Construction of an in situ interfacial layer for aramid fiber reinforced styrene butadiene rubber composites

Luo, Zhu; Yang, Le; Xiang, Sheng; Li, Xiaolong; Yin, Liang; Yang, Bo

doi:10.1002/app.49420

Cited by 9 publications

(8 citation statements)

References 36 publications

(36 reference statements)

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“…The master batch obtained in this way, the fiber was evenly dispersed in it. [14,15] Thus, according to the formula listed in Table 3, the material consisting of the master batch was mixed with 200 g SBR-CB (containing 100 g CB) using a two-roll mill (XK-160-A, each roller had a diameter of 160 cm, length of 320 cm, and speed ratio of 1:1.22), and the obtained gross rubber was placed for 24 h to eliminate the internal stress of the rubber. [16] Finally the rheometer (M2000FAN, High Speed Rail Technology Co. Ltd., China) was used to determine cure time (tc90) at 150 C, and the gross rubber was cut into a mold-sized template, placed in the mold, and formed it in a press vulcanizer (XLB, 25 t, Jiangdu Pearl Experiment Machine Factory, China) at 150 C for the standard Tc90.…”

Section: Preparation Of the Sbr/af Vulcanized Compositementioning

confidence: 99%

The reinforcement of styrene butadiene rubber composites with simple environmentally friendly aramid fiber modification

Liu

Luo

et al. 2020

Polymer Composites

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The surface treatment of aramid fiber (AF) improved the properties of reinforced composites. However, many AF modification methods were difficult to apply to the mass production of reinforced composites due to drawbacks, such as processes that were complex and not environmentally friendly. This paper described three simple and environmentally friendly methods for AF surface treatment and their effects on the properties of reinforced aramid fiber/carbon black/butadiene benzene ethylene rubber (AF/CB/SBR) composites. The AF was treated by thermal oxidation and coated with butadiene‐styrene‐pyridine rubber latex (VPL) or maleated polybutadiene liquid rubber. Then, AF/CB/SBR composites were produced when the modified AF was introduced into the SBR matrix. The results showed that compared with that of the composite with untreated AF, the interfacial bonding between the modified AF and the rubber matrix was improved, especially for tensile modulus elongations of 100% and 300%, and the tear strength of the composites was enhanced. Compared with those for the rubber composites with the AF treated by thermal oxidation, the mechanical properties of the rubber composites with the coated AF showed a greater improvement, but the heat generation was higher. Moreover, the thermal oxidation method not only improved the constant elongation stress and tear strength but also reduced the heat generation of the materials.

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Section: Preparation Of the Sbr/af Vulcanized Compositementioning

confidence: 99%

The reinforcement of styrene butadiene rubber composites with simple environmentally friendly aramid fiber modification

Liu

Luo

et al. 2020

Polymer Composites

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“…21,22 However, aramid fiber is a rigid material and the surface of aramid fiber is chemically inert and poorly combined with the matrix material. [23][24][25] When subjected to alternating stress, aramid fiber will produce friction with rubber molecular chains and particles in the rubber matrix, causing a lot of heat. Therefore, aramid fiber is necessary to be modified in order to reduce the dynamic heat generation of rubber composites.…”

Section: Introductionmentioning

confidence: 99%

Hybrid enhancement of silica and aramid pulp on improving performance and reducing dynamic heat generation of natural rubber composites

et al. 2023

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The composites with excellent mechanical, low rolling resistance, and low heat build‐up are the potential materials for preparing green tires. In this study, we prepared silica‐natural rubber latex (silica‐NRL) masterbatch, which improved the processing and dispersion properties of silica in the natural rubber, proved by the rheological properties of composites. Furthermore, the idea of partial replacement of silica with low content modified aramid pulp (AP) for preparing hybrid enhanced natural rubber with high mechanical properties and low heat build‐up was put forward and evaluated the feasibility of this strategy. We find that replacing 5 phr silica with 1 phr AP, the performances of the rubber composites were all superior to the composites with only filled 50 phr silica, and replacing 10 phr silica with 2 phr AP, the mechanical and fatigue property was improved remarkably and dynamic heat generation was reduced the most at same time. The strategy of preparing silica‐NRL masterbatch and partial replacement of silica with AP provides a novel reference for the preparation of low heat build‐up green tire.

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“…Compared with SBR/CB filled with high content of CB, a flexible interface layer was constructed on the fiber surface, which was mainly composed of natural rubber not filled with CB with low heat build‐up. It can be co‐vulcanized with matrix SBR rubber to obtain a well‐bonded interface layer 26 . This article tried to apply this coated AP to replace a part of CB in rubber, which provides a new idea for the development of low thermal rubber materials.…”

Section: Introductionmentioning

confidence: 99%

“…It can be co-vulcanized with matrix SBR rubber to obtain a well-bonded interface layer. 26 This article tried to apply this coated AP to replace a part of CB in rubber, which provides a new idea for the development of low thermal rubber materials.…”

Section: Introductionmentioning

confidence: 99%

Reducing dynamic heat build‐up of styrene butadiene rubber/carbon black by filling aramid pulp coated with natural rubber latex

Wang

Luo

et al. 2022

J of Applied Polymer Sci

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The manufacture of green tires with low heat build‐up has attracted extensive attention. Furthermore, the trouble to solve the problem of rubber failure caused by tires dynamic heat build‐up is a great challenge faced by the automotive tire industry. In this article, a method of preparing styrene butadiene rubber/carbon black/aramid pulp‐natural rubber latex (SBR/CB/AP‐NRL) composites was described in detail, which used AP coated with NRL to fill SBR/CB. A flexible interface layer was constructed between fibers and rubber matrix, making for forming a large specific surface area of the NRL. The mechanism of reducing heat build‐up of the rubber composite through “deforming transformation” in the flexible interface layer was discussed. In addition, the NRL interface layer contributed to the dispersion of the AP in the rubber matrix and the good interfacial bonding between AP and the rubber matrix. In the experiment of replacing a part of CB with a certain content of AP‐NRL, it was found that the temperature rise of the rubber composites decreased by 8.33% with 1 phr modified AP replacing 5 phr CB. The strategy of reducing dynamic heat build‐up of rubber composite provides a new idea for the development of green tire.

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Construction of an in situ interfacial layer for aramid fiber reinforced styrene butadiene rubber composites

Cited by 9 publications

References 36 publications

The reinforcement of styrene butadiene rubber composites with simple environmentally friendly aramid fiber modification

The reinforcement of styrene butadiene rubber composites with simple environmentally friendly aramid fiber modification

Hybrid enhancement of silica and aramid pulp on improving performance and reducing dynamic heat generation of natural rubber composites

Reducing dynamic heat build‐up of styrene butadiene rubber/carbon black by filling aramid pulp coated with natural rubber latex

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