• 제목/요약/키워드: Tread compounds

검색결과 27건 처리시간 0.023초

Influence of Loading Procedure of Liquid Butadiene Rubber on Properties of Silica-filled Tire Tread Compounds

  • Jinwoo Seo;Woong Kim;Seongguk Bae;Jungsoo Kim
    • Elastomers and Composites
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    • 제57권4호
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    • pp.129-137
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    • 2022
  • Low molecular weight liquid butadiene rubber (LqBR) is a processing aid that can resolve the migration problem of tire tread compounds. Various studies are being conducted to replace the petroleum-based processing oil with LqBR. However, the effect of the loading time of LqBR in the compounding process on silica dispersion and vulcanizate properties is not well known. In this study, we analyzed silica dispersion, vulcanizate properties, and viscoelastic properties of silica-filled tire tread compound according to the processing aid type (TDAE oil, non-functional LqBR) and, silane terminated LqBR) and input timing. In the non-functional LqBR compounds, the 'with TESPT' mixing procedure showed excellent dynamic viscoelastic properties while silane-terminated LqBR compounds showed that the 'after TESPT' mixing procedure was good for 300% modulus and abrasion resistance.

타이어 트레드 컴파운드와 고무 시멘트 계면의 점착과 접착 특성 (Interfacial Tacky and Adhesive Characteristics between Tire Tread Compounds and Rubber Cement)

  • 송요순;김건옥
    • 공업화학
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    • 제29권4호
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    • pp.399-404
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    • 2018
  • 타이어 트레드 컴파운드와 천연 및 합성 고무 접착제 종류에 따른 가황 전/후의 점착력과 접착력 차이를 비교하였다. 가황 전 점착력은 모든 트레드에서 천연고무 시멘트가 가장 강하고, 시간의 경과에 따른 점착력 감소도 천연고무 시멘트가 합성고무 시멘트보다 낮았다. 가황 전 점착력은 시멘트에 사용된 고무의 유리전이온도에 영향을 받았으며, 천연고무가 합성고무에 비해 시간의 경과에 따른 점착력 감소도 적었다. 가황 후 접착력은 천연고무 시멘트가 천연고무가 주성분인 트레드에 강하게 접착하지만 합성고무가 주성분인 트레드에는 약하게 접착했다. 반면 유화중합 SBR, 용액중합 SBR 시멘트는 모든 트레드 컴파운드에 강하게 접착하였고, 시멘트 고무의 가황 속도가 느릴수록 강한 접착력을 보였다.

Wear Particulate Matters and Physical Properties of Silica filled ENR/BR Tread Compounds according to the BR Contents

  • Ryu, Gyeongchan;Kim, Donghyuk;Song, Sanghoon;Lee, Hyun Hee;Ha, Jin Uk;Kim, Wonho
    • Elastomers and Composites
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    • 제56권4호
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    • pp.243-249
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    • 2021
  • The demand for truck bus radial (TBR) tires with enhanced fuel efficiency and wear resistance have grown in recent years. In addition, as the issue of particulate matter and air pollution increases, efforts are being made to reduce the generation of particulate matter. In this study, we investigated the effect of varying the content of butadiene rubber (BR) on the properties of the rubber compounds and the amount of particulate matter in the TBR tire tread compound. Furthermore, we utilized carbon black in the NR/BR blend compounds owing to its excellent compatibility, and we used silica in the ENR-25/BR blend compounds because it can interact chemically with epoxide groups. The NR/BR blend compounds and the ENR-25/BR blend compounds were evaluated by varying their BR content between 20 phr and 30 phr. The results showed that the ENR-25/BR blend compounds had superior wear resistance than the NR/BR blend compounds. This was caused by the interaction between silica and ENR. In addition, it was confirmed that the increased wear resistance as the BR content increased. Furthermore, compared to the NR/BR blend compounds, ENR-25/BR blend compounds exhibited a lower tan 𝛿 value at 60℃ because silica was used as filler. This indicates a higher fuel efficiency. The measurement results for wear particulate matter showed that as increasing the BR content resulted in generation of less wear particulate matter. This was caused by the increased wear resistance. Moreover, the ENR-25/BR blend compounds with excellent filler-rubber interaction exhibited lower quantities of generated wear particulate matters as compared to the NR/BR blend compounds.

Influence of Blending Method on the Generation of Wear Particulate Matters and Physical Properties in TBR Tire Tread Compounds

  • Sanghoon Song;Junhwan Jeong;Jin Uk Ha;Daedong Park;Gyeongchan Ryu;Donghyuk Kim;Kiwon Hwang;Sungwook Chung;Wonho Kim
    • Elastomers and Composites
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    • 제58권4호
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    • pp.161-172
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    • 2023
  • Because particulate matter has emerged as a major contributor to air pollution, the tire industry has conducted studies to reduce particulate matters from tires by improving tire performance. In this study, we compared the conventional blending method, in which rubber, filler, and additives are mixed simultaneously, to the Y-blending method, in which masterbatches are blended. We manufactured carbon black (CB)-filled natural rubber (NR)/butadiene rubber (BR) blend and silica-filled epoxidized NR/BR blend compounds to compare the effects of the two blending methods on the physical properties of the compounds and the amount of particulate matter generated. The Y-blending method provided uniform filler distribution in the heterogeneous rubber matrix, improved processability, and exhibited low rolling resistance. This method also improved physical properties owing to the excellent filler-rubber interaction. The results obtained from measuring the generation of particulate matter indicated that, the Y-blending method reduced PM2.5 particulate matter generation from the CB-filled and silica-filled compounds by 38% and 60%, and that of PM10 by 29% and 67%, respectively. This confirmed the excellence of the Y-blending method regarding the physical properties of truck bus radial tire tread compounds and reduced particulate matter generated.

Current and Future Trends of Accelerators and Antidegradants for the Tire Industry

  • Hong, Sung-W.
    • Elastomers and Composites
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    • 제34권2호
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    • pp.156-176
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    • 1999
  • Rubber chemicals such as accelerators, antidegradants, vulcanizing agents, processing agents and retarders are very important to the production and protection of tires and rubber goods. The use of accelerators and antidegradants are evaluated in various tire components. This paper will focus on how to vulcanize tires economically and maintain the physical properties of each tire component without severe degradation due to oxygen, heat and ozone. Also, new non-nitrosoamine accelerators and non-staining antiozonants will be discussed. Lastly, the future requirements of antidegradants and accelerators in the tire industry will be reviewed. Tires have been vulcanized with Sulfenamides as primary accelerators and either Guamdine's or Thiurams as secondary accelerators to achieve proper properties at service conditions. However, interior components such as the carcass can be vulcanized with Thiazoles as a primary accelerator to cure faster than the external components. Using the combination of Sulfenamide with secondary accelerators in a tire tread compound and the combination of a Thiazole and Guanidine in a carcass compound will be presented with performance data. Uniroyal Chemical and another Rubber Chemical Manufacturer have developed, "Tetrabenzyl Thiuram Disulfide," (TBzTD) as a non-Nitrosoamine accelerator, which could replace Nitrosoamine generating Thiurams. This new accelerator has been evaluated in a tread compound as a secondary accelerator. Also, Flexsys has developed N-t-butyl-2-benzothiazole Sulfenamide (TBSI) as a non-Nitrosoamine accelerator which could replace 2-(Morpholinothio) -benzothiazole (MBS), a scorch delayed Sulfendamide accelerator. TBSI has been evaluated in a Natural Rubber (NR) belt skim compound vs. MBS. An optimum low rolling resistant cure system has been developed in a NR tread with Dithiomorpholine (DTDM). Also, future requirements for developing accelerators will be discussed such as the replacement of DTDM and other stable crosslink systems. Antidegradants are divided into two different types for use in tire compounds. Internal tire compounds such as apex, carcass, liner, wire breaker, cushion, base tread and bead compounds are protected by antioxidants against degradation from oxygen and heat due to mechanical shear. The external components such as sidewall, chafer and cap tread com-pounds are protected from ozone by antiozonants and waxes. Various kinds of staining and non-staining antioxidants have been evaluated in a tire carcass compound. Also, various para-phenylene diamine antiozonants have been evaluated in a tire sidewall compound to achieve the improved lifetime of the tire. New non-staining antiozonants such as 2, 4, 6-tris-(N-1, 4-dimethylpentyl-p-phenylene diamine) 1, 3, 5 Trizine (D-37) and un-saturated Acetal (AFS) will be discussed in the tire sidewall to achieve better appearance. The future requirements of antidegradants will be presented to improve tire performance such as durability, better appearance and longer lasting tires.

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Effect of Functionalized BR Content on the Wear Particulate Matters and Physical Properties in TBR Tire Tread Compounds

  • Junhwan Jeong;Sanghoon Song;Jin Uk Ha;Daedong Park;Jaeyun Kim;Yeongmin Jung;Donghyuk Kim;Kiwon Hwang;Sungwook Chung;Wonho Kim
    • Elastomers and Composites
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    • 제59권2호
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    • pp.64-72
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    • 2024
  • As air pollution continues to increase owing to increasing traffic centered in urban areas, the tire industry is researching methods to reduce particulate matter. In this study, functionalized lithium butadiene rubber (F-LiBR) was applied to a natural rubber (NR)/butadiene rubber (BR) blend compound often used in truck bus radial (TBR) tire treads. The effect of the functional group that can react with carbon black (CB) in BR was investigated in terms of the dispersion of CB and the compound performance, including the generation of particulate matter. Compounds that were substituted with F-LiBR exhibited enhanced interaction with CB, resulting in excellent filler dispersion. Although F-LiBR exhibited lower crosslinking density and inferior abrasion resistance due to its high vinyl content, the compound with 30 phr of F-LiBR was advantageous in terms of its rolling resistance due to the excellent filler dispersion, which was also effective in reducing the amount of generated particulate matter (up to 56% reduction for PM2.5, and 67% reduction for PM10). The results confirmed the benefits of the introduction of functional groups into TBR tire tread compounds, which can aid in improving the fuel efficiency and reducing particulate matter generation.

Effect of Silica Contents on the Vulcanizates Structure and Physical Properties in ENR/BR Blend Compounds

  • Sanghoon Song;Junhwan Jeong;Donghyuk Kim;Kiwon Hwang;Sungwook Chung;Wonho Kim
    • Elastomers and Composites
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    • 제59권1호
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    • pp.8-16
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    • 2024
  • As regulations on greenhouse gas emission have strengthened globally, the demand for improved fuel efficiency in automobiles continues to rise. In response, the tire industry is actively conducting research to improve fuel efficiency by enhancing tire performance. In this study, silica-filled epoxidized natural rubber (ENR)/butadiene rubber (BR) blend compounds were manufactured according to ENR types and silica contents, and their physical properties and vulcanizate structure were evaluated. ENR-50, which has a higher epoxide content than ENR-25, exhibited stronger filler-rubber interaction, resulting in superior abrasion resistance. In addition, because of its high glass transition temperature (Tg), the wet grip performance of ENR-50 improved, even though the rolling resistance increased. Increasing the amount of silica had little effect on the abrasion resistance due to the increase in filler-rubber interaction and decrease in toughness. In addition, ENR-50 exhibited better wet grip performance; however, the rolling resistance increased. The results indicated that truck bus radial (TBR) tire tread compounds can be designed by applying ENR-50 to improve wear resistance and wet grip performance. In addition, by applying ENR-25 and reducing the silica contents improve fuel efficiency.

가교제 증량이 트레드용 실리카 컴파운드의 물성에 미치는 영향 (Physical Properties of the Silica-Reinforced Tire Tread Compounds by the Increased Amount of Vulcanization Agents)

  • 서병호;김기현;김원호
    • Elastomers and Composites
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    • 제48권3호
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    • pp.201-208
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    • 2013
  • 본 연구는 황과 가교 촉진제의 함량이 달리 적용된 acrylonitrile styrene-butadiene rubber (AN-SBR)/silica 컴파운드가 타이어 트레드 컴파운드의 특성에 미치는 영향에 대해 연구하였다. 실험 결과, 가교제 및 가교촉진제의 함량이 증가할수록 가교 반응성이 증대되어 가교속도 및 컴파운드의 가교도가 상승하였다. 또한 내마모 특성 뿐만 아니라 경도, 모듈러스와 같은 컴파운드의 기계적 특성은 높은 가교도에 기인하여 향상되었다. 동적 점탄 특성에서는 가교도의 증가와 함께 유리전이온도 ($T_g$)가 상승하여 $0^{\circ}C$ 영역에서의 tan ${\delta}$ 값이 향상되었고, $60^{\circ}C$ 영역에서의 tan ${\delta}$ 값이 감소되었다. 초기 가교 속도 ($t_1$)는 $60^{\circ}C$의 tan ${\delta}$ 값과 선형적인 관계를 나타내었다. 이는 가교제의 증량으로 초기 가교 속도 ($t_1$)가 빨라져 조기에 가교가 시작됨으로써 filler network 의 발달을 억제시킨 결과에 따른 것으로 판단된다. 이러한 결과는 AFM (atomic force microscopy)을 통하여 열처리된 컴파운드의 표면 관찰에서도 확인할 수 있었다. 따라서, 빠른 초기 가황 반응에 기인한 실리카의 re-agglomeration 감소는 $60^{\circ}C$에서의 tan ${\delta}$를 결정하는 매우 중요한 변수임을 알 수 있다.

Properties of Silica-SBR Compounds Using Cellulose Dispersant Applicable to Tire Tread Rubber

  • Kim, Jung Soo;Kim, Dong Hyun
    • Elastomers and Composites
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    • 제55권3호
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    • pp.176-183
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    • 2020
  • Silica-styrene butadiene rubber (Silica-SBR) compounds have been used in the preparation of tire treads. The silica dispersibility of silica-SBR compounds is related to the processability, mechanical properties, and wear resistance of tires. Recently, in order to improve the silica dispersibility of the silica-SBR compounds, the wet masterbatch (WMB) process was introduced, which is a method of mixing rubber in the water phase. We aimed to improve the silica dispersibility of the silica-SBR compounds by preparing a silica dispersant applicable to the WMB process. For this purpose, cellulose, 2-hydroxyethyl cellulose, and cellulose acetate were employed as a silica dispersant. The silica dispersibility of the compounds was measured by a moving die rheometer. Improvement in the processability of silica-SBR compounds was evaluated by the Mooney viscometer. The wear resistance of silica-SBR compounds using a cellulose dispersant was improved by up to 29%.

SBR/Organoclay Nanocomposites for the Application on Tire Tread Compounds

  • Kim, Wook-Soo;Lee, Dong-Hyun;Kim, Il-Jin;Son, Min-Jin;Kim, Won-Ho;Cho, Seong-Gyu
    • Macromolecular Research
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    • 제17권10호
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    • pp.776-784
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    • 2009
  • N,N-dimethyldodecylamine (tertiary amine)-modified MMT (DDA-MMT) was prepared as an organically modified layered silicate (OLS), after which styrene-butadiene rubber (SBR) nanocomposites reinforced with the OLS were manufactured via the latex method. The layer distance of the OLS and the morphology of the nanocomposites were characterized by X-ray diffraction (XRD) and transmission electron microscopy (TEM). By increasing the amount of N,N-dimethyldodecylamine (DDA) up to 2.5 g, the maximum values of torque, tensile strength and wear resistance of the SBR nanocomposites were increased due to the increased dispersion of the silicate layers in the rubber matrix and the increased crosslinking of the SBR nanocomposites by DDA itself. When SBR nanocomposites were manufactured by using the ternary filler system (carbon black/silica/OLS) to improve their dynamic properties as a tire tread compound, the tan $\delta$(at $0^{\circ}C$ and $60^{\circ}C$) property of the compounds was improved by using metal stearates instead of stearic acid. The mechanical properties and wear resistance were increased by direct substitution of calcium stearate for stearic acid because the filler-rubber interaction was increased by the strong ionic effect between the calcium cation and silicates with anionic surface. However, as the amount of calcium stearate was further increased above 0.5 phr, the mechanical properties and wear resistance were degraded due to the lubrication effect of the excessive amount of calcium stearate. Consequently, the SBR/organoclay nanocomposites that used carbon black, silica, and organoclay as their ternary filler system showed excellent dynamic properties, mechanical properties and wear resistance as a tire tread compound for passenger cars when 0.5 phr of calcium stearate was substituted for the conventionally used stearic acid.