composite material. The shear modulus produced by 
GRE pipe is 46.15 MPa. In addition to the tensile stress value, the maximum strain and 
maximum deformation values of GRE pipe are obtained as shown in Figure 3 and Figure 4. The 
maximum strain and maximum deformation values of GRE pipe are respectively 7.45% and 
0.1058 cm. 
 

 
Figure 2. The maximum tensile stress of the GRE pipe 



  
 
 
 
 

15 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 12-16 
 
 

Submitted  : September 3, 2018  
Accepted  : October 10, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19544 

 
Figure 3. The maximum strain of the GRE pipe 

 
 

 
Figure 4. Maximum deformation of GRE pipe 

 

Summary  

Research on the analysis of the tensile strength and shear modulus of GRE pipes has been 
carried out. The tensile stress value resulting from the modeling is still far different from the 
maximum tensile stress of epoxy resin and glass fiber. Due to the small tensile stress, the shear 
modulus is also small. This is presumably due to the large size of the meshing. Therefore, 
further research can be carried out with a smaller meshing size in order to obtain results with 
better accuracy. 

References 

[1]  N Sridhar, D S Dunn, A M Anderko, M M Lencka and H U Schutt, 2000, Effect of Water and 
Gas Compositions on The Internal Corrosion of Gas Pipelines Modeling and Experimental 
Studies, Corrosion, volume 57(3). 

[2] J M Berthelot, 1999, Composite Materials: Mechanical Behavior and Structural Analysis, 
New York, Springer. 



  
 
 
 
 

16 
 

Computational and Experimental Research  
in Materials and Renewable Energy (CERiMRE)         
Volume 1, Issue 1, page 12-16 
 
 

Submitted  : September 3, 2018  
Accepted  : October 10, 2018 
Online  : November 10, 2018 
doi : 10.19184/cerimre.v1i1.19544 

[3] P A Fowler, J M Hughes and R M Elias, 2006, Biocomposites: Technology, Environmental 
Credentials and Market Forces, Journal of the Sciences of Food and Agricultures, volume 
86, page 1781 – 1789. 

[4] M Akay, 2015, An Introduction to Polymer-matrix Composites, http://www.bookbon.com, 
accessed January 11, 2018. 

[5]  P Wambua, J Ivens and I Verpoest, 2003, Natural Fiber: Can They Replace Glass in Fiber 
Reinforced  Plastics, Composites Science and Technology, volume 63, page 1259 – 1264. 

[6]  M B Kermani and A Morshed, 2003, Carbon Dioxide Corrosion in Oil and Gas Production-A 
Compendium, Corrosion, volume 59(8). 

[7]  S R Frost and A Cervenka, 1994, Glass Fibre-reinforced epoxy matrix filament-wound pipes 
for use in the oil industry, Composit manufacturing, volume 5(2). 

[8]  N Himawan, I Rochani and H Ikhwani, Comparative Analysis of Onshore Pipeline Design 
Using Material Glass Reinforced Polymer (GRP) and Carbon Steel Based on Techno 
Echonomic. 

[9]  J R Davis, 2004, Tensile Testing Second Edition, USA: ASM International. 

[10] M Ohring, 1995, Engineering Materials Science, California: Academic Press INC. 

[11] D Roylance, 2008, Mechanical Properties of Materials, USA: MIT. 

 

 

 

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