Corrugated Board UV Flute-Shaped Structure Size Optimization Design Based on the Finite Element

Wei Yuan; Jin Xin Sun; Gai Mei Zhang; Da Zhi Liao; Ya Jun Wang

doi:10.4028/www.scientific.net/AMM.469.213

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 469Corrugated Board UV Flute-Shaped Structure Size...

Corrugated Board UV Flute-Shaped Structure Size Optimization Design Based on the Finite Element

Abstract:

UV-shaped corrugated cardboard Fusion V-shaped and U-shaped structure the advantages made, to make up for the lack of V-type and two U-shaped corrugated cardboard, the higher the compressive strength, good elasticity, is widely used UV type corrugated manufacturing corrugated board. But no strict standards for UV-shaped concrete structure of corrugated board size parameter corresponding corrugating roll no uniform size of the corrugated shape, in order to achieve the best elasticity and compressive strength. First, by mathematical methods, the corrugated structure is analyzed, and analysis to facilitate research, to select the 1/4 cycle corrugated. Create multiple vertical auxiliary line level is divided into 10 equal parts, to identify key points in shape between the V-shaped and U-shaped curve, connecting into multiple segments curve. Studied the actual thickness of the corrugated board of 3.8mm, a smaller thickness and therefore a straight line can be connected to each group of the resultant key points simplify the corrugated curve, model 1/4 of a cycle of UV-shaped corrugated first determined, using the symmetry of the model to establish a cycle, 300mm side length of the square created by one cycle of replication, about 38 of the corrugated board corrugated cycle. Use of finite element analysis in ANSYS corrugated structure, including a gradual transition to a simplified model of the 11 U-shaped flute-shaped corrugated cardboard from the V-shaped set of material properties, loads are cloth pressure, research corrugated cardboard stress and strain, i.e., the smaller the radius of curvature of the curve can be obtained along corrugated, the closer the U-shaped, corrugated board having a larger strain, i.e. has good flexibility, consistent with the empirical data to prove the feasibility of this analysis method.

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Periodical:

Applied Mechanics and Materials (Volume 469)

Pages:

213-216

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.469.213

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Online since:

November 2013

Authors:

Wei Yuan*, Jin Xin Sun, Gai Mei Zhang, Da Zhi Liao, Ya Jun Wang

Keywords:

Finite Element, Numerical Simulation, Optimization, UV Flute-Shaped

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