International Journal of Mechanical Engineering and Technology (IJMET) Volume 10, Issue 01, January 2019, pp. 543–549, Article ID: IJMET_10_01_056 Available online at http://www.iaeme.com/ijmet/issues.asp?JType=IJMET&VType=10&IType=01 ISSN Print: 0976-6340 and ISSN Online: 0976-6359 © IAEME Publication Scopus Indexed EFFECT OF PROCESS PARAMETERS ON WEAR BEHAVIOR AND WATER ABSORPTION OF UHMWPE FABRIC REINFORCED EPOXY COMPOSITES P.RajendraPrasad* Research Scholar, School of Mechanical Engineering, Reva University, Bangalore, INDIA. Assistant Professor, Department of Mechanical Engineering, G.Pulla Reddy Engineering College, Kurnool, INDIA, J.N.Prakash Research Supervisor, School of Mechanical Engineering, Reva University, Bangalore, INDIA 3 L.H.Manjunath School of Mechanical Engineering, Reva University, Bangalore, INDIA. *Corresponding author ABSTRACT The use of artificial fiber reinforced composites are widely used in many applications such as automobile, aircraft manufacturing because they are cost effective and offers high strength, and weight ratio compared to other composites with similar applications. In this work, epoxy was selected as a matrix material to prepare a composite specimens reinforced with UHMWPE fabric with varying layers. Composite specimens are prepared by varying the number of fabric layers and Taguchi’s L9 orthogonal array method is used to study the Tribological behavior. The test specimen of composite material had been prepared using hand layup technique and the samples were tested for wear properties using the equipment DUCOM made pin on disc experimental setup. The weight was measured before and after the experiment is conducted. The effects of the Tribological operating parameters applied load, sliding velocity and sliding distance on the frictional and wear performance of UHMWPE fabric reinforced composites are demonstrated. Moreover, water absorption tests were conducted to know their effect over a period of time for both the aerial densities 200gsm and 240gsm of the fiber mats. It was observed that the wear response of the specimens is influenced by the applied load, sliding distance and the speed. Keywords: Woven fabric, textile composites, UHMWPE, orthogonal array, and Hand lay-up. Cite this Article: P.RajendraPrasad, J.N.Prakash and L.H.Manjunath, EFFECT OF PROCESS PARAMETERS ON WEAR BEHAVIOR AND WATER ABSORPTION OF UHMWPE FABRIC REINFORCED EPOXY COMPOSITES, International Journal of Mechanical Engineering and Technology, 10(01), 2019, pp.543–549 http://www.iaeme.com/IJMET/issues.asp?JType=IJMET&VType=10&Type=01 http://www.iaeme.com/IJMET/index.asp 543 editor@iaeme.com P.RajendraPrasad, J.N.Prakash and L.H.Manjunath 1. INTRODUCTION From decades the customary metals or materials have been supplanted by Polymer matrix composites (PMC) in view of simplicity of processing, productivity and low cost. Because of their splendid formability, low specific weight, high stiffness to weight and high strength to weight proportions the fiber-reinforced polymer (FRP) [1-3] composites are used in various fields of Engineering and structural applications such as ship superstructures, marine, auto mobile, machine parts, and the modern aerospace industries [3]. The Fiber-reinforced polymer (FRP) composites are made of two constituents i.e. thermosetting or thermoplastic resins [11] as matrix material, and fiber or fabric as reinforcement [2]. The fiber or fabric provides a load-bearing capacity while the resin contributes to transfer of loads to the fiber. Resins also protect the fibers from environmental factors such as humidity, high temperature, and chemical attack [2, 3]. The FRP composites possess desired Mechanical properties like Tensile, Flexural and Impact strengths, and Tribological properties. The Mechanical properties of FRP composites depend on the properties of the fiber and matrix constituents, as well as the interface between the fiber and matrix [4]. The Thermosets (epoxies & phenolics) and Thermoplastics are used as matrix, and Fiber glasses, Carbon fiber, Kevlar (Aramid) fiber, and Ultra-high molecular weight polyethylene (UHMWPE) fiber are used as reinforcement [3]. The UHMWPE fiber or high modulus fiber considered as third generation high-performance fiber [5-9] after Kevlar and carbon fiber because of remarkable physical and mechanical properties such as high specific weight, high modulus, high stiffness, high cut proof and abrasion resistance, good UV resistance, water resistant, and non-chemical reactive [3,10]. Due to these exceptional properties the UHMWPE fiber reinforced composites are extensively used in aerospace, automobile [11], and sports utilities industries [3]. Ultra–high molecular weight polyethylene (UHMWPE) woven fabric reinforced polymer (WFRP) composite laminates or textile composites are increasingly used in defense industries and marine construction due to their exceptional properties like highest strength to weight ratio, and outstanding features like environmental resistance and long life, these would be the better replacement to traditional materials like metals and ceramics. In this work UHMWPE fabric reinforced polymer composites were synthesized and wear and friction properties of the specimens were investigated. The water absorption test also conducted to investigate the water resistance in the composite specimens. 2. MATERIALS AND METHODS 2.1. Materials The Epoxy resin (LAPOX L-12) of medium viscosity is used as matrix material, and a room temperature curing polyamine hardener (K-6) both are supplied by ATUL Limited (Polymers division), Gujarat, India. The properties of epoxy resin and hardener are given in table 1. The Ultra-high molecular weight polyethylene (UHMWPE) fabric of 200 gsm and 240 gsm areal densities are used as reinforcement material supplied by Huaheng High Performance Fiber Textile Co. Ltd (China), the details of fabrics given in table 2. http://www.iaeme.com/IJMET/index.asp 544 editor@iaeme.com EFFECT OF PROCESS PARAMETERS ON WEAR BEHAVIOR AND WATER ABSORPTION OF UHMWPE FABRIC REINFORCED EPOXY COMPOSITES Table 1: Properties of Epoxy resin and Hardener Typical values Description Epoxy (L-12) Appearance Clear viscous liquid Hardener (K-6) Pale yellow liquid 1.1-1.2 0.95-1.1 9000-12000 5-15 180-190 - Density at 25 ºC (g/cm3) Viscosity (mpa.s at 25ºC) Epoxy Equi. Wt (g/eq) Table 2: Details of Fabric Parameter Areal density (gsm) Weave Fiber count (cm) Yarn denier Thickness (mm) UHMWPE Fabric 200 240 Plain Plain 15.5X12 10X9 600D 1000D 0.42 0.48 2.2. Processing of composites The composites are prepared as laminates with fixed dimensions of 160 x 160 x 3 mm3. The matrix is prepared by mixing epoxy (LAPOX L-12) and 10% hardener (K-6). Hardener is added to the resin system shortly before use to initiate the polymerization reaction. A glass mould with the aforementioned dimensions is placed and a layer of wax is coated over it which acts as releasing agent. Resin is applied on top of the layer of fiber and it’s ensured that the fiber is completely wet. Another layer of fiber is placed on top. These steps are repeated until the desired thickness was obtained. Another plastic sheet is placed on top. Pressure is applied using weights over the mould in order to ooze out the excess matrix and to apply load uniformly. These steps were followed to make the three different layered composites. The composite material reinforced with UHMWPE and epoxy matrix was analyzed for wear with ASTM G99. Wear and Friction monitor- TR 201 (Pin on disc) wear apparatus is shown in Figure.1 and its specifications are shown in Table.3. http://www.iaeme.com/IJMET/index.asp 545 editor@iaeme.com P.RajendraPrasad, J.N.Prakash and L.H.Manjunath Figure.1 Wear and Friction test experimental set up with specimen Table 3. Tribological test specification Pin size 2mm - 10mm Wear 2000 micrometer Disc size 6mm X 100mm Frictional Force 100N 3. RESULTS AND DISCUSSION Wear and frictional force tests were performed as per Taguchi’s L9 orthogonal array. Taguchi’s method is used when the numbers of inputs are too large to allow for exhaustive testing of every possible input. Three layers of composites were processed and planned to study the wear properties with varying parameters of Load (N), Speed (rpm) and Time (min) which was listed in Table 4. Table 4. Wear Test process conditions S. No. Load (N) Speed (rpm) Time (Min) 1 2 3 4 5 6 7 8 9 10 10 10 20 20 20 30 30 30 500 600 700 500 600 700 500 600 700 5 10 15 10 15 5 15 5 10 http://www.iaeme.com/IJMET/index.asp 546 editor@iaeme.com EFFECT OF PROCESS PARAMETERS ON WEAR BEHAVIOR AND WATER ABSORPTION OF UHMWPE FABRIC REINFORCED EPOXY COMPOSITES Table 5. Experimental design and its response on single layered composite specimen 240 gsm weight loss (milligrams) S. No. 1 2 3 4 5 6 7 8 9 200 gsm weight loss (milligrams) 1 layer 2 layers 3 layers 1 layer 2 layers 3 layers 0.0863 0.0892 0.0941 0.0895 0.0995 0.0877 0.0917 0.0899 0.0914 0.0864 0.0892 0.0942 0.0894 0.0994 0.0877 0.0916 0.0896 0.0913 0.0862 0.0891 0.0943 0.0896 0.0995 0.0874 0.0915 0.0894 0.0912 0.0895 0.0897 0.0941 0.0915 0.0924 0.0931 0.0924 0.0914 0.0922 0.0897 0.0892 0.0942 0.0914 0.0924 0.0936 0.0928 0.0915 0.0924 0.0895 0.0898 0.0943 0.0914 0.0925 0.0934 0.0926 0.0918 0.0921 Wear tests were conducted on the composite specimens to tests the wear resistance of the specimens using pin-on-disc test apparatus. A total of 54 tests were conducted to know the wear behavior against the EN32 material. The weight loss obtained for all these samples with different process parameters is very minute as shown in Table 5. Only one conclusion can be drawn from the data that as the time of the contact increases, wear (weight loss) increases, that too only a minute increment. 3.1. Water Absorption Tests The effect of number of layers on the water absorption UHMWPE reinforced composites for both the areal densities increased in immersion time is shown in Figure 2 & 3. It is evident from the figures that the rate of moisture absorption increases with increase in number of layers. Another effect of increasing water absorption rate of composites is the nature of UHMWPE fiber, voids inside the composites lead to the formation of micro channels. After immersion time in water, the presence of these micro voids and cracks in the composite surface results in the movement of water molecules to the material by capillary action [12]. Water absorption (%) 0.9 0.8 240 gsm 1 layer 0.7 240 gsm 2 layers 240 gsm 3 layers 0.6 0.5 0.4 0.3 0.2 0.1 0 0 1 2 3 4 Days 5 6 7 8 Figure.2 Effect of layers on water absorption with 240 gsm http://www.iaeme.com/IJMET/index.asp 547 editor@iaeme.com P.RajendraPrasad, J.N.Prakash and L.H.Manjunath 0.7 200 gsm 1 layer 0.6 Water Absorption (%) 200 gsm 2 layers 0.5 200 gsm 3 layers 0.4 0.3 0.2 0.1 0 0 2 4 Days 6 8 Figure.3 Effect of layers on water absorption with 200 gsm 4. CONCLUSIONS Composite laminates are prepared for both areal densities of 200 gsm and 240 gsm UHMWPE plane woven fabric reinforcement by varying the number of layers. A total of 3 laminates were prepared for each areal density with 1, 2 and 3 layers of UHMWPE fabric. Both water absorption and wear tests were conducted for all the six samples. 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