冰雪地区橡胶颗粒沥青混合料应用技术的研究
|
摘要
冰雪地区路面行车安全问题一直是困扰道路交通部门的难题,寻求科学有效的路面抑制冰雪技术成为研究的重点。橡胶颗粒沥青混合料是将废旧橡胶轮胎破碎成一定形状和粒径的颗粒,以骨料的形式直接添加于沥青混合料中,用以代替部分集料而形成的新型沥青混合料。由于具有高弹特性的橡胶颗粒的存在,改变了橡胶颗粒沥青路面表面冰雪层的受力状态和冰雪与路面的粘结状态,使橡胶颗粒沥青路面能够有效地抑制路面积雪结冰,从而为季节性冰冻地区的抑制路面冰雪问题提供了新的解决方案。而且,随着废旧橡胶轮胎污染问题的日趋严重,其回收利用技术日益成为研究热点,而橡胶颗粒沥青混合料的应用为废旧橡胶轮胎回收利用提供了有效途径。但是长期以来,对橡胶颗粒沥青混合料技术还缺乏系统的研究。
为此,本论文就橡胶颗粒的技术性质、橡胶颗粒沥青混合料组成设计方法、成型工艺及其除冰雪性能等问题,对橡胶颗粒沥青混合料应用技术进行了系统研究。论文的主要研究工作如下:
⑴橡胶颗粒技术性质的研究。从橡胶颗粒的形状特性、表面特性和力学特性角度入手,分析了橡胶颗粒的技术性质对橡胶颗粒沥青混合料压实特性、体积特性、弹性变形特性和耐久性能等的影响,并最终确定出沥青混合料用橡胶颗粒的技术指标要求。
研究结果表明,橡胶颗粒的形状特性和力学特性对混合料的性能影响较大,随细长扁平颗粒含量的减小,硬度的增大,混合料的压实特性、体积特性和使用的耐久性增强;橡胶颗粒的表面特性的差异对混合料性能有一定影响,但其影响并不显著。
⑵橡胶颗粒沥青混合料级配组成设计方法的研究。对橡胶颗粒沥青混合料组成材料的配比范围、级配组成设计方法、最佳沥青用量的确定方法等进行了研究。
首先,采用多目标的星点设计—效应面法,确定了混合料中粗集料、橡胶颗粒和粗橡胶颗粒的配比范围;在此基础上,运用体积设计法进行了混合料配合比设计;针对橡胶颗粒沥青混合料组成材料的特点,提出修正的马歇尔法用于橡胶颗粒沥青混合料最佳沥青用量的确定,在考察常规马歇尔体积指标的基础上,增加飞散损失率这一评价指标;最后,进行了混合料路用性能验证。
Transportation security is a difficult problem for administrator in cold region. Granulated crumb rubber asphalt mixture is a new mixture with granulated crumb rubber. Granulated crumb rubber act as aggregates in mixture, which are crashed from scrap tires. Ice and snow layers are in different conditions on granulated crumb rubber asphalt pavement for elasticity of granulated crumb rubber. Thus it can be eliminated from pavement. It is a effective method to anti-ice-snow. Moreover, the quantities of scrap tires are increasing. It is necessary to deal with so many scrap tires. Granulated crumb rubber asphalt mixture is the best choice. However it lacks systemic research on application technologies of granulated crumb rubber asphalt mixture, such as gradation design or compaction technology and anti-ice-snow performance.
Thus the application technologies of granulated crumb rubber asphalt mixture are studied in the paper. It includes characteristics of granulated crumb rubber, gradation composition design, compaction technology and anti-ice-snow performance. The main contents are introduced in the following paragraphs. The effect of granulated crumb rubber characteristics on mixtures performance are analyzed in three aspects. They are shape characteristics, surface characteristics and physical and mechanical characteristics. The technical index are confirmed through performance test.
The results indicate the shape characteristics and the physical and mechanical characteristics are important to performance of mixture . But the surface characteristics is minor. When rigidity of granulated crumb rubber is increased, the performance of mixture is improved including compaction performance, volume performance and enduring performance.
The ratio of coarse aggregates, granulated crumb rubber and coarse granulated crumb rubber are confirmed using the central composite design and response surface methodology. Then mixture gradations are designed with volume design method. According the characteristics of granulated crumb rubber asphalt mixture, the improved Marshall test method is put forward to confirm the optimal asphalt content. In this process the anti-scaling ratio is considered
为此,本论文就橡胶颗粒的技术性质、橡胶颗粒沥青混合料组成设计方法、成型工艺及其除冰雪性能等问题,对橡胶颗粒沥青混合料应用技术进行了系统研究。论文的主要研究工作如下:
⑴橡胶颗粒技术性质的研究。从橡胶颗粒的形状特性、表面特性和力学特性角度入手,分析了橡胶颗粒的技术性质对橡胶颗粒沥青混合料压实特性、体积特性、弹性变形特性和耐久性能等的影响,并最终确定出沥青混合料用橡胶颗粒的技术指标要求。
研究结果表明,橡胶颗粒的形状特性和力学特性对混合料的性能影响较大,随细长扁平颗粒含量的减小,硬度的增大,混合料的压实特性、体积特性和使用的耐久性增强;橡胶颗粒的表面特性的差异对混合料性能有一定影响,但其影响并不显著。
⑵橡胶颗粒沥青混合料级配组成设计方法的研究。对橡胶颗粒沥青混合料组成材料的配比范围、级配组成设计方法、最佳沥青用量的确定方法等进行了研究。
首先,采用多目标的星点设计—效应面法,确定了混合料中粗集料、橡胶颗粒和粗橡胶颗粒的配比范围;在此基础上,运用体积设计法进行了混合料配合比设计;针对橡胶颗粒沥青混合料组成材料的特点,提出修正的马歇尔法用于橡胶颗粒沥青混合料最佳沥青用量的确定,在考察常规马歇尔体积指标的基础上,增加飞散损失率这一评价指标;最后,进行了混合料路用性能验证。
Transportation security is a difficult problem for administrator in cold region. Granulated crumb rubber asphalt mixture is a new mixture with granulated crumb rubber. Granulated crumb rubber act as aggregates in mixture, which are crashed from scrap tires. Ice and snow layers are in different conditions on granulated crumb rubber asphalt pavement for elasticity of granulated crumb rubber. Thus it can be eliminated from pavement. It is a effective method to anti-ice-snow. Moreover, the quantities of scrap tires are increasing. It is necessary to deal with so many scrap tires. Granulated crumb rubber asphalt mixture is the best choice. However it lacks systemic research on application technologies of granulated crumb rubber asphalt mixture, such as gradation design or compaction technology and anti-ice-snow performance.
Thus the application technologies of granulated crumb rubber asphalt mixture are studied in the paper. It includes characteristics of granulated crumb rubber, gradation composition design, compaction technology and anti-ice-snow performance. The main contents are introduced in the following paragraphs. The effect of granulated crumb rubber characteristics on mixtures performance are analyzed in three aspects. They are shape characteristics, surface characteristics and physical and mechanical characteristics. The technical index are confirmed through performance test.
The results indicate the shape characteristics and the physical and mechanical characteristics are important to performance of mixture . But the surface characteristics is minor. When rigidity of granulated crumb rubber is increased, the performance of mixture is improved including compaction performance, volume performance and enduring performance.
The ratio of coarse aggregates, granulated crumb rubber and coarse granulated crumb rubber are confirmed using the central composite design and response surface methodology. Then mixture gradations are designed with volume design method. According the characteristics of granulated crumb rubber asphalt mixture, the improved Marshall test method is put forward to confirm the optimal asphalt content. In this process the anti-scaling ratio is considered
引文
1 彭旭东, 孟祥凯, 卢荡, 郭孔辉, 谢友柏. 冰雪路面汽车轮胎摩擦特性研究进展.摩擦学学报.2003, 23(5):451~455
2 彭旭东, 雷毅, 郭孔辉, 谢友柏. 冰雪路面上轮胎摩擦特性的控制方法研究. 中国机械工程. 2001, 12(11):1232~1235
3 赵波, 李晋. 高原冰雪条件下汽车主要性能的变化探析. 兵工学报. 1999, (4):46~49
4 废旧轮胎回收利用大有作为. 国家发展改革委环境和资源综合利用司. 中国经贸导刊. 2003, (21):27
5 王淑芬. 废旧轮胎的回收与利用. 辽宁城乡环境科技. 2004, 24(4):37~38
6 庾晋, 白杉. 废旧轮胎回收利用现状和利用途径. 橡塑技术与装备. 2003, 29:11-18
7 张隐西, 范茹良. 废旧轮胎的回收和综合利用. 中国资源综合利用. 2000, (6):4~10
8 阎家宾. 废旧轮胎的利用和再生胶的生产与应用. 世界橡胶工业. 1999, 26(1):44~48
9 杨志峰, 李美江, 王旭东. 废旧橡胶粉在道路工程中应用的历史和现状. 公路交通科技. 2005, 22(7):20~22
10 郑南翔, 李安. 废轮胎胶粉改性沥青设计与施工工艺. 山西建筑. 2005, 31(3):93
11 李锐. 处理废旧轮胎 回收二次资源. 山东环境. 1996, (2):44~45
12 王祺. 废旧橡胶粉改性沥青的试验与应用. 辽宁交通科技. 2000, (12):6~8
13 夏云标. 贯彻发展循环经济理念 促进废橡胶综合利用发展. 中国橡胶. 2005, 21(12):9~11
14 石洪波, 邹明旭, 廖克俭,丛玉凤,闫锋. 废橡胶粉改性道路沥青的研究进展. 化学工业与工程技术. 2005, 26(2):27~32
15 张炳臣,刘淑敏. 冬季道路除雪方式的探讨. 山东交通科技. 2004,(1):76~77
16 厉永举,高一平,田保侠. 日本札幌市道路抗冻结路面铺设方法. 内蒙古公路与运输. 2001, (4):16~17
17 骆虹, 罗立斌, 张晶. 融雪剂对环境的影响及对策. 中国环境监测. 2004,20(1):55~57
18 唐祖全, 李卓球, 侯作富, 徐东亮. 导电混凝土电热除冰雪的功率分析. 重庆建筑大学学报. 2002, 24(3):101~105
19 武海琴. 发热电缆用于路面融雪化冰的技术研究. 北京工业大学硕士学位论文. 2005:2~9
20 George B. Way, P. E. Pavement Design-OGFC Meet CRM. The Asphalt Conference. Atlanta, Georgia. March 25, 1998:32~37
21 Lee R.C. Bridge Heating Using Ground Source Heat Pipe. Transportation Research. 1984,(1): 51~57
22 曾玉珍, 廖正环. 废旧轮胎在道路工程中的应用. 国外公路. 2000, 20(1):39-41
23 Don J. Degroot, Wayne M. Shelbume, Michael S. Switzenbaum. Use of Recycled Materials and Recycled Products in Highway Construction. Final Report. 1995:81~93
24 Epps, Jon A. Use of Recycled Rubber Tires in Highways. NCHRP Synthesis of Highway Practice No. 198, Transportation Research Board, Washington, DC, 1994:23~29
25 Prithvi S. Kandhal. Waste Materials in Hot Mix Asphalt Overview. NCAT Report. 1992:64~89
26 Turgeon, Curtis M. The Use of Asphalt-Rubber Products in Minnesota. Presented at the National Seminar on Asphalt-Rubber, Kansas City, Missouri, October, 1989:6~11
27 Oliver J W H. Modification of Paving Asphalts by Digestion with Scrap Rubber. Transportation Research Record. 1979, (821):37~44
28 Charles J.Glover and Richard R.Davison.High-Cure Crumb Rubber Modified Asphalt for Dense-Graded Mixes. Project Summary Report 1460-S, 1998:16~23
29 R. Michael Anderson, John T. Harvey, James A. Scherocman. Bailey Method for Gradation Selection in Hot-Mix Asphalt Mixture Design. Transportation Research E-circular.Number E-C044, October 2002:2-6
30 Meiarashi Seishi. Noticeable Civil Engineering Materials-Research and Development of New Low-noise Pavement Using Rubber of Waste Tire. Doboku Gijutsu. 1998, 53(4):72~77
31 J. Werner. Asphalt Pavement Developments in Europe. AAPT. 1998(42): 524~541
32 Ferrara A.A.& Haslett R. Prevention of Preferential Bridge Icing Using Heat Pipes, Washington. D.C. Federal Highway Administration, FHWA-ED-75- 111:37~43
33 Sherif Y., Christopher Y and David F. et al. Conductive Concrete Overlay for Bridge Deck Deicing: Mixing Proportioning, Optimizing and Properties. ACU Marerials Journal. 2000,(97): 172~181
34 SHRP-LTPP General Pavement Studies. National Research Council. 1994:326~382
35 C.L.Monismith, F.N. Finn. Improved Asphalt Mix Design. AAPT. 1985, (54):347~406
36 Louisiana Standard Specifications for Construction of Roads and Bridges. State Louisiana Department of Transportation and Development Baton Rouge. 2000: 97~105
37 Standard Specifications for Construction and Maintenance of Highways and Bridges. Texas Department of Transportation. 1995:45~62
38 Billiter T C, Chun J S, Pavision R R, Glover C J, Buttin J A. Investigation of the Curing Variables of Asphalt-Rubber Binder. ACS Division of Fuel Chemistry Preprints. 1996, 41(4):1221~1226
39 Swearingen, David L., Newton C. Jackson, and Keith W. Anderson. Use of Recycled Materials in Highway Construction. Washington State Department of Transportation, Report No.WA-RD 252.1, Olympia, Washington, February, 1992:87~92
40 Heitzman, Michael. Design and Construction of Asphalt Paving Materials with Crumb Rubber. Transportation Research Record No. 1339, Transportation Research Board, Washington, DC, 1991:1-8
41 Van Kirk, Jack L. Experience with Rubberized Asphalt Concrete.Presented at the Technology Transfer Session of an Introduction to Rubberized Asphalt Concrete, Topeka, Kansas, January, 1991:45~51
42 Shimomura Soichi, Motofuji Tsutomu, Takahashi Takuji. Freezing Controlled Pavement with Rubber Matted Concrete flat Plate Utilizing Waste Tire. Nippon Doro Kaigi Ronbunshu, 1995, 21:522~523
43 Taniguchi Toyoaki, Inaba Yulinori, Ohashihajime. Mechanisms and Effect of a Granular Rubber Freezing Controlled Pavement. Doro Kensetsu,1995,(564):66~72.
44 Hossein B, Takallou.Evaluation of Mix Ingredients on the Performance of Rubber-Modified Asphalt Mixtures. The Doctor Thesis of Philosophy for Oregon State University. 1988:2~8
45 Jason Fleming Chipps. The Industrial Manufacture of Tire Rubber Modified Asphalts with Enhanced Rheological Performance and Improved Longevity. The Doctor Thesis of Philosophy for Texas A&M University. 2001:15~18
46 Akpanika Nyong Ekpo Ntekim.Effects of Moisture on Asphalt-Rubber Mixtures Using Superpave. The Doctor Thesis of Civil Engineering for Polytechnic University. 2001:31~34
47 State of California Department of Transportation. Asphalt Rubber Usage Guide. Division of Engineering Services. 2003:1~4
48 Freedy L.Robert, Prithvi S.Kandhal, E.Ray Brown, Robert L.Dunning. Investigation and Evaluation of Ground Tire Rubber in Hot Mix Asphalt. National Center for Asphalt Technology Report No.89-3.1989, 8:69~82
49 ARRB Transport Research. Crumb Rubber Asphalt Fatigue Study Phase 1:Binder Testing.1997, 2:73~91
50 Panagiotis Frantzis.Crumb Rubber-Bitumen Interactions: Cold-Stage Optical Microscopy. Journal of Materials in Civil Engineering/ASCE. 2003,9(10): 419~426
51 George B.Way, P.E.Arizona Department of Transportation. FlagstaffⅠ-40 Asphalt Rubber Overlay Project Nine Years of Success. Paper Presented to TRB 78th Annual Meeting. 1999, 8:108~117
52 Haifeng Ni.Application of Asphalt Rubber Technology to Recreational Trails.A Doctor Dissertation Presented to The Faculty of Natural Sciences, Mathematics and Engineering University of Denver. 2003, 6:34~41
53 Prithvi S.Kandhal.Potential of Asphalt Pavement Analyzer(APA)to Predict Rutting of Hot Mix Asphalt. 1999 International Conference on Accelerated Pavement Testing. 1999,7:42~49
54 John T. Harvey. Fatigue Performance of Asphalt Concrete Mixes and its Relationship to Asphalt Concrete Pavement Performance in California. 1995
55 Paul Croney, David Croney. The Design and Performance of Road. New York: Kluwer Academic Plenum Publishers, 1997:25~42
56 Powell. The Structural Design of Bituminous Roads. TRRL Laboratory Report. 1984:358~420
57 Robert. Asphalts in Road Construction. London: National Academy Press, 2000:125~148
58 Highway Agency. Design Manual for Roads and Bridges. Pavement Design and Maintenance. Conference in London. 1998:26~98
59 Lewandowski L.H. Polymer Modification of Paving Asphalt Binders. Rubber Chemistry and Technology. 1994:67(3):447~480
60 Adhikari B D D, Maiti S. Reclamation and Recycling of Waste Rubber. Prog Polym Science. 2000,25(7):909~948
61 Rebala S R, Estakhri C K. Laboratory Evaluation of Crumb Rubber Modified Mixtures Designed Using TxDOT Mixture Design Method. Transport Research Record. 1995,1515:1~10
62 Ghaly A M. Properties of Asphalt Rubberized with Waste tires Crumb. Journal of Solid Waste Technology and Management. 1999,26(1):45~50
63 陆永其. 国外废橡胶资源的利用概况. 再生资源研究. 2005, (1):16~19
64 卢剑涛, 王钊编译. 橡胶粉改性沥青混合料性质研究. 中外公路. 2003, 23(6):79
65 何永峰, 刘玉强. 胶粉生产及其应用. 中国石化出版社. 2001:54~56 60~71 72~98 99~106
66 马志远, 连永祥. 胶粉的生产及应用. 辽宁化工. 2003, 32(2):91~94
67 黄彭, 吕伟民, 张福清, 魏晓静. 橡胶粉改性沥青混合料性能与工艺技术研究. 中国公路学报. 2001, 14(9):6 8
68 王文贵, 覃淑媛. 橡胶沥青在北方高寒地区公路工程中的应用. 内蒙古公路与运输. 1996, (4):30~31
69 彭文勇, 赵弘亮. 聚乙烯橡胶改性沥青的研究. 云南交通科技. 2000, 16(1):21~22
70 廖明义, 李雪. 废橡胶粉改性沥青稳定性及其影响因素. 石油化工高等学校学报. 2004, 17(4):38~43
71 赵光贤. 胶粉及其应用. 特种橡胶制品. 1997, 18(1):12~13 38~47
72 张小英, 徐传杰, 张玉贞. 废橡胶粉改性沥青研究综述(2). 石油沥青. 2004, 18(5):1~6
73 叶智刚, 孔宪明, 余剑英, 魏连启, 蒋中林. 橡胶粉改性沥青的研究. 武汉理工大学学报. 2003, 25(1):12~13
74 傅大放, 惠先宝, 符冠华, 姜伟立, 解建光. 废弃轮胎胶粉干法改性热拌沥青混合料(RUMAC)试验研究. 公路交通科技. 2001, 18(5):4~8
75 曾蔚. 干拌法橡胶粉混合料的低温性能研究. 公路交通科技. 2004, 21(7):22~25
76 黄文元, 孙立军, 王旭东. 橡胶粉改性沥青混凝土的性能评价和施工工艺措施研究. 上海公路. 2004, (2):6 7 9~10
77 李宇峙, 黄敏, 黄云涌. 橡胶沥青混凝土(干法)压实特性及高温稳定性室内试验研究. 公路. 2003, (10):87~90
78 刘晓鸿. RUBBIT 设计与研究. 哈尔滨建筑大学硕士学位论文. 2000, 6:4~5 16~27
79 庄继德. 汽车轮胎学. 北京理工大学出版社. 1997:8~11 52~59 13~15
80 Francis P Milcnis, Laurant C Michon. Some Application of Nuclear Magnetic Resonance Imaging to Rubber Modified Asphalts. ACS Division of Fuel Chemistry Preprints. 1997, 42(3):928~1032
81 Brian D.Prowell, P.E.Senior. Development of Rutting for the Asphalt Pavement Analyzer. 1999 International Conference on Accelerated Pavement Testing. 1999,7:75~81
82 Federal Highway Administration and Office for Engineering and Technology Applications. State of the Practice-Design and Construction of Asphalt Paving Materials with Crumb Rubber Modifier. Publication No. FHWA-SA- 92-022.1992, 5:93~106
83 刘植榕, 汤华远, 郑亚丽. 橡胶工业手册. 化学工业出版社. 1997:74 2~5
84 吴伟, 崔光华, 陆彬. 实验设计中多指标的优化:星点设计和总评“归一值”的应用. 中国药学杂志. 2000, 35(8):530~533
85 吴伟, 崔光华.星点设计-效应面优化法及其在药学中的应用.国外医学药学分册.2000, 27(5):292~298
86 Wang YM, Sato H, Adachi I, et al. Optimization of the Formulation Design of Chitosan Microspheres Containing Cisplatin. J Pharm Science.1996, 85(11):1204
87 Molpeceres J, Guzman M, Aberturas MR, et al. Application of Central Composite Design to the Preparation of Polycaprolactone Nanoparticles by Solvent Displacement. J Pharm Science. 1996, 85(2):206~208
88 陈佩茹.与性能相关的法国沥青混合料设计方法.中外公路.2002, 20(1):1~4
89 Aggregate Blending for Asphalt Mix Design: The Bailey Method TRB02- 3629. 2001,11:12~29
90 Estakhri, Cindy K., Joe W. Button, and Emmanuel G. Fernando. Experience, Availability, and Cost-Effectiveness of Asphalt Rubber in Texas. Transportation Research Record No. 1339, Transportation Research Board, Washington, DC, 1992:45~53
91 Green E, Tolone W. The Chemical and Physical Properties of Asphalt-Rubber Mixture. Part- Ⅰ Basic Material Behaviour. FHWA-AI-HPR14-162, Arizona Department to Transportation, March 1977:52~56
92 解晓光. 沥青混合料振动压实特性的研究. 哈尔滨工业大学硕士学位论文. 2000:26~50 16~25
93 郭永辉. 美国工程兵旋转压实剪切试验机设计的沥青混凝土性能. 公路. 2002, (4):74~76
94 解晓光, 马松林. 压实工艺对沥青混合料力学性能的影响.东北公路.2001, 24(2):29~31
95 蔡之锐, 孙柏涛, 郭世荣, 周世光. 冰荷载的试验研究与计算方法. 地震工程与工程振动. 1997, (2):49~52 54~56
96 李锋, 岳前进. 冰在斜面结构上的纵横弯曲破坏分析. 水利学报. 2000, (3):44~47
97 李洪升, 杜小振. 冰体材料损伤与断裂破坏的本构理论. 冰川冻土. 2003, (9):304~307
98 孙大刚, 诸文农, 李立辉. 橡胶缓冲装置疲劳失效特征值的研究. 农业工程学报. 1998, 14(2):111
99 梁焱, 郭有仪, 王焱. 橡胶低温冲击断裂机理研究. 低温工程. 2002, (6):30~32
100 梁焱, 郭有仪, 丁平. 橡胶单颗粒低温冲击破碎的实验研究. 低温工程. 2002, (5):37
101 龚曙光. ANSYS 基础应用及范例解析. 机械工业出版社, 2003, 1:30~50
102 易日. 使用 ANSYS 进行结构力学分析. 北京工业出版社, 2002, 9:21~35
103 任晓辉. 冰的韧脆转变行为研究. 大连理工大学硕士学位论文. 2005, 6:12~23
104 马维林. 雪剪切变形与断裂实验研究. 干旱区地理. 1995, 18(4):73~81
105 郝大力. 路面性能评价与分析研究. 长安大学博士学位论文. 2000, 7:23~41
2 彭旭东, 雷毅, 郭孔辉, 谢友柏. 冰雪路面上轮胎摩擦特性的控制方法研究. 中国机械工程. 2001, 12(11):1232~1235
3 赵波, 李晋. 高原冰雪条件下汽车主要性能的变化探析. 兵工学报. 1999, (4):46~49
4 废旧轮胎回收利用大有作为. 国家发展改革委环境和资源综合利用司. 中国经贸导刊. 2003, (21):27
5 王淑芬. 废旧轮胎的回收与利用. 辽宁城乡环境科技. 2004, 24(4):37~38
6 庾晋, 白杉. 废旧轮胎回收利用现状和利用途径. 橡塑技术与装备. 2003, 29:11-18
7 张隐西, 范茹良. 废旧轮胎的回收和综合利用. 中国资源综合利用. 2000, (6):4~10
8 阎家宾. 废旧轮胎的利用和再生胶的生产与应用. 世界橡胶工业. 1999, 26(1):44~48
9 杨志峰, 李美江, 王旭东. 废旧橡胶粉在道路工程中应用的历史和现状. 公路交通科技. 2005, 22(7):20~22
10 郑南翔, 李安. 废轮胎胶粉改性沥青设计与施工工艺. 山西建筑. 2005, 31(3):93
11 李锐. 处理废旧轮胎 回收二次资源. 山东环境. 1996, (2):44~45
12 王祺. 废旧橡胶粉改性沥青的试验与应用. 辽宁交通科技. 2000, (12):6~8
13 夏云标. 贯彻发展循环经济理念 促进废橡胶综合利用发展. 中国橡胶. 2005, 21(12):9~11
14 石洪波, 邹明旭, 廖克俭,丛玉凤,闫锋. 废橡胶粉改性道路沥青的研究进展. 化学工业与工程技术. 2005, 26(2):27~32
15 张炳臣,刘淑敏. 冬季道路除雪方式的探讨. 山东交通科技. 2004,(1):76~77
16 厉永举,高一平,田保侠. 日本札幌市道路抗冻结路面铺设方法. 内蒙古公路与运输. 2001, (4):16~17
17 骆虹, 罗立斌, 张晶. 融雪剂对环境的影响及对策. 中国环境监测. 2004,20(1):55~57
18 唐祖全, 李卓球, 侯作富, 徐东亮. 导电混凝土电热除冰雪的功率分析. 重庆建筑大学学报. 2002, 24(3):101~105
19 武海琴. 发热电缆用于路面融雪化冰的技术研究. 北京工业大学硕士学位论文. 2005:2~9
20 George B. Way, P. E. Pavement Design-OGFC Meet CRM. The Asphalt Conference. Atlanta, Georgia. March 25, 1998:32~37
21 Lee R.C. Bridge Heating Using Ground Source Heat Pipe. Transportation Research. 1984,(1): 51~57
22 曾玉珍, 廖正环. 废旧轮胎在道路工程中的应用. 国外公路. 2000, 20(1):39-41
23 Don J. Degroot, Wayne M. Shelbume, Michael S. Switzenbaum. Use of Recycled Materials and Recycled Products in Highway Construction. Final Report. 1995:81~93
24 Epps, Jon A. Use of Recycled Rubber Tires in Highways. NCHRP Synthesis of Highway Practice No. 198, Transportation Research Board, Washington, DC, 1994:23~29
25 Prithvi S. Kandhal. Waste Materials in Hot Mix Asphalt Overview. NCAT Report. 1992:64~89
26 Turgeon, Curtis M. The Use of Asphalt-Rubber Products in Minnesota. Presented at the National Seminar on Asphalt-Rubber, Kansas City, Missouri, October, 1989:6~11
27 Oliver J W H. Modification of Paving Asphalts by Digestion with Scrap Rubber. Transportation Research Record. 1979, (821):37~44
28 Charles J.Glover and Richard R.Davison.High-Cure Crumb Rubber Modified Asphalt for Dense-Graded Mixes. Project Summary Report 1460-S, 1998:16~23
29 R. Michael Anderson, John T. Harvey, James A. Scherocman. Bailey Method for Gradation Selection in Hot-Mix Asphalt Mixture Design. Transportation Research E-circular.Number E-C044, October 2002:2-6
30 Meiarashi Seishi. Noticeable Civil Engineering Materials-Research and Development of New Low-noise Pavement Using Rubber of Waste Tire. Doboku Gijutsu. 1998, 53(4):72~77
31 J. Werner. Asphalt Pavement Developments in Europe. AAPT. 1998(42): 524~541
32 Ferrara A.A.& Haslett R. Prevention of Preferential Bridge Icing Using Heat Pipes, Washington. D.C. Federal Highway Administration, FHWA-ED-75- 111:37~43
33 Sherif Y., Christopher Y and David F. et al. Conductive Concrete Overlay for Bridge Deck Deicing: Mixing Proportioning, Optimizing and Properties. ACU Marerials Journal. 2000,(97): 172~181
34 SHRP-LTPP General Pavement Studies. National Research Council. 1994:326~382
35 C.L.Monismith, F.N. Finn. Improved Asphalt Mix Design. AAPT. 1985, (54):347~406
36 Louisiana Standard Specifications for Construction of Roads and Bridges. State Louisiana Department of Transportation and Development Baton Rouge. 2000: 97~105
37 Standard Specifications for Construction and Maintenance of Highways and Bridges. Texas Department of Transportation. 1995:45~62
38 Billiter T C, Chun J S, Pavision R R, Glover C J, Buttin J A. Investigation of the Curing Variables of Asphalt-Rubber Binder. ACS Division of Fuel Chemistry Preprints. 1996, 41(4):1221~1226
39 Swearingen, David L., Newton C. Jackson, and Keith W. Anderson. Use of Recycled Materials in Highway Construction. Washington State Department of Transportation, Report No.WA-RD 252.1, Olympia, Washington, February, 1992:87~92
40 Heitzman, Michael. Design and Construction of Asphalt Paving Materials with Crumb Rubber. Transportation Research Record No. 1339, Transportation Research Board, Washington, DC, 1991:1-8
41 Van Kirk, Jack L. Experience with Rubberized Asphalt Concrete.Presented at the Technology Transfer Session of an Introduction to Rubberized Asphalt Concrete, Topeka, Kansas, January, 1991:45~51
42 Shimomura Soichi, Motofuji Tsutomu, Takahashi Takuji. Freezing Controlled Pavement with Rubber Matted Concrete flat Plate Utilizing Waste Tire. Nippon Doro Kaigi Ronbunshu, 1995, 21:522~523
43 Taniguchi Toyoaki, Inaba Yulinori, Ohashihajime. Mechanisms and Effect of a Granular Rubber Freezing Controlled Pavement. Doro Kensetsu,1995,(564):66~72.
44 Hossein B, Takallou.Evaluation of Mix Ingredients on the Performance of Rubber-Modified Asphalt Mixtures. The Doctor Thesis of Philosophy for Oregon State University. 1988:2~8
45 Jason Fleming Chipps. The Industrial Manufacture of Tire Rubber Modified Asphalts with Enhanced Rheological Performance and Improved Longevity. The Doctor Thesis of Philosophy for Texas A&M University. 2001:15~18
46 Akpanika Nyong Ekpo Ntekim.Effects of Moisture on Asphalt-Rubber Mixtures Using Superpave. The Doctor Thesis of Civil Engineering for Polytechnic University. 2001:31~34
47 State of California Department of Transportation. Asphalt Rubber Usage Guide. Division of Engineering Services. 2003:1~4
48 Freedy L.Robert, Prithvi S.Kandhal, E.Ray Brown, Robert L.Dunning. Investigation and Evaluation of Ground Tire Rubber in Hot Mix Asphalt. National Center for Asphalt Technology Report No.89-3.1989, 8:69~82
49 ARRB Transport Research. Crumb Rubber Asphalt Fatigue Study Phase 1:Binder Testing.1997, 2:73~91
50 Panagiotis Frantzis.Crumb Rubber-Bitumen Interactions: Cold-Stage Optical Microscopy. Journal of Materials in Civil Engineering/ASCE. 2003,9(10): 419~426
51 George B.Way, P.E.Arizona Department of Transportation. FlagstaffⅠ-40 Asphalt Rubber Overlay Project Nine Years of Success. Paper Presented to TRB 78th Annual Meeting. 1999, 8:108~117
52 Haifeng Ni.Application of Asphalt Rubber Technology to Recreational Trails.A Doctor Dissertation Presented to The Faculty of Natural Sciences, Mathematics and Engineering University of Denver. 2003, 6:34~41
53 Prithvi S.Kandhal.Potential of Asphalt Pavement Analyzer(APA)to Predict Rutting of Hot Mix Asphalt. 1999 International Conference on Accelerated Pavement Testing. 1999,7:42~49
54 John T. Harvey. Fatigue Performance of Asphalt Concrete Mixes and its Relationship to Asphalt Concrete Pavement Performance in California. 1995
55 Paul Croney, David Croney. The Design and Performance of Road. New York: Kluwer Academic Plenum Publishers, 1997:25~42
56 Powell. The Structural Design of Bituminous Roads. TRRL Laboratory Report. 1984:358~420
57 Robert. Asphalts in Road Construction. London: National Academy Press, 2000:125~148
58 Highway Agency. Design Manual for Roads and Bridges. Pavement Design and Maintenance. Conference in London. 1998:26~98
59 Lewandowski L.H. Polymer Modification of Paving Asphalt Binders. Rubber Chemistry and Technology. 1994:67(3):447~480
60 Adhikari B D D, Maiti S. Reclamation and Recycling of Waste Rubber. Prog Polym Science. 2000,25(7):909~948
61 Rebala S R, Estakhri C K. Laboratory Evaluation of Crumb Rubber Modified Mixtures Designed Using TxDOT Mixture Design Method. Transport Research Record. 1995,1515:1~10
62 Ghaly A M. Properties of Asphalt Rubberized with Waste tires Crumb. Journal of Solid Waste Technology and Management. 1999,26(1):45~50
63 陆永其. 国外废橡胶资源的利用概况. 再生资源研究. 2005, (1):16~19
64 卢剑涛, 王钊编译. 橡胶粉改性沥青混合料性质研究. 中外公路. 2003, 23(6):79
65 何永峰, 刘玉强. 胶粉生产及其应用. 中国石化出版社. 2001:54~56 60~71 72~98 99~106
66 马志远, 连永祥. 胶粉的生产及应用. 辽宁化工. 2003, 32(2):91~94
67 黄彭, 吕伟民, 张福清, 魏晓静. 橡胶粉改性沥青混合料性能与工艺技术研究. 中国公路学报. 2001, 14(9):6 8
68 王文贵, 覃淑媛. 橡胶沥青在北方高寒地区公路工程中的应用. 内蒙古公路与运输. 1996, (4):30~31
69 彭文勇, 赵弘亮. 聚乙烯橡胶改性沥青的研究. 云南交通科技. 2000, 16(1):21~22
70 廖明义, 李雪. 废橡胶粉改性沥青稳定性及其影响因素. 石油化工高等学校学报. 2004, 17(4):38~43
71 赵光贤. 胶粉及其应用. 特种橡胶制品. 1997, 18(1):12~13 38~47
72 张小英, 徐传杰, 张玉贞. 废橡胶粉改性沥青研究综述(2). 石油沥青. 2004, 18(5):1~6
73 叶智刚, 孔宪明, 余剑英, 魏连启, 蒋中林. 橡胶粉改性沥青的研究. 武汉理工大学学报. 2003, 25(1):12~13
74 傅大放, 惠先宝, 符冠华, 姜伟立, 解建光. 废弃轮胎胶粉干法改性热拌沥青混合料(RUMAC)试验研究. 公路交通科技. 2001, 18(5):4~8
75 曾蔚. 干拌法橡胶粉混合料的低温性能研究. 公路交通科技. 2004, 21(7):22~25
76 黄文元, 孙立军, 王旭东. 橡胶粉改性沥青混凝土的性能评价和施工工艺措施研究. 上海公路. 2004, (2):6 7 9~10
77 李宇峙, 黄敏, 黄云涌. 橡胶沥青混凝土(干法)压实特性及高温稳定性室内试验研究. 公路. 2003, (10):87~90
78 刘晓鸿. RUBBIT 设计与研究. 哈尔滨建筑大学硕士学位论文. 2000, 6:4~5 16~27
79 庄继德. 汽车轮胎学. 北京理工大学出版社. 1997:8~11 52~59 13~15
80 Francis P Milcnis, Laurant C Michon. Some Application of Nuclear Magnetic Resonance Imaging to Rubber Modified Asphalts. ACS Division of Fuel Chemistry Preprints. 1997, 42(3):928~1032
81 Brian D.Prowell, P.E.Senior. Development of Rutting for the Asphalt Pavement Analyzer. 1999 International Conference on Accelerated Pavement Testing. 1999,7:75~81
82 Federal Highway Administration and Office for Engineering and Technology Applications. State of the Practice-Design and Construction of Asphalt Paving Materials with Crumb Rubber Modifier. Publication No. FHWA-SA- 92-022.1992, 5:93~106
83 刘植榕, 汤华远, 郑亚丽. 橡胶工业手册. 化学工业出版社. 1997:74 2~5
84 吴伟, 崔光华, 陆彬. 实验设计中多指标的优化:星点设计和总评“归一值”的应用. 中国药学杂志. 2000, 35(8):530~533
85 吴伟, 崔光华.星点设计-效应面优化法及其在药学中的应用.国外医学药学分册.2000, 27(5):292~298
86 Wang YM, Sato H, Adachi I, et al. Optimization of the Formulation Design of Chitosan Microspheres Containing Cisplatin. J Pharm Science.1996, 85(11):1204
87 Molpeceres J, Guzman M, Aberturas MR, et al. Application of Central Composite Design to the Preparation of Polycaprolactone Nanoparticles by Solvent Displacement. J Pharm Science. 1996, 85(2):206~208
88 陈佩茹.与性能相关的法国沥青混合料设计方法.中外公路.2002, 20(1):1~4
89 Aggregate Blending for Asphalt Mix Design: The Bailey Method TRB02- 3629. 2001,11:12~29
90 Estakhri, Cindy K., Joe W. Button, and Emmanuel G. Fernando. Experience, Availability, and Cost-Effectiveness of Asphalt Rubber in Texas. Transportation Research Record No. 1339, Transportation Research Board, Washington, DC, 1992:45~53
91 Green E, Tolone W. The Chemical and Physical Properties of Asphalt-Rubber Mixture. Part- Ⅰ Basic Material Behaviour. FHWA-AI-HPR14-162, Arizona Department to Transportation, March 1977:52~56
92 解晓光. 沥青混合料振动压实特性的研究. 哈尔滨工业大学硕士学位论文. 2000:26~50 16~25
93 郭永辉. 美国工程兵旋转压实剪切试验机设计的沥青混凝土性能. 公路. 2002, (4):74~76
94 解晓光, 马松林. 压实工艺对沥青混合料力学性能的影响.东北公路.2001, 24(2):29~31
95 蔡之锐, 孙柏涛, 郭世荣, 周世光. 冰荷载的试验研究与计算方法. 地震工程与工程振动. 1997, (2):49~52 54~56
96 李锋, 岳前进. 冰在斜面结构上的纵横弯曲破坏分析. 水利学报. 2000, (3):44~47
97 李洪升, 杜小振. 冰体材料损伤与断裂破坏的本构理论. 冰川冻土. 2003, (9):304~307
98 孙大刚, 诸文农, 李立辉. 橡胶缓冲装置疲劳失效特征值的研究. 农业工程学报. 1998, 14(2):111
99 梁焱, 郭有仪, 王焱. 橡胶低温冲击断裂机理研究. 低温工程. 2002, (6):30~32
100 梁焱, 郭有仪, 丁平. 橡胶单颗粒低温冲击破碎的实验研究. 低温工程. 2002, (5):37
101 龚曙光. ANSYS 基础应用及范例解析. 机械工业出版社, 2003, 1:30~50
102 易日. 使用 ANSYS 进行结构力学分析. 北京工业出版社, 2002, 9:21~35
103 任晓辉. 冰的韧脆转变行为研究. 大连理工大学硕士学位论文. 2005, 6:12~23
104 马维林. 雪剪切变形与断裂实验研究. 干旱区地理. 1995, 18(4):73~81
105 郝大力. 路面性能评价与分析研究. 长安大学博士学位论文. 2000, 7:23~41