[1]张震,郑晓光,房佳仪,等.有氧再生废轮胎橡胶粉的制备与表征[J].合成橡胶工业,2023,2:114-118.
ZHANG Zhen,ZHENG Xiao-guang,FANG Jia-yi,et al.Preparation and characterization of aerobic recycled
waste tire rubber powder[J].China synthetic rubber industy,2023,2:114-118.
点击复制
有氧再生废轮胎橡胶粉的制备与表征
ZHANG Zhen,ZHENG Xiao-guang,FANG Jia-yi,et al.Preparation and characterization of aerobic recycled waste tire rubber powder[J].China synthetic rubber industy,2023,2:114-118.
《合成橡胶工业》[ISSN:1000-1255/CN:62-1036/TQ]
- 期数:
- 2023年2期
- 页码:
- 114-118
- 栏目:
- 加工 · 应用
- 出版日期:
- 2023-03-15
文章信息/Info
- Title:
- Preparation and characterization of aerobic recycled waste tire rubber powder
- 文章编号:
- 1000-1255(2023)02-0114-05
- Author(s):
- ZHANG Zhen1; 2; ZHENG Xiao-guang1; FANG Jia-yi2; MA Lan2; LIU Shuang2; WANG Shi-feng2
- 1. Shanghai Municipal Engineering Design Institute (Group) Co Ltd, Shanghai 200092, China; 2. Research Institute of Polymer Meterials, Shanghai Jiao Tong University, Shanghai 200240, China
- Keywords:
- waste tire rubber powder; aerobic regeneration; regeneration temperature; regeneration time; oxidation reaction
- 分类号:
- TQ 335
- DOI:
- DOI:10.19908/j.cnki.ISSN1000-1255.2023.02.0114
- 文献标识码:
- B
- 摘要:
- 在管式炉中对废轮胎橡胶粉进行了有氧再生,并考察了气氛、再生温度和再生时间对废轮胎橡胶粉有氧再生过程的影响。结果表明,有氧条件下橡胶粉的质量损失和溶胶质量分数均随温度升高而增大,溶胶中合成胶分子链之间易发生二次重组再交联反应,天然橡胶分子链则主要发生断裂。240 ℃下橡胶粉在有氧条件下再生10 min时,溶胶质量分数达55.9%。橡胶主链和交联键断裂主要发生了氧化反应,生成含羰基和亚砜基的化合物,同时伴有水和二氧化碳等生成,说明橡胶粉中的橡胶分子链有效断链。
- Abstract:
- The aerobic regeneration of waste tire rubber powder was carried out in a tubular furnace, and the effects of atmosphere, regeneration temperature and regeneration time on the aerobic regeneration process of waste tire rubber powder were investigated. The results showed that the mass loss and mass fraction of sol of rubber powder increased with the increasing temperature under aerobic conditions. The secondary recombination and re-crosslinking reaction occurred in the molecular chains of synthetic rubber, while the main chain of natural rubber was mainly broken. When the rubber powder was treated under aerobic conditions for 10 min at 240 ℃, the mass fraction of sol reached 55.9%. The fracture of rubber main chain and cross-link bond was mainly broken by oxidation reaction. The aerobic reclamation of waste rubber generated the compounds containing carbonyl and sulfoxide groups, accompanying the formation of water and carbon dioxide. These phenomena indicated that the rubber molecular chain in rubber powder was effectively broken by oxidative reaction.
参考文献/References
[1] Ramarada S, Khalida M, Ratnamb C, et al. Waste tire rubber in polymer blends: A review on the evolution, properties and future[J]. Progress in Materials Science,2015,72(7):100-140. [2] Akhlaghi S, Gedde U, Hedenqvist M, et al. Deterioration of automotive rubbers in liquid biofuels: A review[J]. Renewable and Sustainable Energy Reviews,2015,43(3):1238-1248. [3] Burlakovs J, Kriipsalu M, Klavins M, et al. Paradigms on landfill mining: From dump site scavenging to ecosystem services revitalization[J]. Resources, Conservation and Recycling,2017,123(8):73-84. [4] Asaro L, Gratton M, Seghar S, et al. Recycling of rubber wastes by devulcanization[J]. Resources, Conservation and Recycling,2018,133(6):250-262. [5] Gagol M, Boczkaj G, Haponiuk J, et al. Investigation of volatile low molecular weight compounds formed during continuous reclaiming of ground tire rubber[J]. Polymer Degradation and Stability,2015,119(9):113-120. [6] Machin E, Pedroso D, de Carvalho J. Energetic valorization of waste tires[J]. Renewable and Sustainable Energy Reviews,2017,68(2):306-315. [7] Aoudia K, Azem S, Hocine N. Recycling of waste tire rubber: Microwave devulcanization and incorporation in a thermoset resin[J]. Waste Management,2017,60(2):471-481. [8] Simon D, Pirityi D, Bárány T. Devulcanization of ground tire rubber: Microwave and thermomechanical approaches[J]. Scientific Reports,2020,10(5):16587. [9] Sousa F, Júnior H. From devulcanization of ground tire rubber by microwaves to revulcanization: A revulcanization kinetic approach using a simple prediction model[J]. ACS Sustainable Chemistry & Engineering,2020,43(8):16304-16319. [10] Li Yuanhu, Zhao Suhe, Wang Yaqin, et al. Improvement of the properties of natural rubber/ground tire rubber composites through biological desulfurization of GTR[J]. Journal of Polymer Research,2012,17(4):9864. [11] Tatangelo V, Mangili I, Caracino P, et al. Microbial desulfurization of ground tire rubber (GTR): Characterization of microbial communities and theological and mechanical properties of GTR and natural rubber composites (GTR/NR)[J]. Polymer Degradation & Stability,2019,160(2):102-109. [12] Zhang Zhen, Wan Chaoying, Song Pan, et al. Soybean oil induced efficient thermal-oxidative degradation of covalently crosslinked styrene butadiene rubber[J]. Journal of Applied Polymer Science 2019, 137 (31): 48935 [13] Martínez J, Puy N, Murillo R, et al. Waste tyre pyrolysis——A review[J]. Renewable and Sustainable Energy Reviews,2013,23(7):179-213. [14] Guo Lili, Huang Gguangsu, Zheng Jing, et al. Thermal oxidative degradation of styrene-butadiene rubber (SBR) studied by 2 D correlation analysis and kinetic analysis[J]. Journal of Thermal Analysis and Calorimetry,2013,115(1):647-657. [15] Yang Qirong, Yu Shuangpeng, Zhong Haowen, et al. Gas products generation mechanism during co-pyrolysis of styrene-butadiene rubber and natural rubber[J]. Journal of Hazardous Material,2020,401(1):123302. [16] Zhang Zhen, Zhang Yuxin, Li Jiayi, et al. Accelerated liquefaction of vulcanized natural rubber by thermo-oxidative degradation[J]. Polymer Bulletin,2022,79(2):1767-1786.
备注/Memo
- 备注/Memo:
- 上海市青年科技英才扬帆计划资助项目(20 YF 1445500)
