It is difficult to solve the structural problems related to agricultural engineering, due to the wide ranges of the means of related variables and complex structural shapes. For these reasons, discrete models are required that are able to replace or simplify solid structure components used in traditional analysis methods. Therefore, the objective of this study was to develop a regular truss structure model that behaves the same way as a solid structure. It was assumed that if a unit element consists of truss elements with each hinge at the end of the element and the size of the element is infinitesimal, the stress distribution and displacement field will be constant throughout the domain of the unit element. Additionally, the behavior of the truss element was assumed to be in a linear state in a two-dimensional plane. The law of energy conservation, based on the theory of elasticity, was applied to determine the equilibrium conditions between discretized and solid elements. The restrictive condition that we obtained revealed that applications are limited to only ideal elastic materials with a Poisson’s ratio of 1 to 3. The volumetric ratio of the equivalent truss to the continuum structures was 3:1, regardless of the size or number of the mesh. To calculate the internal stress and strain of the unit element, the geometric relationships of each truss member, which has its own role against different stress directions, were used. The calculated von Misses stresses were used to verify this model. Stress concentrations, as explained based on Saint Venant’s principle, were also observed in the equivalent truss structure model. The main stress paths, indicating the areas where reinforcement bars should be placed, were successfully shown without the requirement that each element be transformed in the direction of principal stress; this was done by eliminating elements with only compressive and near-zero stresses.
Keywords: structural analysis, regular mesh, equivalent truss structure model, discretized element, energy method
DOI: 10.3965/j.ijabe.20150805.1742

Citation: Choi W, Lee J, Yoon S. Regular truss structure model equivalent to continuum structure. Int J Agric & Biol Eng, 2015; 8(5): 151－161.

structural analysis, regular mesh, equivalent truss structure model, discretized element, energy method

Abdalla M, Gurdal Z. Structural design using optimality based cellular automata. Proc., 43th AIAA/ASME/AHS/ASC Structures, Structural Dynamics and Material Conf., 22-25 April, Denver, CO, USA, 2002; AIAA-2002-1676.

Chu D N, Xie Y M, Hira A, Steven G P. Evolutionary topology optimization of structures subject to displacement. Proc., the Australian Conf. on Structural Optimization, 11-13 February, Sydney, Australia, 1998; 419–426.

Gurdal Z, Tatting B. Cellular automata for design of truss structures with linear and nonlinear response. Proc., 41st AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conf., 3-6 April, Atlanta, GA, USA, 2000; AIAA-2000-1580.

Inou N, Shimotai N, Uesugi T. A cellular automaton generating topological structures. Proc., SPIE 2361, Second European Conf. on Smart Structures and Materials, 13 September, Glasgow, Britain, 1994; 47–50. doi: http://dx.doi.org/10.1117/12.184866.

Inou N, Uesugi T, Iwasaki A, Ujihashi S. Self-organization of mechanical structure by cellula automata. Key. Eng. Mat., 1998; 145–149, 1115-1120. doi: http://dx.doi.org/ 10.4028/www.scientific.net/KEM.145-149.1115.

Kita E, Toyoda T. Structural design using cellular automata. Struct. Multidiscip. O., 2000; 19(1): 64–73. doi: http://dx.doi. org/10.1007/s001580050086.

Levy S. Artificial life: the quest for a new creation, New

York: Pantheon Books. 1992; 390 p.

Missoum S, Abdalla M, Gurdal Z. Nonlinear topology design of trusses using cellular automata. Proc., 44th AIAA/ASME/AHS/ASC Structures, Structural Dynamics and Material Conf., 7-10 April, Norfolk, VA, USA, 2003; AIAA-2003-1445.

Setoodeh S, Abdalla M, Gurdal Z. Combined topology and fiber path design of composite layers using cellular automata. Struct. Multidiscip. O., 2005; 30(6): 413–421. doi: http://dx.doi.org/10.1007/s00158-005-0528-y.

Tatting B, Gurdal Z. Cellular automata for design of two-dimensional continuum structures. Proc., 8th AIAA/USAF/NASA/ISSMO Symp. on Multidisciplinary Analysis and Optimization, 6-8 September, Long Beach, CA, USA, 2000; AIAA-2000-4832.

Tovar A, Patel N, Kaushik A K, Letona G A, Renaud J E. Hybrid Cellular Automata: a biologically-inspired structural optimization technique. Proc., 10th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conf., 30 August - 1 September, Albany, NY, USA, 2004; AIAA-2004-4558.

Waldrop M M. (1992). Complexity: the emerging science at the edge of order and chaos, New York: Simon and Schuster. 380 p.

Young V, Querin Q M, Steven G P, Xie Y M. 3D bi-directional evolutionary structural optimization (BESO). Proc., the Australian Conf. on Structural Optimization, 11-13 February, Sydney, Australia, 1998; p.275–282.

Zakhama R, Abdalla M M, Smaoui H, Gurdal Z. Topology design of geometrically nonlinear 2D elastic continua using CA and an equivalent truss model. Proc., 11th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conf., 6-8 September, Portsmouth, VA, USA, 2006; AIAA-2006-6972.

Zhao C, Steven G P, Xie Y M. Effect of initial nondesign domain on optimal topologies of structures during natural frequency optimization. Comput. Struct., 1997; 62(1): 119–131. doi: http://dx.doi.org/10.1016/S0045-7949(96) 00204-0.