橡胶粉预处理对橡胶沥青性能影响的研究进展
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摘要
综述了橡胶粉的预处理方法对橡胶沥青性能的影响,分析了脱硫降解(热机械法、化学法、微波辐射法及微生物法),脱硫再生,活性增强(等离子体活化、氧化处理及增容调和)和偶联处理等方法的适用性,并提出了今后的研究方向。
The effect of pretreatment methods of crumb rubber on properties of rubber asphalt was reviewed, the applicability of desulfurization degradation(thermal mechanical method, chemical method, microwave radiation method, microbiological method), desulfurization regeneration, activity enhancing(plasma activation, oxidative treatment, compatibilization), coupling treatment and other methods were introduced with 54 references, and future research directions were also proposed.
The effect of pretreatment methods of crumb rubber on properties of rubber asphalt was reviewed, the applicability of desulfurization degradation(thermal mechanical method, chemical method, microwave radiation method, microbiological method), desulfurization regeneration, activity enhancing(plasma activation, oxidative treatment, compatibilization), coupling treatment and other methods were introduced with 54 references, and future research directions were also proposed.
引文
[1]Adhikari B, De D, Maiti S. Reclamation and recycling of waste rubber[J]. Progress in Polymer Science,2000,25(7):909-948.
[2]Zhou Haiping, Holikatti S, Vacura P. Caltrans use of scrap tires in asphalt rubber products: A comprehensive review[J]. Journal of Traffic and Transportation Engineering,2014,1(1):39-48.
[3]Wang Hainian, You Zhanping, Mills-Beale J, et al. Laboratory evaluation on high temperature viscosity and low temperature stiffness of asphalt binder with high percent scrap tire rubber[J]. Construction and Building Materials,2012,26(1):583-590.
[4]Huang S, Pauli A. Particle size effect of crumb rubber on rheology and morphology of asphalt binders with long-term aging[J]. Road Materials and Pavement Design,2008,9(1):73-95.
[5]Lee S. The effect of crumb rubber modifier on the perfor-mance properties of rubberized binders in HMA pavements[J]. Construction and Building Materials,2008,22(7),1368-1376.
[6]Baumgardner G L, Hardee J R, Negulescu I I, et al. Quantitative analysis of functional polymer in recycled tyre rubber used in modified asphalt binders[J]. Road Materials and Pavement Design,2014,15(1):263-278.
[7]Ding Xunhao, Ma Tao, Zhang Weiguang, et al. Experimental study of stable crumb rubber asphalt and asphalt mixture[J]. Construction and Building Materials,2017,157:975-981.
[8]Nazzal M D, Iqbal M T, Sang S K, et al. Evaluation of the long-term performance and life cycle costs of GTR asphalt pavements[J]. Construction and Building Materials,2016,114:261-268.
[9]Yao Hongru, Zhou Shuai, Wang Shifeng. Structural evolution of recycled tire rubber in asphalt[J]. Journal of Applied Polymer Science,2016,133(6):42954.
[10]Wang Shifeng, Cheng Dingxin, Xiao Feipeng. Recent developments in the application of chemical approaches to rubberized asphalt[J]. Construction and Building Materials,2017,131:101-113.
[11]王仕峰,姚鸿儒,张宏雷,等. 螺杆反应挤出脱硫橡胶技术的研究与应用进展[J]. 中国轮胎资源综合利用,2015,5:43-48.
[12]Asaro L, Gratton M, Seghar S, et al. Recycling of rubber wastes by devulcanization[J]. Resources, Conservation and Recycling,2018,133:250-262.
[13]张广泰,李悦,陈柳灼,等. 废机油活化轿车胎胶粉改性沥青的流变性能[J]. 建筑材料学报,2018(2):320-326.
[14]程国香,沈本贤,张建峰. 表面活化处理胶粉改性沥青的性能[J]. 合成橡胶工业,2009,32(5):387-390.
[15]叶奋,杨思远,吴晓羽,等. 深度降解橡胶改性沥青的流变性能[J]. 建筑材料学报,2016,19(5):945-949.
[16]Wu Xiaoyu, Wang Shifeng, Dong Ruikun. Lightly pyrolyzed tire rubber used as potential asphalt alternative[J]. Construction and Building Materials,2016(112):623-628.
[17]董瑞琨,戚昌鹏,郑凯军, 等. 高温裂解胶粉改性沥青的低温性能试验[J]. 中国公路学报,2017,30(10):32-38.
[18]吴翠,廖小雪,陈荣凤. 废旧橡胶脱硫再生胶的研究现状[J]. 特种橡胶制品,2010,31(5):66-70.
[19]Jana G K, Das C K. Devulcanization of natural rubber vulcanizates by mechano-chemical process[J]. Polymer-Plastics Technology and Engineering,2005,44(8/9):1399-1412.
[20]毛宇. 裂解—聚合法橡胶颗粒改性沥青机理及技术性能研究[D]. 西安:长安大学,2017.
[21]De D, Das A, De D, et al., Reclaiming of ground rubber tire(GRT) by a novel reclaiming agent[J]. European Polymer Journal,2006,42(16):917-927.
[22]Sabzekar M, Chenar M P, Mortazavi S M, et al. Influence of process variables on chemical devulcanization of sulfur-cured natural rubber[J], Polymer Degradation and Stability,2015,118:88-95.
[23]杨进宇. 微波活化胶粉制备橡胶沥青的改性机理研究[D]. 兰州:兰州交通大学,2017.
[24]康爱红. 微波辐射活化胶粉改性沥青作用机理分析[J]. 扬州大学学报(自然科学版),2007(3):74-78.
[25]Garcia P S, De Sousa F D B, De Lima J A, et al. Devulcanization of ground tire rubber: Physical and chemical changes after different microwave exposure times[J]. Express Polymer Letters,2015,9(11):1015-1026.
[26]De Sousa F D B, Scuracchio C H, Hu Guohua, et al. Devulcanization of waste tire rubber by microwaves[J]. Polymer Degradation and Stability,2017,138:169-181.
[27]王彦,董月,夏琳,等. 胶粉的制备和改性方法及应用研究进展[J]. 橡胶科技,2017,15(7):12-16.
[28]王坤,康永. 废胶粉表面微生物脱硫及其改性沥青的性能研究[J]. 橡塑技术与装备,2017,43(3):58-62.
[29]Cui Xiaoxiao, Zhao Suhe, Wang Bingwu. Microbial desulfurization for ground tire rubber by mixed consortium-Sphingomonas sp. and Gordonia sp.[J]. Polymer Degradation and Stability,2016,128:165-171.
[30]卢娜,孙鹏,辛振祥. 开炼机再生废丁基橡胶及再生胶性能[J]. 青岛科技大学学报(自然科学版),2017,38(5):80-84.
[31]Wang Shifeng, Wang Qiang, Wu Xiaoyu, et al. Asphalt modified by thermoplastic elastomer based on recycled rubber[J]. Construction and Building Materials,2015,93:678-684.
[32]何亮,马育,黄晓明,等. 再生胶改性沥青性能及其微观结构研究[J]. 建筑材料学报,2012,15(2):227-231.
[33]尤凤兵. 低温等离子体活化废旧轮胎橡胶粉改进沥青性能研究[D]. 苏州:苏州科技学院,2015.
[34]尤凤兵,田永静,沈菊男,等. 低温等离子体活化胶粉改性沥青的性能[J]. 环境工程学报,2017,11(2):1080-1086.
[35]Pastor-Blas M M, Martín-Martínez J M, Dillard J G. Surface characterization of synthetic vulcanized rubber treated with oxygen plasma[J]. Surface and Interface Analysis,2015,26(5):385-399.
[36]Romero-Sánchez M D, Martín-Martínez J M. Surface modifications of vulcanized SBR rubber by treatment with atmospheric pressure plasma torch[J]. International Journal of Adhesion and Adhesives,2006,26(5):345-354.
[37]薛哲,乔云雁,宋莉芳,等. 过氧化苯甲酰氧化废胶粉在橡胶沥青中的应用[J]. 化学研究与应用,2017,29(7):1089-1093.
[38]陈戈. 基于活化特性的橡胶沥青性能及其改性机理研究[J]. 中外公路,2017,37(1):249-253.
[39]于凯,张琛,王欢,等. 次氯酸钠氧化废轮胎胶粉对改性沥青性能的影响[J]. 环境工程学报,2016,10(1):350-354.
[40]于凯,王欢,韩赫兴,等. 双氧水氧化废轮胎胶粉在改性沥青中的应用[J]. 天津大学学报(自然科学与工程技术版),2014,47(11):949-954.
[41]Cataldo F, Ursini O, Angelini G. Surface oxidation of rubber crumb with ozone[J]. Polymer Degradation and Stability,2010,95(5):803-810.
[42]Cao Xianwu, Luo Jun, Cao Yu, et al. Structure and properties of deeply oxidized waster rubber crumb through long time ozonization[J]. Polymer Degradation and Stability,2014,109:1-6.
[43]何东坡,王浩. 柴油活化橡胶粉制备橡胶沥青路用性能研究[J]. 路基工程,2013(1):14-17.
[44]何东坡,王浩. 汽油活化橡胶粉制备的橡胶沥青路用性能研究[J]. 中外公路,2013,33(4):288-291.
[45]杨平文,袁斌,南兵章. 醛糠抽出油对橡胶沥青性能的影响[J]. 公路交通科技(应用技术版),2015,11(12):137-138.
[46]Shatanawi K M, Biro S, Geiger A, et al. Effects of furfural activated crumb rubber on the properties of rubberized asphalt[J]. Construction and Building Materials,2012,28(1):96-103.
[47]王歌. 基于活化技术的高掺量橡胶沥青性能[D]. 重庆:重庆大学,2013.
[48]程国香,陆小军,沈本贤. FCC油浆提高废胶粉改性沥青热存储稳定性试验[J]. 炼油技术与工程,2006(6):10-12.
[49]卢娜,辛振祥. 偶联剂改性废轮胎胶粉及其在力车胎胎侧胶中的应用[J]. 青岛科技大学学报(自然科学版),2017,38(3):93-98.
[50]曹卫东,刘树堂,房建果,等. 硅烷偶联剂对橡胶沥青性能的影响[J]. 建筑材料学报,2009,12(4):497-500.
[51]Dong Qiao, Huang Baoshan, Shu Xiang. Rubber modified concrete improved by chemically active coating and silane coupling agent[J]. Construction and Building Materials,2013,48(19):116-123.
[52]张文清,李承成,刘德仁. 活化橡胶改性沥青路用性能研究[J]. 硅酸盐通报,2017,36(S 1):138-143.
[53]王浩. 活化橡胶沥青及混合料路用性能研究[D]. 哈尔滨:东北林业大学,2013.
[54]解建光,钱春香,傅大放,等. 表面活化处理的废胶粉用于改性热拌沥青混合料[J]. 公路,2004(4):101-105.
[2]Zhou Haiping, Holikatti S, Vacura P. Caltrans use of scrap tires in asphalt rubber products: A comprehensive review[J]. Journal of Traffic and Transportation Engineering,2014,1(1):39-48.
[3]Wang Hainian, You Zhanping, Mills-Beale J, et al. Laboratory evaluation on high temperature viscosity and low temperature stiffness of asphalt binder with high percent scrap tire rubber[J]. Construction and Building Materials,2012,26(1):583-590.
[4]Huang S, Pauli A. Particle size effect of crumb rubber on rheology and morphology of asphalt binders with long-term aging[J]. Road Materials and Pavement Design,2008,9(1):73-95.
[5]Lee S. The effect of crumb rubber modifier on the perfor-mance properties of rubberized binders in HMA pavements[J]. Construction and Building Materials,2008,22(7),1368-1376.
[6]Baumgardner G L, Hardee J R, Negulescu I I, et al. Quantitative analysis of functional polymer in recycled tyre rubber used in modified asphalt binders[J]. Road Materials and Pavement Design,2014,15(1):263-278.
[7]Ding Xunhao, Ma Tao, Zhang Weiguang, et al. Experimental study of stable crumb rubber asphalt and asphalt mixture[J]. Construction and Building Materials,2017,157:975-981.
[8]Nazzal M D, Iqbal M T, Sang S K, et al. Evaluation of the long-term performance and life cycle costs of GTR asphalt pavements[J]. Construction and Building Materials,2016,114:261-268.
[9]Yao Hongru, Zhou Shuai, Wang Shifeng. Structural evolution of recycled tire rubber in asphalt[J]. Journal of Applied Polymer Science,2016,133(6):42954.
[10]Wang Shifeng, Cheng Dingxin, Xiao Feipeng. Recent developments in the application of chemical approaches to rubberized asphalt[J]. Construction and Building Materials,2017,131:101-113.
[11]王仕峰,姚鸿儒,张宏雷,等. 螺杆反应挤出脱硫橡胶技术的研究与应用进展[J]. 中国轮胎资源综合利用,2015,5:43-48.
[12]Asaro L, Gratton M, Seghar S, et al. Recycling of rubber wastes by devulcanization[J]. Resources, Conservation and Recycling,2018,133:250-262.
[13]张广泰,李悦,陈柳灼,等. 废机油活化轿车胎胶粉改性沥青的流变性能[J]. 建筑材料学报,2018(2):320-326.
[14]程国香,沈本贤,张建峰. 表面活化处理胶粉改性沥青的性能[J]. 合成橡胶工业,2009,32(5):387-390.
[15]叶奋,杨思远,吴晓羽,等. 深度降解橡胶改性沥青的流变性能[J]. 建筑材料学报,2016,19(5):945-949.
[16]Wu Xiaoyu, Wang Shifeng, Dong Ruikun. Lightly pyrolyzed tire rubber used as potential asphalt alternative[J]. Construction and Building Materials,2016(112):623-628.
[17]董瑞琨,戚昌鹏,郑凯军, 等. 高温裂解胶粉改性沥青的低温性能试验[J]. 中国公路学报,2017,30(10):32-38.
[18]吴翠,廖小雪,陈荣凤. 废旧橡胶脱硫再生胶的研究现状[J]. 特种橡胶制品,2010,31(5):66-70.
[19]Jana G K, Das C K. Devulcanization of natural rubber vulcanizates by mechano-chemical process[J]. Polymer-Plastics Technology and Engineering,2005,44(8/9):1399-1412.
[20]毛宇. 裂解—聚合法橡胶颗粒改性沥青机理及技术性能研究[D]. 西安:长安大学,2017.
[21]De D, Das A, De D, et al., Reclaiming of ground rubber tire(GRT) by a novel reclaiming agent[J]. European Polymer Journal,2006,42(16):917-927.
[22]Sabzekar M, Chenar M P, Mortazavi S M, et al. Influence of process variables on chemical devulcanization of sulfur-cured natural rubber[J], Polymer Degradation and Stability,2015,118:88-95.
[23]杨进宇. 微波活化胶粉制备橡胶沥青的改性机理研究[D]. 兰州:兰州交通大学,2017.
[24]康爱红. 微波辐射活化胶粉改性沥青作用机理分析[J]. 扬州大学学报(自然科学版),2007(3):74-78.
[25]Garcia P S, De Sousa F D B, De Lima J A, et al. Devulcanization of ground tire rubber: Physical and chemical changes after different microwave exposure times[J]. Express Polymer Letters,2015,9(11):1015-1026.
[26]De Sousa F D B, Scuracchio C H, Hu Guohua, et al. Devulcanization of waste tire rubber by microwaves[J]. Polymer Degradation and Stability,2017,138:169-181.
[27]王彦,董月,夏琳,等. 胶粉的制备和改性方法及应用研究进展[J]. 橡胶科技,2017,15(7):12-16.
[28]王坤,康永. 废胶粉表面微生物脱硫及其改性沥青的性能研究[J]. 橡塑技术与装备,2017,43(3):58-62.
[29]Cui Xiaoxiao, Zhao Suhe, Wang Bingwu. Microbial desulfurization for ground tire rubber by mixed consortium-Sphingomonas sp. and Gordonia sp.[J]. Polymer Degradation and Stability,2016,128:165-171.
[30]卢娜,孙鹏,辛振祥. 开炼机再生废丁基橡胶及再生胶性能[J]. 青岛科技大学学报(自然科学版),2017,38(5):80-84.
[31]Wang Shifeng, Wang Qiang, Wu Xiaoyu, et al. Asphalt modified by thermoplastic elastomer based on recycled rubber[J]. Construction and Building Materials,2015,93:678-684.
[32]何亮,马育,黄晓明,等. 再生胶改性沥青性能及其微观结构研究[J]. 建筑材料学报,2012,15(2):227-231.
[33]尤凤兵. 低温等离子体活化废旧轮胎橡胶粉改进沥青性能研究[D]. 苏州:苏州科技学院,2015.
[34]尤凤兵,田永静,沈菊男,等. 低温等离子体活化胶粉改性沥青的性能[J]. 环境工程学报,2017,11(2):1080-1086.
[35]Pastor-Blas M M, Martín-Martínez J M, Dillard J G. Surface characterization of synthetic vulcanized rubber treated with oxygen plasma[J]. Surface and Interface Analysis,2015,26(5):385-399.
[36]Romero-Sánchez M D, Martín-Martínez J M. Surface modifications of vulcanized SBR rubber by treatment with atmospheric pressure plasma torch[J]. International Journal of Adhesion and Adhesives,2006,26(5):345-354.
[37]薛哲,乔云雁,宋莉芳,等. 过氧化苯甲酰氧化废胶粉在橡胶沥青中的应用[J]. 化学研究与应用,2017,29(7):1089-1093.
[38]陈戈. 基于活化特性的橡胶沥青性能及其改性机理研究[J]. 中外公路,2017,37(1):249-253.
[39]于凯,张琛,王欢,等. 次氯酸钠氧化废轮胎胶粉对改性沥青性能的影响[J]. 环境工程学报,2016,10(1):350-354.
[40]于凯,王欢,韩赫兴,等. 双氧水氧化废轮胎胶粉在改性沥青中的应用[J]. 天津大学学报(自然科学与工程技术版),2014,47(11):949-954.
[41]Cataldo F, Ursini O, Angelini G. Surface oxidation of rubber crumb with ozone[J]. Polymer Degradation and Stability,2010,95(5):803-810.
[42]Cao Xianwu, Luo Jun, Cao Yu, et al. Structure and properties of deeply oxidized waster rubber crumb through long time ozonization[J]. Polymer Degradation and Stability,2014,109:1-6.
[43]何东坡,王浩. 柴油活化橡胶粉制备橡胶沥青路用性能研究[J]. 路基工程,2013(1):14-17.
[44]何东坡,王浩. 汽油活化橡胶粉制备的橡胶沥青路用性能研究[J]. 中外公路,2013,33(4):288-291.
[45]杨平文,袁斌,南兵章. 醛糠抽出油对橡胶沥青性能的影响[J]. 公路交通科技(应用技术版),2015,11(12):137-138.
[46]Shatanawi K M, Biro S, Geiger A, et al. Effects of furfural activated crumb rubber on the properties of rubberized asphalt[J]. Construction and Building Materials,2012,28(1):96-103.
[47]王歌. 基于活化技术的高掺量橡胶沥青性能[D]. 重庆:重庆大学,2013.
[48]程国香,陆小军,沈本贤. FCC油浆提高废胶粉改性沥青热存储稳定性试验[J]. 炼油技术与工程,2006(6):10-12.
[49]卢娜,辛振祥. 偶联剂改性废轮胎胶粉及其在力车胎胎侧胶中的应用[J]. 青岛科技大学学报(自然科学版),2017,38(3):93-98.
[50]曹卫东,刘树堂,房建果,等. 硅烷偶联剂对橡胶沥青性能的影响[J]. 建筑材料学报,2009,12(4):497-500.
[51]Dong Qiao, Huang Baoshan, Shu Xiang. Rubber modified concrete improved by chemically active coating and silane coupling agent[J]. Construction and Building Materials,2013,48(19):116-123.
[52]张文清,李承成,刘德仁. 活化橡胶改性沥青路用性能研究[J]. 硅酸盐通报,2017,36(S 1):138-143.
[53]王浩. 活化橡胶沥青及混合料路用性能研究[D]. 哈尔滨:东北林业大学,2013.
[54]解建光,钱春香,傅大放,等. 表面活化处理的废胶粉用于改性热拌沥青混合料[J]. 公路,2004(4):101-105.
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