Kinetics of sulfur vulcanization of NR, BR, SBR, and their blends using a rheometer and DSC

Chough, Sung-Hyo; Chang, Dong-Ho

doi:10.1002/(sici)1097-4628(19960718)61:3<449::aid-app7>3.0.co;2-i

Cited by 107 publications

(130 citation statements)

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“…The sulfur vulcanization with unsaturated rubbers generally occurred through a free radical reaction initiated by accelerator. The resulting sulfur radicals further attack reactive allylic hydrogens in rubber chains to form sulfur crosslinks, and so the vulcanization depends upon the number of the allylic hydrogens [28]. s2 is the time required for the torque value to increase two units from L , which corresponds to the premature vulcanization of rubber compound, while t 90 is the vulcanization time for optimum cure torque [1,3].…”

Section: Characterization Of Unvulcanized Samplesmentioning

confidence: 99%

“…As can be seen, NR exhibited shorter s2 and t 90 than ENR 40 after being cured under the same condition. This is because NR possessed a higher level of unsaturation and reactive sites than ENR 40, and so the crosslinks started and reached the optimum cure torque in a shorter time [1,18,28]. Moreover, the high content of benzylthiuram substituents in the TBzTD accelerator may provide a steric hindrance to the limited crosslink sites of the ENR 40.…”

Section: Characterization Of Unvulcanized Samplesmentioning

confidence: 99%

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Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO₂ Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Raksaksri

Chuayjuljit

Chaiwutthinan

et al. 2017

International Journal of Polymer Science

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This study reported the use of tetrabenzylthiuram disulphide (TBzTD) as a noncarcinogenic accelerator in a traditional sulfur curing system of epoxidized natural rubber (ENR)/nanosilica (nSiO 2 ) composites. ENR used in this work was synthesized via in situ epoxidation of natural rubber (NR) in the presence of performic acid generated from the reaction of formic acid and hydrogen peroxide at 50 ∘ C for 8 h to acquire the epoxide content of about 40 mol%. Accordingly, the resulting ENR was referred to as ENR 40. The curing characteristics, mechanical properties, thermal behaviors, dynamic mechanical properties, and oil resistance of ENR 40/nSiO 2 nanocomposites filled with three loadings of nSiO 2 (1, 2, and 3 parts per hundred parts of rubber) were investigated and compared with NR and neat ENR 40. The results revealed that the scorch and cure times of ENR 40/nSiO 2 nanocomposites were slightly longer than those of NR but slightly shorter than those of ENR 40. The tensile properties and tear strength for both before and after aging of all ENR 40/nSiO 2 nanocomposites were higher than those of ENR 40, while the glass transition temperature, storage modulus at −65 ∘ C, thermal stability, and oil resistance of ENR 40/nSiO 2 nanocomposites were higher than those of NR and ENR 40.

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Section: Characterization Of Unvulcanized Samplesmentioning

confidence: 99%

Section: Characterization Of Unvulcanized Samplesmentioning

confidence: 99%

Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO₂ Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Raksaksri

Chuayjuljit

Chaiwutthinan

et al. 2017

International Journal of Polymer Science

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“…Assumindo que os valores de torque estão diretamente relacionados à densidade de ligações cruzadas e que a cinética é de primeira ordem, uma expressão pode ser escrita em termos de torque [13,14] :…”

Section: Modelo Cinético Generalizadounclassified

“…A combinação da equação de Arrhenius com Equação 1 gera uma conveniente expressão para o cálculo da energia de ativação aparente para o processo de vulcanização. Utilizando-se dados do reômetro a partir de corridas isotérmicas, a diferentes temperaturas, tem-se [13] : Quando se analisa a estrutura dos ácidos graxos envolvidos nesta investigação, a explicação para as diferenças nos valores de k podem ser avaliados. As cadeias de ácidos graxos saturados podem adotar várias conformações que tendem a ser totalmente estendidas, pois isto minimiza as repulsões estéricas entre os grupos metilenos vizinhos.…”

Section: Modelo Cinético Generalizadounclassified

Efeito do Óleo de Linhaça e do Óleo de Amendoim sobre a Vulcanização da Borracha Natural (Nr). Parte I: Modelo Generalizado

BEZERRA¹,

SANTOS²,

Costa³

et al. 2013

Polímeros

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Resumo: O efeito de dois óleos vegetais, óleo de linhaça e óleo de amendoim, em composições de borracha natural (NR) foi avaliado. Um sistema de vulcanização convencional foi escolhido e, após a mistura os parâmetros reométricos (M ℓ , M h , t s1 e t 90 ) foram analisados. A cinética de vulcanização também foi estudada através de um modelo simplificado. A constante de taxa (k) foi determinada em 160° C, 170 °C e 180 °C e a energia de ativação (E a ) global do processo foi estimada. Os resultados experimentais permitem concluir que os óleos sozinhos ou combinados são capazes de atuar como ativadores e, juntamente com os demais ingredientes da composição, de vulcanizar a borracha. No entanto, uma densidade de ligações cruzadas satisfatória só é atingida quando o ácido esteárico está presente. Palavras-chaves: Borracha natural, vulcanização, óleos vegetais. Effect of Linseed Oil and Peanut Oil upon Natural Rubber (NR) Vulcanization. Part I: General ModelAbstract: The effect of two vegetable oils, linseed oil and peanut oil, in natural rubber (NR) compositions was available. A conventional system of vulcanization was chosen and, after the mixtures the rheometer parameters (M ℓ , M h , t s1 e t 90 ) were analyzed. The vulcanization kinetics was also studied through the simplified model. The constant rate (k) was determined at 160 °C, 170 °C and 180 °C, and the global activation energy (E a ) of the process was estimated. Experimental results show that oils alone or combined are capable of acting as activators and, together with the other components, vulcanize rubber. However, an adequate crosslinking density is only reached when stearic acid is present. Keywords: Natural rubber, vulcanization, vegetable oils. IntroduçãoNa indústria da borracha, a preparação de um produto comercial específico requer a seleção de matérias-primas básicas para a obtenção de uma formulação. Em composições elastoméricas usuais, entre os diversos ingredientes, os chamados ativadores são usados. Esses ingredientes formam complexos químicos com os aceleradores e, então, auxiliam na obtenção de maiores taxas de vulcanização e aumento das propriedades finais do vulcanizado [1,2] . Geralmente, os ativadores são compostos inorgânicos (óxido de zinco, óxido de magnésio, entre outros) que atuam em conjunto com compostos orgânicos (aminas, sais de aminas com ácidos fracos, ácidos graxos, entre outros).As quantidades e os tipos em particular de ativadores dependem das quantidades dos outros ingredientes presentes bem como do tipo de acelerador usado [1,2] . Em busca de fontes naturais, renováveis e de baixo custo para a obtenção de matérias-primas, a indústria química, há algum tempo, tem se utilizado dos óleos vegetais e seus derivados. Os principais constituintes dos óleos vegetais são os triacilgliceróis ou triglicerídeos. Os triacilgliceróis podem ser simples, nos quais todos os três grupos acila são os mesmos; ou, mais comumente, mistos onde os grupos acila são diferentes. A hidrólise de uma gordura (triacilgliceróis sólidos à temperatura ambien...

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“…For example, Bideau et al [1] employed a short-wave infrared irradiation, Jaunich et al [2] monitored the vulcanization reaction by using online ultrasonic, Salgueiro et al [3] used SANS and Pazur et al [4] used NMR. Even some utilized DSC to observe the vulcanization reaction including Chough et al [5], Manchado et al [6], and Ding et al [7]. Although a number of methods have been applied to observe the vulcanization reaction, rheometer is still used in industries and research centers, even in Universities as carried out by Cotten [8], Gerspacher et al [9], Mahalling et al [10], Choi [11], Choi et al [12], and Wang et al [13].…”

Section: Introductionmentioning

confidence: 99%

The Effect of Rubber Mixing Process on the Curing Characteristics of Natural Rubber

Hasan¹,

Rochmadi²,

Sulistyo³

et al. 2013

MST

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This research is aimed at studying the relationship between rubber mixing processes and curing characteristics of natural rubber. The curing characteristic analysis was carried out through a natural rubber formula having been masticated and mixed, followed by curing. As many as four mastication methods were finely applied; each respected four sequences of rubber mixing process. In the first method, rubber was masticated for 5 minutes and then rubber chemicals and carbon black N 330 were simultaneously added. In the second and the third methods, rubber was masticated for 1 minute and then carbon blacks and rubber chemicals were also simultaneously added but using different type of fillers. In the fourth method, rubber was masticated for 3 minutes and then rubber chemicals and carbon black were subsequently added. The additions of rubber chemicals and carbon blacks to the masticated rubber were distinguished by the sequence and time allocated for each mixing process. The carbon blacks were added in two stages by which 10 phr was added first and the remaining 40 phr was added later along with oil. In another method, ratios of the carbon blacks addition (as done in the first and the second stages) were 20:30, 30:20, and 40:10. The examination results showed that rubber mixing process gave an impact on the changes of curing characteristics. They were much affected by the method of carbon black addition. The mixing temperature also had an effect on both curing time and curing rate in which the higher the mixing temperature, the lower the curing time and curing rate. Vulcanization temperature also affected the curing time and curing rate in which the higher the vulcanization temperature, the lower the curing time and the higher the curing rate. Lastly, particle size of carbon black also gave an impact on the curing time and curing rate in which the smaller the particle size, the lower the curing time and the higher the curing rate. AbstrakPengaruh Proses Penggilingan Karet terhadap Karakteristik Vulkanisasi Karet Alam. Tujuan penelitian ini adalah untuk mempelajari hubungan antara proses penggilingan karet dan karakteristik vulkanisasi karet alam. Analisis karakteristik vulkanisasi dilakukan dengan merancang formula karet alam yang dimastikasi dan digiling, kemudian diikuti dengan pengamatan reaksi vulkanisasi. Ada empat metode mastikasi yang masing-masing metode diikuti oleh empat urutan proses pencampuran karet. Metode pertama, karet dimastikasi selama 5 menit dan kemudian diikuti penambahan bahan kimia karet dan carbon black N 330 secara simultan. Metode kedua dan ketiga, karet dimastikasi selama 1 menit kemudian carbon black dan bahan kimia karet ditambahkan secara simulan tetapi menggunakan bahan mengisi dengan tipe yang berbeda. Metode keempat, karet dimastikasi selama 3 menit dan kemudian carbon black ditambahkan dahulu lalu diikuti dengan penambahan bahan kimia karet. Penambahan bahan kimia karet dan carbon black ke dalam karet dibedakan atas urutan dan waktu yang dibutuhkan untuk masing-masing proses p...

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Kinetics of sulfur vulcanization of NR, BR, SBR, and their blends using a rheometer and DSC

Cited by 107 publications

References 0 publications

Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO₂ Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO₂ Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Efeito do Óleo de Linhaça e do Óleo de Amendoim sobre a Vulcanização da Borracha Natural (Nr). Parte I: Modelo Generalizado

The Effect of Rubber Mixing Process on the Curing Characteristics of Natural Rubber

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Kinetics of sulfur vulcanization of NR, BR, SBR, and their blends using a rheometer and DSC

Cited by 107 publications

References 0 publications

Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO2 Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO2 Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Efeito do Óleo de Linhaça e do Óleo de Amendoim sobre a Vulcanização da Borracha Natural (Nr). Parte I: Modelo Generalizado

The Effect of Rubber Mixing Process on the Curing Characteristics of Natural Rubber

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Product

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Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO₂ Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance

Use of TBzTD as Noncarcinogenic Accelerator for ENR/SiO₂ Nanocomposites: Cured Characteristics, Mechanical Properties, Thermal Behaviors, and Oil Resistance