Journal of Textile Research ›› 2020, Vol. 41 ›› Issue (10): 74-80.doi: 10.13475/j.fzxb.20191203007

• Textile Engineering • Previous Articles     Next Articles

Energy dissipation evolution of jute fabric/polyethylene composite under cyclic stress relaxation

WANG Zexing(), WU Bo, LI Shuai, HE Bin   

  1. College of Textile and Fashion, Hunan Institute of Engineering, Xiangtan, Hunan 411104, China
  • Received:2019-12-12 Revised:2020-03-07 Online:2020-10-15 Published:2020-10-27

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Abstract:

In order to investigate the energy dissipation characteristics of jute fiber reinforced thermoplastic composite under complex stress conditions, jute fabric/polyethylene composites were prepared using hot pressing with jute fabric as reinforcement and polyethylene film as matrix. The mechanical properties under cyclic stress relaxation were tested,and the effects of stress relaxation time, peak cyclic stress and cyclic number on evolution of the strain energy (total strain energy, elastic strain energy, plastic strain energy) and strain energy factor (recoverable and unrecoverable strain energy factor) were also analyzed. The results show that deformation mechanism and energy dissipation evolution of warp and fill specimen have good agreement. The strain energy and strain energy factor are governed by stress relaxation time, peak cyclic stress, and as well as cyclic number. Moreover, it is found that the elastic strain energy under cyclic stress relaxation is different from that under simple cyclic loading without stress relaxation.

Key words: jute fabric, polyethylene, cyclic stress relaxation, strain energy, energy dissipation

CLC Number: 

  • TS101.923

Fig.1

Stress and strain curves of warp and fill specimens"

Fig.2

First cycle of warp and fill specimens"

Fig.3

Strain energy(a) and strain energy factor(b) of warp and fill specimens"

Fig.4

Strain energy curves at different stress relaxation time. (a) Total strain energy; (b) Elastic strain energy; (c) Plastic strain energy"

Fig.5

Strain energy factor curves at different stress relaxation time. (a) Recoverable strain energy factory; (b) Unrecoverable strain energy factory"

Fig.6

First cycle of warp specimens at different stress relaxation time"

Fig.8

Curves of strain energy at different peak cyclic stress. (a) Total strain energy; (b) Elastic strain energy; (c) Plastic strain energy"

Fig.8

Curves of strain energy factor at different peak cyclic stress. (a) Recoverable strain energy factory; (b) Unrecoverable strain energy factory"

Fig.9

First cyclic of warp specimens at various peak cyclic stress"

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