Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber

Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber

This paper has proposed a fractional K-BKZ numerical model by adopting the framework of the classical K-BKZ model and the relaxation modulus of the fractional Maxwell model with quasiproperties to study the start-up flow of a viscoelastic shock absorber. The start-up flows in both the orifice and th...

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Main Authors: Baoquan Mao, Zhiqian Wang, Yuying Yang, Rui Zhu, Qijin Zhao, Bowen Zheng
Format: Article
Language:English
Published: Hindawi Limited 2020-01-01
Series:Mathematical Problems in Engineering
Online Access:http://dx.doi.org/10.1155/2020/5412361
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spelling doaj-6de70f9ed3f2464a93e0e03b3a2e587e2020-11-25T01:33:24ZengHindawi LimitedMathematical Problems in Engineering1024-123X1563-51472020-01-01202010.1155/2020/54123615412361Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock AbsorberBaoquan Mao0Zhiqian Wang1Yuying Yang2Rui Zhu3Qijin Zhao4Bowen Zheng5Department of Weapons and Control Engineering, Army Academy of Armored Forces, Beijing 100072, ChinaDepartment of Weapons and Control Engineering, Army Academy of Armored Forces, Beijing 100072, ChinaDepartment of Weapons and Control Engineering, Army Academy of Armored Forces, Beijing 100072, ChinaDepartment of Weapons and Control Engineering, Army Academy of Armored Forces, Beijing 100072, ChinaDepartment of Weapons and Control Engineering, Army Academy of Armored Forces, Beijing 100072, ChinaDepartment of Weapons and Control Engineering, Army Academy of Armored Forces, Beijing 100072, ChinaThis paper has proposed a fractional K-BKZ numerical model by adopting the framework of the classical K-BKZ model and the relaxation modulus of the fractional Maxwell model with quasiproperties to study the start-up flow of a viscoelastic shock absorber. The start-up flows in both the orifice and the gap of a shock absorber were simplified to unidirectional accelerated flows in a pipe and between two parallel plates where one plate is accelerating and the other is at rest. The fractional K-BKZ numerical model was then developed using the finite difference method with real-world initial and boundary conditions. Numerical simulation was then performed, and the results were validated through laboratory testing, based on a comparison of the maximum fluid level and the contact angle. The proposed fractional K-BKZ numerical model successfully simulated the characteristics of the viscoelastic material passing through the orifice or the gap of a shock absorber, as demonstrated by accurately capturing the change of the shape of the flow. This fractional K-BKZ numerical model provided better accuracy for the fluid’s viscoelasticity and can be used for shock absorber design.http://dx.doi.org/10.1155/2020/5412361
collection DOAJ
language English
format Article
sources DOAJ
author Baoquan Mao
Zhiqian Wang
Yuying Yang
Rui Zhu
Qijin Zhao
Bowen Zheng
spellingShingle Baoquan Mao
Zhiqian Wang
Yuying Yang
Rui Zhu
Qijin Zhao
Bowen Zheng
Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber
Mathematical Problems in Engineering
author_facet Baoquan Mao
Zhiqian Wang
Yuying Yang
Rui Zhu
Qijin Zhao
Bowen Zheng
author_sort Baoquan Mao
title Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber
title_short Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber
title_full Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber
title_fullStr Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber
title_full_unstemmed Fractional K-BKZ Numerical Model of the Start-Up Flow for a Viscoelastic Shock Absorber
title_sort fractional k-bkz numerical model of the start-up flow for a viscoelastic shock absorber
publisher Hindawi Limited
series Mathematical Problems in Engineering
issn 1024-123X
1563-5147
publishDate 2020-01-01
description This paper has proposed a fractional K-BKZ numerical model by adopting the framework of the classical K-BKZ model and the relaxation modulus of the fractional Maxwell model with quasiproperties to study the start-up flow of a viscoelastic shock absorber. The start-up flows in both the orifice and the gap of a shock absorber were simplified to unidirectional accelerated flows in a pipe and between two parallel plates where one plate is accelerating and the other is at rest. The fractional K-BKZ numerical model was then developed using the finite difference method with real-world initial and boundary conditions. Numerical simulation was then performed, and the results were validated through laboratory testing, based on a comparison of the maximum fluid level and the contact angle. The proposed fractional K-BKZ numerical model successfully simulated the characteristics of the viscoelastic material passing through the orifice or the gap of a shock absorber, as demonstrated by accurately capturing the change of the shape of the flow. This fractional K-BKZ numerical model provided better accuracy for the fluid’s viscoelasticity and can be used for shock absorber design.
url http://dx.doi.org/10.1155/2020/5412361
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AT zhiqianwang fractionalkbkznumericalmodelofthestartupflowforaviscoelasticshockabsorber
AT yuyingyang fractionalkbkznumericalmodelofthestartupflowforaviscoelasticshockabsorber
AT ruizhu fractionalkbkznumericalmodelofthestartupflowforaviscoelasticshockabsorber
AT qijinzhao fractionalkbkznumericalmodelofthestartupflowforaviscoelasticshockabsorber
AT bowenzheng fractionalkbkznumericalmodelofthestartupflowforaviscoelasticshockabsorber
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