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- 1. STRESS ANALYSIS OF BASALT /EPOXY LAMINATE J.Alexander1, DR.BSM.Augustine2 1 ,PhD Scholar, Sathyabama University,Chennai-600119 e-mail vsjalexander@rediffmail.com 2 Professor,Sathyabama University,Chennai-600119 Introduction BASALT FIBER, A new kind of inorganic fiber like glass fiber, is fabricated from basalt rocks through the melting process. It has a higher working temperature and better tensile strength than E-glass fiber as well as good resistance to chemical attack, impact load, and fire with less poisonous fumes. In addition, the basalt fibers do not need any other additives in the single producing process, adding special benefit in cost. Basalt fiber reinforced composites show great improvement in the elastic modulus, chemical resistance and thermal stability compared to glass fiber reinforced composites. These advantages make basalt fiber a promising alternative to glass fiber as a reinforcement material in aerospace, metallurgical, chemical, building industries and so on. In the past five years the use of basalt fibers have been tried in many applications and close attention has been paid to its qualities, especially the excellent chemical resistance which accelerates the application of basalt fibers in both organic and inorganic matrix composites. At this work Basalt epoxy laminate was fabricated using hand lay up process and the material properties were found using experimental methods. Classical Laminated theory is used for calculating Lamina stresses which are compared with lamina stresses of various composite materials.The result shows baslt/epoxy laminate has very good strengths at axial loads.
- 2. The basalt fiber used in the experiment was Basalt fabric whose density is2.7grams/cm3 mixed with LY552 epoxy resins .The fiber – resin volume fraction is 60:40 After being impregnated in resins and cured, the basalt yarns were cut short to about 350 mm, and smooth and rounded specimens were selected for the tests of tensile strength, tensile modulus and elongation at break. Both ends of the selected samples were tabbed by two pieces of starched paper to avoid the end breakage caused by test machine clamp. The gauge length of the sample was 200 mm. The basalt yarns tensile strength was tested on a universal testing machine according to GB3362-82, and the load velocity was 2 mm/min. Table i Tensile Test Results Width(mm Thickness(mm) Breaking Tensile Tensile ) load(N) strength modulus (N/mm^2) (KN/mm^2) 26.4 4.3 16.8 148 12.247 25.8 4.65 15.38 128 11.822 24.8 4.8 17.1 144 10.952 Table ii Compression test Results Area (mm^2) Breaking load(N) Compression strength (N/mm^2) 12.25*12.65 30.96 200 13.5*13.75 24.8 134 13.5*13.25 29.06 163 The above Test result are used in the laminated plate theory for stress analysis II Laminated Plate Theory The mechanics of materials deal with stresses, strains, and deformations in engineering structures subjected to mechanical and thermal loads. A common assumption in the mechanics of conventional materials, such as steel and aluminum, is that they are
- 3. homogeneous and isotropic continua. For a homogeneous material, properties do not depend on the location, and for an isotropic material, properties do not depend on the orientation. Unless severely cold-worked, grains in metallic materials are randomly oriented so that, on a statistical basis, the assumption of isotropy can be justified. Fiber-reinforced composites, on the other hand, are microscopically inhomogeneous and non isotropic (orthotropic). As a result, the mechanics of fiber-reinforced composites. Lamination theory is useful in calculating stresses and strains in each lamina of a thin laminated structure. Beginning with the stiffness matrix of each lamina, the step- by-step procedure in lamination theory includes 1. Calculation of stiffness matrices for the laminate 2. Calculation of mid plane strains and curvatures for the laminate due to a given set of applied forces and moment s 3. Calculation of in-plane strains εxx, εyy , and γxy for each lamina 4. Calculation of in-plane stresses sxx, syy , and txy in each lamina The geometric midplane of the laminate contains the xy axes, and the z axis defines the thickness direction. The total thickness of the laminate is h, and the thickness of various laminas are represented by t1, t2, t3, and so on. The total number of laminas is N. A sketch for the laminate is shown in Figure 1
- 4. ---------------------------------------------------- -----------------------------------------------------------(1) where ε0xx -, ε0yy mid plane normal strains in the laminate 0 γ xy - mid plane shear strain in the laminate kxx ,- k yy bending curvatures of the laminate kxy - twisting curvature of the laminate z - distance from the mid plane in the thickness direction Laminate Forces and Moments
- 5. Applied force an d moment resultant (Figure 2) on a laminate are related to the mid plane strains and curvatures by the following equations -----------------------------------(2) FIGURE 2 In-plane, bending, and twisting loads applied on a laminate. In matrix notion the force and moment equations are written as -------------------------- -----------------------------------------------(3) ------------------------------ -----------------------------------------------(4)
- 6. ---------------------------------------- -------------------------------------------------(5) ------------------------------------------------------------------------------------------ (6) -------------------------------------------------------------------------------------------- (7) The fabricated Basalt/epoxy laminate is subjected to an axial load of 100N in the X direction and the stresses in each ply is analysed by using matlab software . ************************************************************* **** * Analysis of Composite Laminates Based on * * Classical Laminated Plate Theory * ******************************************************* *********************** Material 4: User Material: BASALT/EPOXY552 Engineering Properties ********************** Matl E1 E2 G12 v12 1 1.810e+011 1.028e+010 7.172e+009 0.280 2 3.931e+010 8.552e+009 3.724e+009 0.280 3 8.690e+010 5.517e+009 2.138e+009 0.340 4 5.480e+010 1.757e+010 7.138e+009 0.232 Stacking Sequence ***************** Layer Matl Ply Angle Ply Thickness 1 4 30.0 1.200e+000 2 4 60.0 1.200e+000
- 7. 3 4 30.0 1.200e+000 ---------- Laminate Mechanical Input Load Vector ************************************* NX NY NXY MX MY MXY 1.000e+002 0.000e+000 0.000e+000 0.000e+000 0.000e+000 0.000e+000 Laminate Matrices ***************** 'ABD' Matrix 1.191e+011 3.977e+010 3.431e+010 7.629e-006 5.722e-006 3.815e-006 3.977e+010 9.636e+010 2.475e+010 5.722e-006 1.144e-005 2.861e-006 3.431e+010 2.475e+010 5.053e+010 3.815e-006 2.861e-006 7.629e-006 7.629e-006 5.722e-006 3.815e-006 1.504e+011 4.295e+010 4.623e+010 5.722e-006 1.144e-005 2.861e-006 4.295e+010 8.224e+010 1.755e+010 3.815e-006 2.861e-006 7.629e-006 4.623e+010 1.755e+010 5.458e+010 Apparent Laminate Stiffness Properties ************************************** EX EY GXY EXB EYB 2.487e+010 2.187e+010 1.070e+010 2.597e+010 1.788e+010 Apparent Laminate Coupling Coefficients (Poisson and Shear Coupling) *************************************** vXY vYX nXY,X nXY,Y nX,XY nY,XY 0.273 0.240 -0.545 -0.327 -0.235 -0. Laminate Total Strain Vector **************************** eX eY gXY KX KY KXY 1.117e-009 -3.046e-010 -6.091e-010 -4.898e-026 -2.501e-027 6.534e-026 Stresses and Strains in the Global Coordinate System (X,Y) - Lower Surfaces ******************************************************* ********************* Layer Eps-X Eps-Y Gam-XY Sig-X Sig-Y Sig-XY 1 1.117e-009 -3.046e-010 -6.091e-010 3.321e+001 3.540e+000 3.775e+000 2 1.117e-009 -3.046e-010 -6.091e-010 1.691e+001 -7.081e+000 -7.549e+000 3 1.117e-009 -3.046e-010 -6.091e-010 3.321e+001 3.540e+000 3.775e+000 Stresses and Strains in the Material Coordinate System (1,2) - Lower Surfaces Strains are given as Total Strains (Mechanical + Thermal + Moisture)
- 8. ******************************************************* ********************** Layer Eps-1 Eps-2 Gam-12 Sig-1 Sig-2 Sig-12 1 4.978e-010 3.146e-010 -1.536e-009 2.906e+001 7.689e+000 -1.096e+001 2 -2.129e-010 1.025e-009 -9.265e-010 -7.621e+000 1.745e+001 -6.613e+000 3 4.978e-010 3.146e-010 -1.536e-009 2.906e+001 7.689e+000 -1.096e+001 Material Strengths ****************** Matl Xt Xc Yt Yc S 1 1.500e+009 -1.500e+009 4.000e+007 -2.462e+008 6.828e+007 2 1.083e+009 -6.207e+008 3.931e+007 -1.283e+008 8.897e+007 3 1.276e+009 -3.379e+008 2.897e+007 -1.579e+008 4.897e+007 4 1.480e+008 -2.000e+008 1.480e+008 -2.000e+008 1.400e+007 Conclusion For a particular load the stresses in each layer is calculated .These stress values are compared with results of same type of laminate with different material. But the properties of basalt /epoxy laminate is better than Glass/epoxy laminate. Hence glass/epoxy can be replaced by Basalt/epoxy for various structural applications. (Detailed results will be discussed in the full paper. References 1. Medvedyev, O. O. and Tsybulya, Y. L. (2004). The Outlook for the use of Basalt Continuous Fibers for Composite Reinforcement[C], International SAMPE Technical Conference, SAMPE 2004, 16–20 May 2004, Long Beach, CA, United States, pp. 275–279. The effect of adhesion interaction on the mechanical properties of 2. thermoplastic basalt plastics P. I. Bashtannik, A. I. Kabak,and Yu. Yakovchuk, Mechanics of Composite Materials, Vol. 39, No. 1, 2003. 3 Novel basalt fibre reinforced glass matrix composites, e. bernardo e. stoll†,, a. r. boccaccini j mater sci 41 (2006) 1207–1211. 4. Chemical Composition and Mechanical Properties of Basalt and Glass Fibers: A Comparison Tamás Deák and Tibor Czigány,Textile Research Journal 2009 79: 645.
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