Influence of Strain Rate on Stress-Strain Behavior of Carbon Black Filled Styrene Butadiene Rubber Vulcanizate

doi:10.19894/j.issn.1000-0518.230385

Chinese Journal of Applied Chemistry ›› 2024, Vol. 41 ›› Issue (7): 959-965.DOI: 10.19894/j.issn.1000-0518.230385

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Influence of Strain Rate on Stress-Strain Behavior of Carbon Black Filled Styrene Butadiene Rubber Vulcanizate

Lian-Chao ZHU¹(), Wen-Cang SHI²

^1.Shanghai Anlun Chemical Co. ，Ltd. ，Shanghai 210210，China
^2.Shanxi Anlun Chemical Co. ，Ltd. ，Hejin 043301，China

Received:2023-12-11 Accepted:2024-04-03 Published:2024-07-01 Online:2024-08-03
Contact: Lian-Chao ZHU
About author:zhulianchao@sxygjh.com

Abstract

Abstract:

The stress-strain behavior of rubber compounds is one of the key items to determine its application performance， and the different service conditions， especially the strain rate， have variable requirements for the performance of rubber compounds. The influence of tension strain rate on the stress-strain behavior of styrene butadiene rubber （SBR） vulcanizates filled with 3 kinds of carbon black was investigated from the point of view of rubber reinforcement. It was found that the stress at a given elongation of any SBR vulcanizate increases with increasing strain rate， and the more reinforcing the carbon black， the higher increment rate the stresses. For any given SBR vulcanizate， the stress increment rate decreases with the increase in strain. As the strain exceeds the critical points， such as 300%， the effect of strain rate on the rate of stress increase is becoming equivalent and independent of carbon black grades. From a filler reinforcement point of view， the tensile modulus of filled vulcanizates in the plateau region is governed by the surface activity of the carbon black. In quasi-static tension test， the networking of carbon black in vulcanizate will be gradually broken with increasing strain， which the break-up is predominantly controlled by strain rather than strain rate.

Key words: Styrene butadiene rubber vulcanizate, Carbon black, Stress-strain behavior, Surface activity, Filler networking

CLC Number:

O631

Lian-Chao ZHU, Wen-Cang SHI. Influence of Strain Rate on Stress-Strain Behavior of Carbon Black Filled Styrene Butadiene Rubber Vulcanizate[J]. Chinese Journal of Applied Chemistry, 2024, 41(7): 959-965.

Figures/Tables 8

Table 1 Colloidal properties of carbon black N330， N660 and N774

Sample	100 COAN/（mL·g^-1）	N₂SA/（m²·g^-1）	Tint/%	D_mean/nm	D_mode/nm	FWHM/nm	FWHM/D_mode
N774	63.1	30.0	56	233	199	204	1.025
N660	74.0	34.8	60	203	156	144	0.923
N330	84.2	74.5	104	101	97	90	0.932

Fig.1 Differential volume distribution （A） and volume fraction by aggregate size （B） of carbon black N330， N660 and N774

Fig.2 Stress-strain （A） and tensile modulus-strain （B） curves of SBR vulcanizate filled with three kinds of carbon black at strain rate of 0.3333 s-1

Fig.3 Bound rubber content of SBR compound filled with different grades of carbon black

Fig.4 Dependence of stress at given elongation on strain rate of four kinds of unfilled （A）， N774 filled （B）， N660 filled （C） and N330 filled （D） SBR vulcanizate

Fig.5 Increment rate of stress at given elongation after strain rate increases to 20 times （0.0333 s-1 to 0.6667 s-1）

Fig.6 Double-logarithmic stress-strain curves of four kinds of SBR vulcanizate at strain rate of 0.3333 s-1

Fig.7 Standard （A） and double-logarithmic （B） stress-strain curves of SBR vulcanizate filled with N330 at different strain rate

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Influence of Strain Rate on Stress-Strain Behavior of Carbon Black Filled Styrene Butadiene Rubber Vulcanizate

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