Simulation and experimental study on the surface morphology and energy lost of the target material under non-overlapping impact of angular particles

doi:10.1016/j.cjche.2020.06.042

Chinese Journal of Chemical Engineering ›› 2021, Vol. 29 ›› Issue (1): 47-56.DOI: 10.1016/j.cjche.2020.06.042

• Fluid Dynamics and Transport Phenomena • Previous Articles Next Articles

Simulation and experimental study on the surface morphology and energy lost of the target material under non-overlapping impact of angular particles

Xuewen Cao, Chenyang Fu, Zhenqiang Xie, Chao Wu, Xiaoyang Sun

College of Pipeline and Civil Engineering, China University of Petroleum(East China), No. 66, West Changjiang Road, Huangdao District, Qingdao 266580, China

Received:2019-12-26 Revised:2020-06-15 Online:2021-04-02 Published:2021-01-28
Contact: Xuewen Cao
Supported by:
The authors acknowledge the financial support from the National Natural Science Foundation of China (China, Grant No. 51874340), the Natural Science Foundation of Shandong Province (China, Grant No. ZR2018MEE004).

Simulation and experimental study on the surface morphology and energy lost of the target material under non-overlapping impact of angular particles

Xuewen Cao, Chenyang Fu, Zhenqiang Xie, Chao Wu, Xiaoyang Sun

College of Pipeline and Civil Engineering, China University of Petroleum(East China), No. 66, West Changjiang Road, Huangdao District, Qingdao 266580, China

通讯作者: Xuewen Cao
基金资助:
The authors acknowledge the financial support from the National Natural Science Foundation of China (China, Grant No. 51874340), the Natural Science Foundation of Shandong Province (China, Grant No. ZR2018MEE004).

Abstract

Abstract: In order to further understand the effect of solid impurities on pipeline wall during erosion, the particle impact process without fluid was extracted for specific study. The effect of multi-impact particles on the wall of pipeline was studied experimentally and simulated. In this experiment, an improved ejection apparatus was implemented to carry out multi-impacts non-overlapping impingement by rhombic particles made of high speed steel(W18Cr4V) on the AA6061 aluminum alloy plate through changing particle angle, incident angle, orientation angle and impact velocity. As a result, each particle's penetration depth was investigated and particles' rebound trajectory can be described through this experiment as well as surface morphology of the target material after impingement. The ductile damage criterion, shear damage criterion and MSFLD damage criterion were jointly implemented in ABAQUS/CAE software to simulate the whole process of collision which proved to be effective by getting consistent result compared with experimental data. It is found that under the condition of continuous non-overlapping impact, the target material produces a small work hardening effect in the impact area by converting kinetic energy of moving particles into internal energy of plate so as to reduce the penetration depth of each impact particle.

Key words: Multi-impact experiment, Angular particle, Surface morphology, Energy lost, ABAQUS/CAE simulation

摘要： In order to further understand the effect of solid impurities on pipeline wall during erosion, the particle impact process without fluid was extracted for specific study. The effect of multi-impact particles on the wall of pipeline was studied experimentally and simulated. In this experiment, an improved ejection apparatus was implemented to carry out multi-impacts non-overlapping impingement by rhombic particles made of high speed steel(W18Cr4V) on the AA6061 aluminum alloy plate through changing particle angle, incident angle, orientation angle and impact velocity. As a result, each particle's penetration depth was investigated and particles' rebound trajectory can be described through this experiment as well as surface morphology of the target material after impingement. The ductile damage criterion, shear damage criterion and MSFLD damage criterion were jointly implemented in ABAQUS/CAE software to simulate the whole process of collision which proved to be effective by getting consistent result compared with experimental data. It is found that under the condition of continuous non-overlapping impact, the target material produces a small work hardening effect in the impact area by converting kinetic energy of moving particles into internal energy of plate so as to reduce the penetration depth of each impact particle.

关键词: Multi-impact experiment, Angular particle, Surface morphology, Energy lost, ABAQUS/CAE simulation

Xuewen Cao, Chenyang Fu, Zhenqiang Xie, Chao Wu, Xiaoyang Sun. Simulation and experimental study on the surface morphology and energy lost of the target material under non-overlapping impact of angular particles[J]. Chinese Journal of Chemical Engineering, 2021, 29(1): 47-56.

References

[1] V.D. Zhibaedov, N.A. Lebedeva, A.A. Osiptsov, K.F. Sin'kov, On the hyperbolicity of one-dimensional models for transient two-phase flow in a pipeline, Fluid Dyn. 51(2016) 56-69.
[2] E. Zhang, D. Zeng, H. Zhu, S. Li, D. Chen, J. Li, Y. Ding, G. Tian, Numerical simulation for erosion effects of three-phase flow containing sulfur particles on elbows in high sour gas fields, Petroleum 4(2018) 158-167.
[3] E. Zhang, D. Zeng, H. Zhu, S. Li, D. Chen, J. Li, Y. Ding, G. Tian, Numerical simulation for erosion effects of three-phase flow containing sulfur particles on elbows in high sour gas fields, Petroleum 4(2017) S2405656117300846.
[4] I. Finnie, Erosion of surfaces by solid particles, Wear 3(1960) 87-103.
[5] D.O. Njobuenwu, M. Fairweather, Modelling of pipe bend erosion by dilute particle suspensions, Comput. Chem. Eng. 42(2012) 235-247.
[6] X. Cao, Simulation and analysis of liquid-solid two-phase flow erosion failure in pipe bends, Surf. Technol. 45(2016) 124-131.
[7] J. Zhang, J. Fan, T. Wang, X. Wang, Experimental study and numerical simulation of erosion wear on high-pressure pipe and tee, International Conference on Pipelines and Trenchless Technology 2013, pp. 927-934.
[8] G.J. Brown, Erosion prediction in slurry pipeline tee-junctions, Appl. Math. Model. (2002) 155-170.
[9] G. Ou, J. Qiu, Z. Zhu, Y. Wang, G. Xu, Fluid-structure interactional numerical simulation of erosion-corrosion failure of reducer in multiphase flow, Chin. J. Theor. Appl. Mech. 42(2008) 197-204.
[10] X. He, L. Xiang, J. Li, Erosion's numerical simulation on different size of reducer, Sci. Technol. Chem. Ind. 23(02) (2015) 20-23.
[11] D.N. Veritas, Erosive Wear in Piping Systems, Det Norske Veritas, Hφvik, Norway, 1996.
[12] Y. Zhang, E.P. Reuterfors, B.S. McLaury, S.A. Shirazi, E.F. Rybicki, Comparison of computed and erosion in water and air flows, Wear 263(2006) 330-338.
[13] K.R. Ahlert, Effects of particle impingement angle and surface wetting on solid particle erosion of aisi 1018 steel, PhD Thesis, The University of Tulsa, 1994.
[14] Y.I.O, K. Okamura, T. Yoshida, Practical estimation of erosion damage caused by solid particle impact. Part 1:effects of impact parameters on a predictive equation, Wear 259(2005) 95-101.
[15] X. Chen, B.S. McLaury, S.A. Shirazi, Application and experimental validation of a Computational Fluid Dynamics (CFD)-based erosion prediction model in elbows and plugged tees, Comput. Fluids 33(2004) 1251-1272.
[16] R. Zhang, H. Liu, C. Zhao, A probability model for solid particle erosion in a straight pipe, Wear 308(2013) 1-9.
[17] Q.H. Mazumder, Prediction of erosion due to solid particle impact in single-phase and multiphase flows, J. Press. Vessel. Technol. 129(2007) 576-582.
[18] J.G.A. Bitter, A study of erosion phenomena part I, Wear 6(1963) 5-21.
[19] A.V. Levy, The platelet mechanism of erosion of ductile metals, Wear 108(1986) 1-21.
[20] I.M. Hutchings, A model for the erosion of metals by spherical particles at normal incidence, Wear 70(1981) 269-281.
[21] R. Sahoo, B.B. Jha, T.K. Sahoo, S. Mantry, Effect of microstructural degradation on solid particle erosion behavior of 2.25Cr-1Mo steel, Tribol. Trans. 57(2014) 679-689.
[22] E. Avcu, S. Fidan, Y. Yıldıran, T. Sinmazcelik, Solid particle erosion behaviour of Ti6Al4V alloy, Tribol. Mater. Surf. Interf. 7(2013) 201-210.
[23] Y. Tirupataiah, B. Venkataraman, G. Sundararajan, The nature of the elastic rebound of a hard ball impacting on ductile, metallic target materials, Mater. Sci. Eng. A 124(1990) 133-140.
[24] M. Papini, J.K. Spelt, The plowing erosion of organic coatings by spherical particles, Wear 222(1998) 38-48.
[25] I.M. Hutchings, R.E. Winter, J.E. Field, Solid particle erosion of metals:the removal of surface material by spherical projectiles, Proc. R. Soc. Lond. A 348(1976) 379-392.
[26] I.M. Hutchings, R.E. Winter, J.E. Field, Solid particle erosion of metals:the removal of surface material by spherical projectiles, Proc. R. Soc. A 348(1976) 379-392.
[27] M. Papini, J.K. Spelt, Impact of rigid angular particles with fully-plastic targets part I:analysis, Int. J. Mech. Sci. 42(2000) 991-1006.
[28] M. Papini, J.K. Spelt, Impact of rigid angular particles with fully-plastic targets part Ⅱ:parametric study of erosion phenomena, Int. J. Mech. Sci. 42(2000) 1007-1025.
[29] S. Dhar, T. Krajac, D. Ciampini, M. Papini, Erosion mechanisms due to impact of single angular particles, Wear 258(2005) 567-579.
[30] M. Papini, S. Dhar, Experimental verification of a model of erosion due to the impact of rigid single angular particles on fully plastic targets, Int. J. Mech. Sci. 48(2006) 469-482.
[31] M. Takaffoli, M. Papini, Finite element analysis of single impacts of angular particles on ductile targets, Wear 267(2009) 144-151.
[32] K. Shimizu, T. Noguchi, Y. Matubara, H. Seitoh, FEM analysis of erosive wear, Cast Metals 11(1999) 515-520.
[33] M. Azimian, P. Schmitt, H.-J. Bart, Numerical investigation of single and multi impacts of angular particles on ductile surface, Wear 342-343(2015) 252-261.
[34] J.J. Monaghan, An introduction to SPH, Comput. Phys. Commun. 48(1988) 89-96.
[35] X. Dong, Z. Li, G. Liu, L. Zhao, X. Zhang, Numerical study of impact behaviors of angular particles on metallic surface using smoothed particle hydrodynamics, Tribol. Trans. 60(2016) 693-710.
[36] X. Dong, G.R. Liu, Z. Li, W. Zeng, A smoothed particle hydrodynamics (SPH) model for simulating surface erosion by impacts of foreign particles, Tribol. Int. 95(2016) 267-278.
[37] L. Xue, T. Wierzbicki, Ductile fracture initiation and propagation modeling using damage plasticity theory, Eng. Fract. Mech. 75(2008) 3276-3293.
[38] H. Hooputra, H. Gese, H. Dell, H. Werner, A comprehensive failure model for crashworthiness simulation of aluminium extrusions, Int. J. Crashworthiness 9(2004) 449-464.
[39] T.Y. Pang, D. Waterson, R. Veltjens, T. Garcia, Nonlinear finite element and postbuckling of large diameter thin walled tubes, Nonlinear Approach. Eng. Appl. (2014) 219-233.
[40] Q. Estrada, D. Szwedowicz, J. Silva-Aceves, T. Majewski, J. Vergara-Vazquez, A. Rodriguez-Mendez, Crashworthiness behavior of aluminum profiles with holes considering damage criteria and damage evolution, Int. J. Mech. Sci. 131-132(2017) 776-791.
[41] M.C. Richardson, The erosion of metals by solid particles-a study using high-speed photography, Intl Congress on High Speed Photography, 1977.

Simulation and experimental study on the surface morphology and energy lost of the target material under non-overlapping impact of angular particles

Simulation and experimental study on the surface morphology and energy lost of the target material under non-overlapping impact of angular particles

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