Deformation Mechanism and Energy Dissipation of Solid Buoyant Material with Different Ratio of Height to Diameter under Uniaxial Compression Loading

doi:10.11901/1005.3093.2017.342

Chinese Journal of Materials Research

2018, Vol. 32

Issue (8): 591-598 DOI: 10.11901/1005.3093.2017.342

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Deformation Mechanism and Energy Dissipation of Solid Buoyant Material with Different Ratio of Height to Diameter under Uniaxial Compression Loading

Zhiyuan MEI¹, Xiaosong ZHOU²(

), Fan WU¹

1 College of Naval Architecture and Ocean Engineering, Naval University of Engineering, Wuhan 430033, China
2 National Academy of Defense Science and Technology Innovation,Academy of Military Sciences PLA China, Beijing 100071, China

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Zhiyuan MEI, Xiaosong ZHOU, Fan WU. Deformation Mechanism and Energy Dissipation of Solid Buoyant Material with Different Ratio of Height to Diameter under Uniaxial Compression Loading. Chinese Journal of Materials Research, 2018, 32(8): 591-598.

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Abstract

In order to understand the deformation mechanism and energy dissipation of solid buoyant material with different ratio of height to diameter under uniaxial compression loading, the desired experimental tests and numerical simulation were conducted. Firstly, the uniaxial compression test of solid buoyant material specimens with five different ratios of H to D is conducted by means of MTS-45 universal testing machine, while the mechanical response characteristics and failure modes are analyzed. Secondly,the simulation model of the solid buoyant material is proposed based on the results of uniaxial compression test and the macroscopic mechanical property of the solid buoyant material is described with ABAQUS finite element software. Results show that the bearing load stress circles of the solid buoyant material expand at the beginning of plateau stage and the dominant deformation mode is plastic compression during the plateau stage. As densification stage starts, the deformation mode transfers from symmetric biconcave disks to asymmetric slip deformation with the increasing ratio of H to D. The solid buoyant material is apt to shear failure, while the amount of absorbed energy of the failure process increases with the decreasing ratio of H to D, which presents plastic shear failure characteristics. On the contrary, with the increasing ratio of H to D, the material is apt to compression fracture failure．

Key words: composite solid buoyant material height to diameter ratio deformation mechanism energy dissipation

Received: 27 May 2017

ZTFLH:

TB332

Fund: Supported by National Natural Science Foundation of China (No. 51479205)

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https://www.cjmr.org/EN/10.11901/1005.3093.2017.342 OR https://www.cjmr.org/EN/Y2018/V32/I8/591

Fig.1 Compression response curves of solid buoyant material in different height to diameter ratios (a) Load- displacement curves (b) Stress-strain curves (c) Local enlarged drawing

Fig.2 Compressive stiffness and initial yield strength curves of solid buoyant material in different height to diameter ratios

Fig.3 Failure modes of solid buoyant material in different height to diameter ratios

Fig.4 Numerical analysis model of solid buoyant material

Table 1 Elastic-plastic data of solid buoyant material

Fig.5 Comparison of experiment and simulation results for solid buoyant material specimens

Fig.6 Deformation comparison of experiment test and numerical simulation results for solid buoyant material (a) H/D=0.56 (b) H/D=1.00 (c) H/D=1.31 (d) H/D=1.63 (e) H/D=2.05

Table 2 Energy absorption distribution of numerical model

Fig.7 Energy absorption component of numerical model (a) Comparision of experiment and simulation (b) Global energy balance of simulation (c) Internal energy balance of simulation

Fig.8 Energy absorption curves of solid buoyant material in different height to diameter ratios (a) Energy-displacement curves (b) Specific energy-strain curves

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