High Strain Rate Response of In-Situ TiB2/7055 Composite by Taylor Impact

Li, Hengfu; Yang, Zhenyu; Peng, Rong; Wu, Yi; Hui, Xidong; Zhang, Fengguo; Chen, Zhe; Wang, Haowei

doi:10.3390/ma14020258

Materials

2021

DOI: 10.3390/ma14020258

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High Strain Rate Response of In-Situ TiB2/7055 Composite by Taylor Impact

Hengfu Li

Zhenyu Yang

Rong Peng

et al.

Abstract: The high strain rate deformation behavior and microstructure evolution of in situ TiB2 particle reinforced Al-Zn-Mg-Cu composite were investigated by means of Taylor impact. The dynamic tests were performed at three different impact velocities. Under three different velocities, no obvious shear failure occurred in the composite, indicating a good impact resistance. Compared to the quasi-static compression test, the dynamic yield strength increased obviously with the rise of velocity, even more than 1 GPa. The … Show more

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Cited by 2 publications

References 34 publications

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Determination of dynamic parameters of free vibrating materials (Nizhny Novgorod)

Khazov,

Shkoda,

Tiagunova

2023

Vestnik Tomskogo gosudarstvennogo arhitekturno-stroitelnogo uni

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The most commonly used methods for determination of dynamic properties are expensive and difficult to reproduce without specialised equipment. There is a need to develop simplified techniques that allow to determine specific material properties, avoiding the use of complex laboratory tests.Purpose: The aim of this work is to develop and test a simplified methodology for determining dynamic properties of various materials using pine wood as an example.Methodology: Experimental modelling using up-to-date measuring devices and analytical processing of the obtained results.Research findings: The dynamic modulus of elasticity of pine wood is determined with high accuracy and coincides with reference values. The coefficient of vibration damping is obtained for the calculation of dynamic systems in near-resonance zones.Practical implications: The proposed methodology can be used to determine the dynamic properties of new materials in order to enter these characteristics in software databases and computer complexes.Originality: The proposed method of determining the dynamic parameters of the material is based on the analysis of two-support beam vibrations registered by an accelerometer.

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Determination of dynamic parameters of free vibrating materials (Nizhny Novgorod)

Khazov,

Shkoda,

Tiagunova

2023

Vestnik Tomskogo gosudarstvennogo arhitekturno-stroitelnogo uni

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show abstract

Investigation on the Application of Taylor Impact Test to High-G Loading

Chen

et al. 2021

Front. Mater.

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Taylor impact test is characterized by high impact energy, low cost, and good repeatability, giving it the technical foundation and development potential for application in high-g loading. In this paper, the feasibility of performing high-g load impact testing to a missile-borne recorder by conducting Taylor impact test was studied by combining simulation analyses with experimental verification. Acccording to the actual dimensions of the missile-borne recorder, an experimental piece was designed based on the Taylor impact principle. The impact loading characteristics of the missile-borne recorder were then simulated and analyzed at different impact velocities. In addition, the peak acceleration function and the pulse duration function of the load were fitted to guide the experimental design. A Taylor-Hopkinson impact experiment was also conducted to measure the impact load that was actually experienced by the missile-borne recorder and the results were compared with the results of strain measurements on the Hopkinson incident bar. The results showed that the peak value of impact load, the pulse duration and the waveform of the actual experimental results were in good agreement with the results predicted by the simulations. Additionally, the strain data measured on the incident bar could be used to verify or replace the acceleration testing of the specimen to simplify the experimental process required. Based on the impact velocity, high-g loading impact was achieved with peak values in the 7,000–30,000 g range and durations of 1.3–1 ms, and the waveform generated was a sawtooth wave. The research results provide a new approach for high amplitude and long pulse duration impact loading to large-mass components, and broaden the application field of Taylor impact test.

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High Strain Rate Response of In-Situ TiB2/7055 Composite by Taylor Impact

Cited by 2 publications

References 34 publications

Determination of dynamic parameters of free vibrating materials (Nizhny Novgorod)

Determination of dynamic parameters of free vibrating materials (Nizhny Novgorod)

Investigation on the Application of Taylor Impact Test to High-G Loading

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