Analysis of Compressive Mechanics Properties of Body Centered Cubic Lattice with Pillars in Different Reinforcement Directions and Their Filling Structures

doi:10.3969/j.issn.1004-132X.2024.09.014

Abstract

Abstract: To study the compressive mechanics properties of pillar centered cubic lattice with different reinforcement directions and their filling structures, silicone rubber filled lattice structure test specimens were prepared herein. The compressive mechanics properties of two lattice structures(BCC1 or BCC2, loading direction was either the same or perpendicular to the direction of pillar rod in body centered cubic lattice with pillars) filled with silicone rubber were studied through experimental and simulation methods. The equivalent elastic modulus and compressive platform stress of two lattice structures were conducted using Timoshenko beam theory and ultimate load method. The results indicate that the proposed theoretical model may effectively predict the equivalent elastic modulus and compressive platform stress of two type lattice structures. After filling, the compression strength and energy absorption performance of the two lattice structures are enhanced, while the enhancement effect of the BCC2 structure is more significant. For the BCC1 lattice, rubber filling enhances the bearing capacity of the internal members. However, for the BCC2 lattice structure, rubber filling reduces the bending deformation of the members near the V-shaped shear band. As the radius of the lattice structure increases, the energy absorption coupling factors of both lattice structures first increase and then decrease, yet the energy absorption coupling factor of BCC1 type structure changes more significantly.

Key words: mechanics property, lattice structure, , equivalent elastic modulus, filling structure

摘要： 为研究不同增强方向的带支柱体心立方点阵及其填充结构的压缩力学性能，制备了硅橡胶填充点阵结构试验件。通过试验和仿真方法研究了硅橡胶填充BCC1或BCC2（加载方向分别与带支柱体心立方点阵的支柱杆方向相同或垂直）两种点阵结构的压缩力学性能，并采用铁摩辛柯梁理论和极限载荷法分析了两种点阵结构的等效弹性模量和压缩平台应力。结果表明：提出的理论模型能够很好地预测两种点阵结构的等效弹性模量和压缩平台应力。经过填充后两种点阵结构的压缩强度和吸能性能均会得到增强，BCC2结构的增强效果更加显著。对于BCC1点阵结构，填充提高了其内部杆件的承载力；而对于BCC2点阵结构，填充减小了其“V”形剪切带附近的杆件弯曲变形。随着点阵结构半径的增大，两种结构的吸能耦合因子均先增大后减小，而BCC1型结构的吸能耦合因子变化更明显。

关键词: 力学性能, 点阵结构, 等效弹性模量, 填充结构

CLC Number:

TB12

ZHANG Wukun1, 2, ZHAO Jian2, TAN Yonghua1, 2, GAO Yushan1, 2, WANG Jun1, 2, HAN Ziyue3, GENG Xiaoliang4. Analysis of Compressive Mechanics Properties of Body Centered Cubic Lattice with Pillars in Different Reinforcement Directions and Their Filling Structures[J]. China Mechanical Engineering, 2024, 35(09): 1642-1652.

张武昆1, 2, 赵剑2, 谭永华1, 2, 高玉闪1, 2, 王珺1, 2, 韩子月3, 耿小亮4. 不同增强方向的带支柱体心立方点阵及其填充结构的压缩力学性能分析[J]. 中国机械工程, 2024, 35(09): 1642-1652.

References

［1］LIU J, SUN Q, ZHOU C, et al. Achieving Ti6Al4V Alloys with Both High Strength and Ductility via Selective Laser Melting［J］. Materials Science and Engineering:A， 2019,766:138319.
［2］刘学, 杨海威, 周伟星, 等. 燃烧室内壁面发汗冷却数值模拟研究［J］.火箭推进,2021,47(4):30-36.
LIU Xue, YANG Haiwei, ZHOU Weixing, et al. Numerical Simulation Research on Transpiration Cooling on the Inner Wall of Combustion Chamber［J］. Journal of Rocket Propulsion, 2021,47(4):30-36.
［3］QI C, JIANG F, YANG S. Advanced Honeycomb Designs for Improving Mechanical Properties:a Review［J］. Composites Part B:Engineering, 2021,227:109393.
［4］JIANG W, YIN G, XIE L, et al. Multifunctional 3D Lattice Metamaterials for Vibration Mitigation and Energy Absorption［J］. International Journal of Mechanical Sciences, 2022,233:107678.
［5］谭永华, 赵剑, 张武昆, 等. 融合增材制造的液体火箭发动机创新设计方法与应用［J］. 火箭推进. 2023, 49(4):1-16.
TAN Yonghua, ZHAO Jian, ZHANG Wukun, et al. Innovative Design Method and Application of Liquid Rocket Engine Integrated Additive Manufacturing［J］. Journal of Rocket Propulsion，2023,49(4):1-16.
［6］GU D D, SHI X Y, POPRAWE R, et al. Material Structure Performance Integrated Laser-metal Additive Manufacturing［J］. Science, 2021,372(6545):eabg1487.
［7］LEE K W, LEE S H, NOH K H, et al.Theoretical and Numerical Analysis of the Mechanical Responses of BCC and FCC Lattice Structures［J］. Journal of Mechanical and Technology, 2019, 33(5):1-8.
［8］WANG P, YANG F, LI P, et al. Bio-inspired Vertex Modified Lattice with Enhanced Mechanical Properties［J］. International Journal of Mechanical Sciences,2023,244:108081.
［9］ZHANG X Y, ZHOU H, SHI W H, et al. Vibration Tests of 3D Printed Satellite Structure Made of Lattice Sandwich Panels［J］. AIAA Journal, 2018, 56(10):4213-4217.
［10］张龙, 李昂, 赵云鹏, 等. 一种全封闭蒙皮点阵支撑结构的优化设计与试验验证［J］. 机械工程学报, 2021,57(22):35-42.
ZHANG Long, LI Ang, ZHAO Yunpeng, et al. Optimal Design and Experimental Verification of an Enclosed Skin Lattice Support Structure［J］. Journal of Mechanical Engineering, 2021,57(22):35-42.
［11］GUMRUK R, MINES R A W, KARADENIZ S, et al. Static Mechanical Behaviors of Stainless Steel Micro-lattice Structures under Different Loading Conditions［J］. Materials Science and Engineering A, 2013, 586:392-406.
［12］LEI H S, LI C L, MENG J X, et al. Evaluation of Compressive Properties of SLM-fabricated Multi-layer Lattice Structures by Experimental Test and μ-CT-based Finite Element Analysis［J］. Materials and Design,2019, 169:107685.
［13］任利民, 戴宁, 程筱胜, 等. 点阵结构填充模型的边界强化设计方法［J］. 中国机械工程,2021,32(5):594-599.
REN Limin, DAI Ning，CHENG Xiaosheng, et al. Method of Boundary Strengthening Design for Lattice Structure Filling Mode［J］. China Mechanical Engineering,2021,32(5):594-599.
［14］USHIJIMA K, CANTWELL W J, MINES R A W, et al. An Investigation into the Compressive Properties of Stainless Steel Micro-lattice Structures［J］. Journal of Sandwich Structures and Materials,2010,13(3):302-329.
［15］YANG Y H, SHAN M J, ZHAO L B, et al. Multiple Strut-deformation Patterns Based Analytical Elastic Modulus of Sandwich BCC Lattices［J］. Materials and Design, 2019, 181:107916.
［16］HAN B, ZHANG Z J, ZHANG Q C, et al.Recent Advances in Hybrid Lattice-cored Sandwiches for Enhanced Multifunctional Performance［J］. Extreme Mechanics Letters，2017，10:58-69.
［17］OSMAN M, SHAZLY M, EL-DANAF E, et al. Compressive Behavior of Stretched and Composite Microlattice Metamaterial for Energy Absorption Applications［J］. Composites Part B，2020，184:107715.
［18］ZHANG G Q, WANG B , MA L ,et al. Energy Absorption and Low Velocity Impact Response of Polyurethane Foam Filled Pyramidal Lattice Core Sandwich Panels［J］.Composite Structures, 2014, 108:304-310.
［19］KAO Y T, AMIN A R, PAYNE N, et al.Low-velocity Impact Response of 3D-printed Lattice Structure with Foam Reinforcement［J］. Composite Structures，2018，192:93-100.
［20］WANG H, LI S, LIU Y, et al.Foam-filling Techniques to Enhance Mechanical Behaviors of Woven Latticetruss Sandwich Panels［J］. Journal of Building Engineering，2021，40:102383.
［21］TAGHIPOOR H, EYVAZIAN A, MUSHARAVATI F, et al. Experimental Investigation of the Three-point Bending Properties of Sandwich Beams with Polyurethane Foam-filled Lattice Cores［J］. Structures，2020，28:424-432.
［22］ROSTAMIYAN Y, NOROUZI H. Flatwise Compression Strength and Energy Absorption of Polyurethane Foam-filled Lattice Core Sandwich Panels［J］. Strength of Materials，2016，48(6):801-810.
［23］PASQUALE G D, SIBONA S. Hybrid Materials Based on Polymers-filled AM Steel Lattices with Energy Absorption Capabilities［J］. Mechanics of Advanced Materials and Structures，2021，29(18):1871536.
［24］WANG P, YANG F, FAN H L, et al.Bio-inspired Multi-cell Tubular Structures Approaching Ideal Energy Absorption Performance［J］. Materials & Design,2023,225:111495.
［25］GENG X L, MA L Y, LIU C, et al. A FEM Study on Mechanical Behavior of Celluar Lattice Materials Based on Combined Elements［J］. Materials Science & Engineering A, 2018, 712:188-198.
［26］ZHU J H, ZHOU H, WANG C, et al. A Review of Topology Optimization for Additive Manufacturing:Status and Challenges［J］. Chinese Journal of Aeronautics, 2021, 34(1):91-110.
［27］郭怡东, 马玉娥, 李佩谣. 增材制造钛合金微桁架夹芯板低速冲击响应［J］. 航空学报， 2021,42(2):423820.
GUO Yidong,MA Yue, LI Peiyao. Low Velocity Impact Response of Additively Manufactured Titanium Alloy Micro-truss Sandwich Panels［J］. Acta Aeronautica et Astronautica Sinica, 2021,42(2):423820.
［28］MARLOW R. A General First-invariant Hyperelastic Constitutive Model［C］∥Constitutive Models for Rubber. London, 2003:157-160.
［29］KOHSAKA K, USHIJIMA K, CANTWELL W J. Study on Vibration Characteristics of Sandwich Beam with BCC Lattice Core［J］. Materials Science and Engineering B, 2021, 264:114986.
［30］DENG J Q, LI X, LIU Z F, et al. Compression Behavior of FCC- and BCB-architected Materials:Theoretical and Numerical Analysis［J］. Acta Mechanica, 2021, 232:4133-4150.
［31］WANG P, YANG F, LI P H, et al. Design and Additive Manufacturing of a Modified Face-centered Cubic Lattice with Enhanced Energy Absorption Capability［J］. Extreme Mechanics Letters,2021,47:101358.
［32］BAI L, GONG C, CHEN X, et al. Mechanical Properties and Energy Absorption Capabilities of Functionally Graded Lattice Structures:Experiments and Simulations［J］. International Journal of Mechanical Sciences, 2020,182:105735.

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