基于板底脱空的水泥混凝土路面检测、处治与力学行为研究
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摘要
脱空评价、处治与力学状态研究是处于水泥混凝土路面板底脱空研究核心地位的内容,但是到目前为止,上述方面尚没有进行综合及系统的研究,而且部分研究的内容和深度未能达到工程所要求的程度,在某种程度上制约着水泥混凝土路面板底脱空研究的发展和工程应用。因此,本研究在分析国内外研究现状的基础上,以水泥混凝土路面板底脱空为研究对象,结合烟威高速试验路为依托,内容涉及水泥混凝土路面板底脱空的检测方法、评价标准、力学状态及处治技术等方面。
(1)路面板底脱空评价体系与标准研究
在对路面板底脱空成因及现有检测判别方法分析的基础上,综合系统地研究同板板中、板边中点、板角动静弯沉差,唧泥高度,路面雷达板底脱空判别方法,以同板动静弯沉差和唧泥高度作为评价指标分别建立旧水泥混凝土路面板底轻度、中度、重度脱空的分级标准,以期能简便、准确、实用的评价旧水泥混凝土路面板底脱空,补充和完善我国相关规范。
(2)基于板底脱空的路面板力学行为研究
全面研究在荷载和温度作用下不同路面板底脱空位置、面积,路面板厚度,接缝传荷能力,基层厚度等因素对水泥混凝土路面板应力及弯沉的影响;系统分析路面板最大应力及弯沉,总结最大应力及弯沉的变化规律,明确板底脱空路面板的力学行为,计算板底脱空水泥混凝土路面结构的疲劳寿命,为水泥混凝土路面板底脱空判别方法等方面研究提供力学基础。
(3)路面板底脱空处治技术与评价标准研究
主要对蓝派冲击压实、门刀式打裂压稳、MHB碎石化等旧水泥混凝土路面冲击压稳处治技术及针对板底不同脱空程度的有机类、水泥类、掺砂式自补偿式压浆处治材料进行全面系统的研究,进而推荐适用于不同板底脱空程度的处治效果评价标准,以应用于板底脱空不同处治技术效果评价,为旧水泥混凝土路面板底脱空处治技术和材料设计等研究提供理论基础。
(4)板底脱空压浆处治路面板力学行为研究
通过对板底脱空旧水泥混凝土路面板力学行为和板底脱空压浆处治技术的研究,进一步研究在荷载作用下不同路面板底压浆位置、面积,浆体模量,路面板厚度,基层厚度等因素对压浆处治路面板应力和弯沉的影响,确定压浆处治路面板的力学状态,得到不同压浆材料的有效处治面积。
(5)基于脱空的旧水泥路面沥青加铺层结构力学行为研究
系统分析荷载和温度耦合作用下沥青罩面层模量、厚度及旧水泥路面厚度等因素对沥青加铺层应力及弯沉的影响,剖析存在脱空的旧水泥路面加铺薄层沥青罩面复合式结构的力学行为,并以弯沉作为检测指标提出旧水泥路面加铺薄层沥青罩面复合式结构脱空评价标准。为沥青加铺层结构组合、材料设计和效果评价提供理论依据。
The study on the detection and treatment technology and mechanical state of voids beneath cement concrete pavement are the key content. However, there still has been no comprehensive and systematic study on them, and the content and degree of some studies can not meet the requirements of engineering. It restricts the development and application of study on voids beneath cement concrete pavement to a certain extent. Hence, based on the study at home and abroad and Yantai-Weihai highway testing part as attaching project, this study analyzes the detection methods, evaluation criteria, mechanical state and treatment technology of voids beneath cement concrete pavement.
(1) Analysis of the evaluation system and criteria of voids
Based on the analysis for cause and existing detection methods of voids beneath cement concrete pavement, the detection methods by the dynamic deflection and static deflection difference among the centre point, the midpoint of edge and the corner of the same slab, the pumping height and the road radar are studied synthetically. The evaluation criteria for the mild, moderate and serious degree of voids beneath cement concrete pavement by the indexes of the dynamic deflection and static deflection difference of the same slab and the pumping height are established. The evaluation criteria are expected to detect voids beneath cement concrete pavement in the simple, accurate and practical way, as the supplement and perfection for the related specifications.
(2) Analysis of the mechanical behaviors of cement concrete slabs above voids
The effect of factors such as the position and area of voids, the thickness of slabs, the load-transfer capacity of joints and the thickness of base on the stress and deflection of cement concrete slabs under traffic load and temperature are analyzed comprehensively. The maximum stress and deflection of cement concrete slabs are analyzed systematically, and the variation rule of the maximum stress and deflection value are summarized. The mechanical behaviors of cement concrete slabs above voids are determined, and the fatigue life is calculated, providing the mechanical basis for the detection methods.
(3) Analysis of the technology and evaluation criteria for voids treatment
The impacting and compacting technology such as of Landpac compaction, Guillotine break and MHB rubblization for voids treatment and the self-compensation grouting material of the organic type, the cement type and the sand type for different degree of voids treatment are analyzed systematically. Then the evaluation criteria are recommended to evaluate the effect of different treatment technology on different degree of voids, providing the theoretical basis for the technology and material design of voids treatment.
(4) Analysis of the mechanical properties of grouting slabs
According to the analysis of the mechanical behaviors of cement concrete slabs above voids and the treatment technology of voids grouting, the effect of factors such as the position and area of voids grouting, the modulus of grouting materials, the thickness of slabs and base on the stress and deflection of cement concrete slabs under traffic load are analyzed further. The mechanical condition of grouting slabs and the effective area of grouting material are determined.
(5) Analysis of the mechanical behaviors of PCC-AC above voids
The effect of factors such as the modulus and thickness of AC overlay and thickness of slabs on the stress and deflection of AC overlay under the coupling function of the traffic and temperature load are analyzed systematically, and the mechanical behaviors of PCC-AC above voids are studied. The evaluation criteria for the voids beneath PCC-AC by the indexes of the dynamic deflection and static deflection are recommended, providing the theoretical basis for the structural combination, material design and effect evaluation of AC overlay.
(1)路面板底脱空评价体系与标准研究
在对路面板底脱空成因及现有检测判别方法分析的基础上,综合系统地研究同板板中、板边中点、板角动静弯沉差,唧泥高度,路面雷达板底脱空判别方法,以同板动静弯沉差和唧泥高度作为评价指标分别建立旧水泥混凝土路面板底轻度、中度、重度脱空的分级标准,以期能简便、准确、实用的评价旧水泥混凝土路面板底脱空,补充和完善我国相关规范。
(2)基于板底脱空的路面板力学行为研究
全面研究在荷载和温度作用下不同路面板底脱空位置、面积,路面板厚度,接缝传荷能力,基层厚度等因素对水泥混凝土路面板应力及弯沉的影响;系统分析路面板最大应力及弯沉,总结最大应力及弯沉的变化规律,明确板底脱空路面板的力学行为,计算板底脱空水泥混凝土路面结构的疲劳寿命,为水泥混凝土路面板底脱空判别方法等方面研究提供力学基础。
(3)路面板底脱空处治技术与评价标准研究
主要对蓝派冲击压实、门刀式打裂压稳、MHB碎石化等旧水泥混凝土路面冲击压稳处治技术及针对板底不同脱空程度的有机类、水泥类、掺砂式自补偿式压浆处治材料进行全面系统的研究,进而推荐适用于不同板底脱空程度的处治效果评价标准,以应用于板底脱空不同处治技术效果评价,为旧水泥混凝土路面板底脱空处治技术和材料设计等研究提供理论基础。
(4)板底脱空压浆处治路面板力学行为研究
通过对板底脱空旧水泥混凝土路面板力学行为和板底脱空压浆处治技术的研究,进一步研究在荷载作用下不同路面板底压浆位置、面积,浆体模量,路面板厚度,基层厚度等因素对压浆处治路面板应力和弯沉的影响,确定压浆处治路面板的力学状态,得到不同压浆材料的有效处治面积。
(5)基于脱空的旧水泥路面沥青加铺层结构力学行为研究
系统分析荷载和温度耦合作用下沥青罩面层模量、厚度及旧水泥路面厚度等因素对沥青加铺层应力及弯沉的影响,剖析存在脱空的旧水泥路面加铺薄层沥青罩面复合式结构的力学行为,并以弯沉作为检测指标提出旧水泥路面加铺薄层沥青罩面复合式结构脱空评价标准。为沥青加铺层结构组合、材料设计和效果评价提供理论依据。
The study on the detection and treatment technology and mechanical state of voids beneath cement concrete pavement are the key content. However, there still has been no comprehensive and systematic study on them, and the content and degree of some studies can not meet the requirements of engineering. It restricts the development and application of study on voids beneath cement concrete pavement to a certain extent. Hence, based on the study at home and abroad and Yantai-Weihai highway testing part as attaching project, this study analyzes the detection methods, evaluation criteria, mechanical state and treatment technology of voids beneath cement concrete pavement.
(1) Analysis of the evaluation system and criteria of voids
Based on the analysis for cause and existing detection methods of voids beneath cement concrete pavement, the detection methods by the dynamic deflection and static deflection difference among the centre point, the midpoint of edge and the corner of the same slab, the pumping height and the road radar are studied synthetically. The evaluation criteria for the mild, moderate and serious degree of voids beneath cement concrete pavement by the indexes of the dynamic deflection and static deflection difference of the same slab and the pumping height are established. The evaluation criteria are expected to detect voids beneath cement concrete pavement in the simple, accurate and practical way, as the supplement and perfection for the related specifications.
(2) Analysis of the mechanical behaviors of cement concrete slabs above voids
The effect of factors such as the position and area of voids, the thickness of slabs, the load-transfer capacity of joints and the thickness of base on the stress and deflection of cement concrete slabs under traffic load and temperature are analyzed comprehensively. The maximum stress and deflection of cement concrete slabs are analyzed systematically, and the variation rule of the maximum stress and deflection value are summarized. The mechanical behaviors of cement concrete slabs above voids are determined, and the fatigue life is calculated, providing the mechanical basis for the detection methods.
(3) Analysis of the technology and evaluation criteria for voids treatment
The impacting and compacting technology such as of Landpac compaction, Guillotine break and MHB rubblization for voids treatment and the self-compensation grouting material of the organic type, the cement type and the sand type for different degree of voids treatment are analyzed systematically. Then the evaluation criteria are recommended to evaluate the effect of different treatment technology on different degree of voids, providing the theoretical basis for the technology and material design of voids treatment.
(4) Analysis of the mechanical properties of grouting slabs
According to the analysis of the mechanical behaviors of cement concrete slabs above voids and the treatment technology of voids grouting, the effect of factors such as the position and area of voids grouting, the modulus of grouting materials, the thickness of slabs and base on the stress and deflection of cement concrete slabs under traffic load are analyzed further. The mechanical condition of grouting slabs and the effective area of grouting material are determined.
(5) Analysis of the mechanical behaviors of PCC-AC above voids
The effect of factors such as the modulus and thickness of AC overlay and thickness of slabs on the stress and deflection of AC overlay under the coupling function of the traffic and temperature load are analyzed systematically, and the mechanical behaviors of PCC-AC above voids are studied. The evaluation criteria for the voids beneath PCC-AC by the indexes of the dynamic deflection and static deflection are recommended, providing the theoretical basis for the structural combination, material design and effect evaluation of AC overlay.
引文
[1]Lovel,C.W., and Mutti,R.A.(1985). Design to prevent pumping in concrete pavement. Report NO. FHWA/RD-86-118, Federal Highway Admin., Washington. D.C.
[2]Neal,B.F.(1980). Model slab faulting study. FHWA/CA/TL-80/23, California Dept. of Transp. Sacramento, Calif.
[3]PCA, Thickness and Construction of Joint for Concrete Highway Street Pavements, Portland Cement Association,1084.
[4]Dempsey, B.J., "Laboratory and Field Studies of Channeling and Pumping in Pavement Systems," Paper presented at PLARC Seminar, Paris, France,1983.
[5]Phu, N.C, J.P Christory and J.Ray, The Hydromechanics of Pumping in Concrete Pavements: Modeling and Prevention Pumping, Appendix I, Combating Concrete Pavement Pumping:State-of-the-Art and Recommendations, PLARC, Technical Committee on Concrete Roads,1986.
[6]NCHRP. Calibrated Mechanistic Structural Analysis Procedures for Pavement, University of Illinois at Urbana-Champaign,1990
[7]沙爱民,胡力群.路面基层材料抗冲刷性能试验研究[J].岩土工程学报,2002,24(3):276-280.
[8]Cheung, Y.K. and Zienkiewicz. O. C, Plates and tanks on elastic foundation an application of finite element method. International Journal of Solids and Structures, Vol,1,1965.
[9]Wang,S. K.,Sargious, M. and Cheung,Y.K. Advanced analysis of rigid pavements. Transportation Engineering Journal, ASCE,1974.
[10]黄仰贤.路面分析与设计[M].北京:人民交通出版社,1998.
[11]姚祖康.路面[M].北京:人民交通出版社,1999.
[12]郑传超,王秉纲,夏永旭.道路结构力学计算[M].北京:人民交通出版社,2003.
[13]唐伯明.落锤式弯沉仪在路面结构状况评定中的应用[D].南京:东南大学,1990.
[14]王陶,王复明,王钊.弹性地基接缝板模量反演和地基脱空判定[J].岩土力学,2003,24(2):233-236.
[15]万捷.水泥混凝土路面板底脱空检测及防治技术研究[D].西安:长安大学,2007.
[16]Crovetti, J.A. and M.I.Darter.Void Detection for Jointed Concrete Pavements. Transportation Research Record 1040, Washington,DC,1985,59-68.
[17]M.I. Darter et al, Joint Repair Methods for Portland cement concrete Pavement, National Cooperative Highway Research Program Report 281,1985.
[18]AASHTO,AASHTO Guide for Design of Pavement Structures,American Association of State Highway Transportation Official,Washington,DC,1993.
[19]张宁,钱振东,黄卫.水泥混凝土路面板下地基脱空状况的评定与分析[J].公路交通科技,2004,21(1):4-7
[20]曹东伟,胡长顺.水泥混凝土路面板底脱空判别方法研究[J].西安公路交通大学学报,1998,18(3):239-243.
[21]陈瑜,张起森.基于FWD检测结果旧路地基脱空状况的模糊评定[J].公路交通科技,2005,22(6):46-49.
[22]元松,张起森.基于FWD的水泥混凝土路面脱空与传荷作用机理动力有限元分析[J].公路工程,2007,32(6):70-75.
[23]王陶.基于遗传算法的刚性路面脱空判定[J].中国公路学报,2003,16(3):23-26.
[24]中华人民共和国交通部.公路水泥混凝土路面设计规范JTJD40-2002[S].北京:人民交通出版社,2002.
[25]曾海,张东长.地质雷达在混凝土路面板脱空检测中的应用探讨[J].公路交通科技,2005,3:72-74.
[26]Amara Loulizi. Development of Ground Penetrating Radar Signal Modeling and Implementation for Transportation Infrastructure Assessment [D].U.S. the Virginia Polytechnic Institute and State University.2001
[27]Maser, K.R., Scullion, T. Automated Detective of Pavement Layer Thickness and Subsurface Moisture Using Ground Penetrating Radar. TRB Paper.1991.
[28]Tom Scullion, Timo Saarenketo. Application of Ground Penetrating Radar Technology for Network and Project Level Pavement Management Systems. Prceedings of the Fourth International Conference on Managing Pavements.1998.
[29]邓世坤,王惠镰.探地雷达的正演合成与偏移处理[J].地球物理学报,1993.36(4):528-536.
[30]张蓓.路面结构层介电特性及其厚度反演分析的系统识别方法—路面雷达关键技术研究[D].重庆:重庆大学,2003.
[31]高翔.混凝土路面脱空红外成像检测及有限元数值模拟研究[D].武汉:武汉理工大学,2005.
[32]宋长柏.水泥混凝土路面脱空的振动模型分析[J].河北工业大学学报,2004,33(4):98-100.
[33]彭永恒,谭忆秋,张肖宁.弹性地基接缝板声振法脱空判定[J].岩土力学,2005,26(12):1981-1986.
[34]杨明理,余志刚.利用瞬态冲击法进行混凝土路面板脱空检测的研究[J].公路,2007,6:104-108.
[35]刘会勋,丁红岩.水泥混凝土路面脱空振动映象测试技术[J].振动与冲击2009,28(1):99-103
[36]罗立峰,周建春,郑国梁.水泥混凝土路面维修方案的研究[J].华南理工大学学报:自然科学版,1999,27(6):123-127.
[37]曹景民,赵宗启,陈明国等.采用压浆工艺处理水泥混凝土路面板底脱空[J].中南公路工程1999,24(3):22-24.
[38]中华人民共和国交通部.公路水泥混凝土路面养护技术规范JTJ073.1-2001[S].北京:人民交通出版社,2001.
[39]Bemanian, S.and P.Sebaaly. Cost-effective rehabilitation of Portland cement concrete pavement in Nevada.Transportation Research Reeord(1684).1999:156-164.
[40]Halil Ceylan, Reshma Mathews, et al. REHABILITATION OF CONCRETE PAVEMENTS UTILIZING RUBBLIZATION AND CRACK AND SEAT METHODS. IHRB Project TR-473. Iowa Highway Research Board.2005.
[41]吴国庆.旧水泥混凝土路面打裂施工控制参数及加铺层研究[D].济南:山东大学,2008.
[42]唐学军,苏卫国.路基刚度对冲击压实旧混凝土路面力学行为的影响分析[J].土木工程学报,2006,39(4):121-126.
[43]刘荥,刘效尧,孙江等.冲击碾压混凝土路面的破碎尺度[J].公路交通科技,2004.4:16-18.
[44]张玉宏.水泥混凝土路面碎石化综合技术研究[D].南京:东南大学,2006
[45]周洋.水泥混凝土路面板下脱空机理及其力学分析[D].长沙:湖南大学,2008.
[46]谈至明,谭福平.水泥混凝土路面板底脱空区水运动规律的分析模型[J].水动力学研究与进展,2008,23(3):281-286.
[47]张擎.考虑冲刷脱空的水泥混凝土路面设计研究[D].西安:长安大学,2009,6.
[48]韩西,陈上均,钟历等.砼路面板检测方法综述[J].重庆交通学院学报,2006,25(4):73-76.
[49]林有贵,凌桂芳,周书林等.水泥混凝土路面板底脱空检测方法研究[J].公路交通科技,2005,22(4):20-22.
[50]邱丽章,王端宜.水泥混凝土路面板底脱空的弯沉判据研究[J].公路,2006,11:5-9.
[51]王昌衡,李冬发,童宏贻.水泥混凝土路面板脱空的弯沉值影响因素分析[J].公路工程,2008,33(4):54-57.
[52]汤立群,胡哲,刘逸平等.脱空刚性路面的弯沉影响因素分析[J].暨南大学学报(自然科学版)2005,26(1):107-109.
[53]王显祎,凌建明.水泥混凝土机场道面板角脱空判定分析[J].同济大学学报(自然科学版)2007,35(5):612-616.
[54]杨群,郭忠印,陈立平.考虑板角脱空的公路隧道水泥路面设计方法[J].哈尔滨工业大学学报,2007,39(6):980-983.
[55]曾胜,曾小军,许佳.基于弯沉比的水泥混凝土路面板底脱空识别方法[J].长沙理工大学学报(自然科学版),2008,5(2):14-19.
[56]王鹏,黄莘.地质雷达在梅河高速公路路面脱空检测中的应用[J].公路交通科技,2007,12:12-15.
[57]曾胜,陈明宪.水泥混凝土路面脱空与传荷作用机理研究[J].铁道科学与工程学报2005,2(1):68-72.
[58]曾胜,张显安.水泥混凝土板下脱空状况时接缝处弯沉的影响分析[J].铁道科学与工程学报2005,2(6):31-35.
[59]肖兴强.水泥混凝土路面板底脱空和接缝传荷能力的关系[D].成都:西南交通大学,2007.
[60]Hansen, B.C etc. "Field effects of water pumping beneath concrete pavement slabs". Journal of Transportation Engineer.1991, V117.
[61]Huang, Y.H. "Pavement analysis of rigid pavements with pumping" PhD dissertation, Purdue University, West Lafayette, Ind.,1993.
[62]冯晋利.路面雷达在刚性路面脱空识别中的应用研究[D].郑州:郑州大学,2007
[63]齐月华.基于落锤式弯沉仪FWD评定刚性路面脱空状况[D].郑州:郑州大学,2007.
[64]薛忠军,王端宜,张肖宁等.水泥混凝土路面不同脱空检测方法识别率的对比验证[J].公路,2007,1:90-93.
[65]吕惠卿,张湘伟,成思源.水泥混凝土路面力学性能研究综述[J].重庆大学学报(自然科学版),2005,28(6):60-63.
[66]周玉民,谈至明,刘伯莹.水泥混凝土路面脱空状态下的荷载应力[J].同济大学学报(自然科学版)2007,35(3):341-345.
[67]余文成,谭波.汽车荷载作用下水泥混凝土路面力学性能分析[J].国水运,2008,8(9):239-243.
[68]Uddin,W.:Hackett, R.M. Pavement nondestructive evaluation using finite-element dynamic analysis. The international Society for Optical Engineering, v2945,1996, p282-293
[69]Owais Mustafa Siddiqui. Dynamic analysis of a modern urban bus for assessment of ride quality and dynamic wheel loads. MDD. Concordia University. Montreal, Quebec, Canada.2000.
[70]Doseung Lee. Development of roughness thresholds for the preventive maintenance of pavements based on dynamic loading considerations and damage analysis. PHD. Michigan State University. USA. 2001.
[71]王瑁成,邵敏.有限单元法基本原理和数值方法[M].北京:清华大学出版社,1996.
[72]龚曙光,谢桂兰ANSYS操作命令与参数化编程[M].北京:机械工业出版社,2004.
[73]郝文化.ANSYS土木工程应用实例[M].北京:中国水利水电出版社,2005.
[74]博弈创作室.ANSYS9.0经典产品基础教程与实例详解[M].北京:中国水利水电出版社,2006.
[75]阚前华,谭长建等.ANSYS高级工程应用实例分析与二次开发[M].北京:电子工业出版社,2006.
[76]周文献,孙立军,阚胜男.水泥混凝土路面脱空与压浆处治研究综述[J].公路,2004,12:194-198.
[77]王选仓,李春平.重载水泥混凝土路面研究[J].中国公路学报,1999,12(1):14-20.
[78]刘银生,杨东援.刚性路面有限元分析新见解[J].南公路工程,1999,24(4):10-12.
[79]田波,姚祖康,赵队家等.承受特重车辆作用的水泥混凝土路面应力分析[J].中国公路学报,2000,13(2):16-19.
[80]吴国雄,李拔,谢强.不平整混凝土路面板底响应的动力有限元分析[J].公路,2003,9:70-72.
[81]陈文,廖卫东,朱继东等.旧混凝土路面板底脱空的有限元分析[J].武汉理工大学学报,2003,25(12):23-25.
[82]巨锁基,李宇峙.局部脱空条件下CRCP荷载应力分析[J].公路交通科技,2005,22(5):12-15.
[83]蒋应军,戴经梁.基于温度应力等效的基顶当量回弹模量换算方法[J].公路交通科技,2006,23(7):10-13.
[84]管昌生,高翔.混凝土路面脱空区的有限元数值模拟[J].武汉理工大学学报,2006,28(3):80-82.
[85]蒋应军,戴经梁.刚性路面中关于温度应力计算问题[J].岩土工程学报,2007,29(6):837-842.
[86]张朝清,魏连雨,许爱丽等.整车通过混凝土路面板的计算机仿真[J].河北工业大学学报,2007,36(3):99-103.
[87]吴瑞麟,彭前程,简晓波.基于正交试验思想有限元分析的水泥砼路面板角脱空判定方法研究[J].工程力学2008,25(1):189-192.
[88]石春香,杨群,郭忠印.公路隧道水泥路面板底脱空有限元分析[J].公路交通科技,2008,25(11):6-10.
[89]谢强,何兆益,梁莉.水泥混凝土路面板角脱空的有限差分分析[J].重庆大学学报,2008,31(7):726-728.
[90]赵茂才.水泥混凝土路面板下脱空对使用寿命的影响分析[J].公路交通科技,2004,21(2):1-4.
[91]杨斌,陈栓发,胡长顺.重载及脱空耦合状态下混凝土路面疲劳寿命分析[J].中南公路工程2005,30(3):175-177.
[92]徐永杰,张长千.冲击压实机改造旧水泥混凝土路面的施工技术[J].路基工程,2006,4:93-94.
[93]肖维,王晓磊.水泥混凝土路面碎石化强度机理分析[J].养护机械&施工技术,2006,23(12):4-6.
[94]朱洪涛,范莹莹.碎石基层的塑性变形对混凝土路面力学行为的影响[J].中外公路,2008,28(4):53-58.
[95]胡长顺,阙云.冲击碾压动荷载下水泥混凝土路面结构的力学行为[J].交通运输工程学报,2008,8(4):40-46.
[96]雷丽君.水泥混凝土路面板脱空评定及压浆技术研究[D].西安:长安大学,2002.
[97]林国仁,四楞和五楞冲击压路机破碎路面板的力学效果对比研究[J].公路,2007,12:31-37.
[98]王海飞,徐京涛,王鑫.水泥混凝土路面碎石化施工机械[J].筑路机械与施工机械化,2006,12:1-3.
[99]王松根,李昶,张玉宏等.旧水泥混凝土路面MHB碎石化后强度机理分析[J].公路,2006,12:95-99.
[100]阎宗岭,高艳龙,冯学钢.水泥混凝土路面MHB法碎石化环境影响分析与评价[J].公路交通科技,2008,25(8):47-51.
[101]李昶,张玉宏,张建.冲击压实与MHB类设备对水泥混凝土路面破碎效果的对比[J].公路交通科技,2004,21(11):17-19.
[102]尚云龙.用水泥乳化沥青灌浆材料治理板底脱空[J].黑龙江交通科技,2007,6:1-2.
[103]郭成超,王复明,钟燕辉.水泥混凝土路面脱空高聚物注浆技术研究[J].公路,2008,10:232-236.
[104]李野,高伟.水泥混凝土路面板底脱空压浆材料研究[J].低温建筑材料,2007,6:20-21.
[105]A1-Suleiman, T.I; Saeed, N.A.; Widdup, J. Towards the development of an improved asphalt overlay design procedure for major roads in Dubai. Road and Transport Research, v 9, n 1, p 20-33,2000.
[106]Harvey J.T., Bejarano M.O. Performance of two overlay strategies under heavy vehicle simulator trafficking. Transportation Research Record, n 1769, p 123-133,2001.
[107]Tighe Susan, Haas Ralph, Li Ningyuan. Overlay performance in Canadian strategic highway research program's Long Term Pavement Performance study. Transportation Research Record, n 1778, p 191-200,2001
[108]Labi Samuel, Lamptey Geoffrey, and Konduri Sravanthi, et al. Analysis of long-term effectiveness of thin hot-mix asphaltic concrete overlay treatments. Transportation Research Record,, p 3-12,2005.
[109]Bennert, Thomas, and Maher. Evaluation of current state of flexible overlay design for rigid and composite pavements in the United States. Transportation Research Record, n 1991, p 97-108,2007.
[110]中华人民共和国交通部.公路沥青路面设计规范JTGD50-2006[S]北京:人民交通出版社,2006.
[111]符冠华.沥青混凝土加铺层改造旧水泥混凝土路面的应用研究[D].南京:东南大学,2001.
[112]Gupta, A.K; Jain, S.S; Singh, G.R. Computer Application for Design of Overlays Based on Deflection Data for Flexible Pavement. Indian Highways, V15, n1, Jan,1987,p 16-21.
[113]Ahmed Abdelazim Eltahan. A Mechanistic-Empirical Approach to The Development of A Stochastic Reflection Crack Prediction Model for Flexible Pavement Overlays. Texas A&M University, PHD, December 1996.
[114]Owusu-Antwi, Emmanuel B; Khazanovich, Lev; Titus-Glover, Leslie. Mechanistic-based model for predicting reflective cracking in asphalt concrete-overlaid pavements. Transportation Research Record, n 1629, Nov,1998, p234-241.
[115]Khalid Ahmad Ghuzlan. Fatigue damage analysis in asphalt concrete mixtures based upon dissipated energy concepts. PHD. University of Illinois at Urbana-Champaign.2001.
[116]杨斌.旧水泥混凝土路面沥青加铺层结构研究[D].西安:长安大学,2005.
[117]周鑫.薄层沥青加铺层间技术研究[D].西安:长安大学,2006,6.
[118]祝海燕.沥青加铺旧水泥混凝土路面复合结构研究[D].西安:长安大学,2006.
[119]徐纬.旧水泥混凝土路面沥青加铺层工作状态及力学分析研究[D].西安:长安大学,2007.
[120]袁玉卿.旧水泥路面沥青加铺层间理论与APP油毡防裂技术[D].西安:长安大学,2007.
[121]陈飞,胡光伟.旧水泥混凝土路面上沥青加铺层力学分析的有限元法[J].公路,2001,12:38-40.
[122]武建民,伍石生.用三维有限元方法评价带接缝的旧水泥混凝土路面罩面[J].长安大学学报:自然科学版,2002,22(1):10-13.
[123]金文成,蒋明星,胡小弟.水泥砼路面沥青加罩层间接触条件不同时的力学响应分析[J].中南公路工程,2003,28(2):11-14.
[124]张开鹏,谭华,陈小庭.旧水泥混凝土路面沥青混凝土罩面的三维瞬态有限元分析[J].公路,2005,8:250-253.
[125]祝海燕,王选仓.旧水泥路面薄层沥青罩面结构层间剪应力分析[J].辽宁省交通高等专科学校学报,2006,8(4):1-2.
[126]祝海燕,王选仓,曹宝贵.复合式路面中夹层对旧水泥混凝土板荷载应力影响分析[J].公路,2006,12:100-103.
[127]王朝辉,王选仓,马士宾等.具有不确定属性的道路养护决策优化[J].河北工业大学学报,2006,35(3):108-111.
[128]王朝辉,王选仓.灰色关联度组合赋权在道路养护优化中的应用[J].河北工业大学学报,2006,35(6):106-110.
[129]祝海燕,王选仓,曹宝贵.路基刚度对复合式路面结构内力影响分析[J].路基工程,2007,5:32-34.
[130]傅珍,王选仓,陈星光等.拓宽路基差异沉降特性和影响因素[J].交通运输工程学报,2007,7(1):54-57.
[131]祝海燕,李书,王选仓等.沥青加铺旧混凝土路面复合结构行为分析[J].沈阳建筑大学学报(自然科学版),2007,23(5):723-727.
[132]马士宾,张绍阳,王选仓等.道路环境影响综合评价指标权重确定方法[J].长安大学学报(自然科学版),2007,27(4):37-41.
[133]王朝辉,王选仓,徐纬等.复合式路面沥青混凝土加铺层设计方法探讨[J].公路,2007,6:96-101.
[134]马士宾,王选仓,王朝辉.基于集对论的路面使用性能变权综合评价方法[J].武汉理工大学报(交通科学与工程版),2007,31(6):969-972.
[135]祝海燕,王选仓.沥青加铺混凝土路面的实用计算方法[J].河北工业大学学报,2007,36(6):106-110.
[136]王朝辉,王选仓.复合式路面沥青混凝土层压缩量研究[J].公路,2007,7:103-108.
[137]姜献民,王选仓,柳永江等.贫混凝土基层水泥混凝土路面温度应力分析[J].公路,2008,7:123-127.
[138]王楠,王芳,王选仓等.水泥混凝土加铺层“黑白”中间层结构的荷载应力分析[J].公路,2008,7:131-135.
[139]王芳,王选仓,台电仓等.水泥混凝土加铺层贫混凝土基层荷载应力分析[J].公路,2008,7:135-139.
[140]柳永江,王选仓,顾迎春等.基于唧泥高度的水泥混凝土板底脱空评价方法研究[J].公路,2008,7:140-142.
[141]王朝辉,王选仓.基于沥青加铺层结构疲劳寿命的夹层最佳位置确定[J].中国公路学报,2008,21(1):29-34.
[142]张绍阳,马玉兰,王选仓.基于关联分析的路面病害成因确定方法[J].中国公路学报,2008,21(2):98-103.
[143]祝海燕,王选仓,杨殿海等.弹性地基上有限尺寸复合路面板受力分析[J].沈阳建筑大学学报(自然 科学版),2008,24(1):6-10.
[144]王朝辉,王选仓,杨维国.不同层位格栅加筋的沥青混凝土抗车辙性能研究[J].长沙交通学院学报,2008,24(4):27-31.
[145]王选仓,王朝辉,张燕萍.复合式路面层间处治技术研究与发展[J].筑路机械与施工机械化,2008,25(2):9-12.
[146]袁玉卿,王选仓,王朝辉.路面加铺层间温度与水影响研究[J].筑路机械与施工机械化,2008,25(2):17-21.
[147]张绍阳,王选仓.基于Petri网的公路施工资源总体优化方法[J].长安大学学报(自然科学版),2008,27(4):33-36.
[148]祝海燕,王选仓,曹宝贵.弹性地基上复合路面的受力分析[J].长安大学学报(自然科学版),2008,28(3):25-29.
[149]王朝辉,王选仓,杨维国.格栅加筋沥青加铺层结构轮载疲劳模拟对比试验[J].长安大学学报(自然科学版),2008,28(6):16-30.
[150]王朝辉,王选仓,马士宾.基于区间数逼近法的路面使用性能综合评价[J].公路交通科技,2009,16(1):21-25.
[2]Neal,B.F.(1980). Model slab faulting study. FHWA/CA/TL-80/23, California Dept. of Transp. Sacramento, Calif.
[3]PCA, Thickness and Construction of Joint for Concrete Highway Street Pavements, Portland Cement Association,1084.
[4]Dempsey, B.J., "Laboratory and Field Studies of Channeling and Pumping in Pavement Systems," Paper presented at PLARC Seminar, Paris, France,1983.
[5]Phu, N.C, J.P Christory and J.Ray, The Hydromechanics of Pumping in Concrete Pavements: Modeling and Prevention Pumping, Appendix I, Combating Concrete Pavement Pumping:State-of-the-Art and Recommendations, PLARC, Technical Committee on Concrete Roads,1986.
[6]NCHRP. Calibrated Mechanistic Structural Analysis Procedures for Pavement, University of Illinois at Urbana-Champaign,1990
[7]沙爱民,胡力群.路面基层材料抗冲刷性能试验研究[J].岩土工程学报,2002,24(3):276-280.
[8]Cheung, Y.K. and Zienkiewicz. O. C, Plates and tanks on elastic foundation an application of finite element method. International Journal of Solids and Structures, Vol,1,1965.
[9]Wang,S. K.,Sargious, M. and Cheung,Y.K. Advanced analysis of rigid pavements. Transportation Engineering Journal, ASCE,1974.
[10]黄仰贤.路面分析与设计[M].北京:人民交通出版社,1998.
[11]姚祖康.路面[M].北京:人民交通出版社,1999.
[12]郑传超,王秉纲,夏永旭.道路结构力学计算[M].北京:人民交通出版社,2003.
[13]唐伯明.落锤式弯沉仪在路面结构状况评定中的应用[D].南京:东南大学,1990.
[14]王陶,王复明,王钊.弹性地基接缝板模量反演和地基脱空判定[J].岩土力学,2003,24(2):233-236.
[15]万捷.水泥混凝土路面板底脱空检测及防治技术研究[D].西安:长安大学,2007.
[16]Crovetti, J.A. and M.I.Darter.Void Detection for Jointed Concrete Pavements. Transportation Research Record 1040, Washington,DC,1985,59-68.
[17]M.I. Darter et al, Joint Repair Methods for Portland cement concrete Pavement, National Cooperative Highway Research Program Report 281,1985.
[18]AASHTO,AASHTO Guide for Design of Pavement Structures,American Association of State Highway Transportation Official,Washington,DC,1993.
[19]张宁,钱振东,黄卫.水泥混凝土路面板下地基脱空状况的评定与分析[J].公路交通科技,2004,21(1):4-7
[20]曹东伟,胡长顺.水泥混凝土路面板底脱空判别方法研究[J].西安公路交通大学学报,1998,18(3):239-243.
[21]陈瑜,张起森.基于FWD检测结果旧路地基脱空状况的模糊评定[J].公路交通科技,2005,22(6):46-49.
[22]元松,张起森.基于FWD的水泥混凝土路面脱空与传荷作用机理动力有限元分析[J].公路工程,2007,32(6):70-75.
[23]王陶.基于遗传算法的刚性路面脱空判定[J].中国公路学报,2003,16(3):23-26.
[24]中华人民共和国交通部.公路水泥混凝土路面设计规范JTJD40-2002[S].北京:人民交通出版社,2002.
[25]曾海,张东长.地质雷达在混凝土路面板脱空检测中的应用探讨[J].公路交通科技,2005,3:72-74.
[26]Amara Loulizi. Development of Ground Penetrating Radar Signal Modeling and Implementation for Transportation Infrastructure Assessment [D].U.S. the Virginia Polytechnic Institute and State University.2001
[27]Maser, K.R., Scullion, T. Automated Detective of Pavement Layer Thickness and Subsurface Moisture Using Ground Penetrating Radar. TRB Paper.1991.
[28]Tom Scullion, Timo Saarenketo. Application of Ground Penetrating Radar Technology for Network and Project Level Pavement Management Systems. Prceedings of the Fourth International Conference on Managing Pavements.1998.
[29]邓世坤,王惠镰.探地雷达的正演合成与偏移处理[J].地球物理学报,1993.36(4):528-536.
[30]张蓓.路面结构层介电特性及其厚度反演分析的系统识别方法—路面雷达关键技术研究[D].重庆:重庆大学,2003.
[31]高翔.混凝土路面脱空红外成像检测及有限元数值模拟研究[D].武汉:武汉理工大学,2005.
[32]宋长柏.水泥混凝土路面脱空的振动模型分析[J].河北工业大学学报,2004,33(4):98-100.
[33]彭永恒,谭忆秋,张肖宁.弹性地基接缝板声振法脱空判定[J].岩土力学,2005,26(12):1981-1986.
[34]杨明理,余志刚.利用瞬态冲击法进行混凝土路面板脱空检测的研究[J].公路,2007,6:104-108.
[35]刘会勋,丁红岩.水泥混凝土路面脱空振动映象测试技术[J].振动与冲击2009,28(1):99-103
[36]罗立峰,周建春,郑国梁.水泥混凝土路面维修方案的研究[J].华南理工大学学报:自然科学版,1999,27(6):123-127.
[37]曹景民,赵宗启,陈明国等.采用压浆工艺处理水泥混凝土路面板底脱空[J].中南公路工程1999,24(3):22-24.
[38]中华人民共和国交通部.公路水泥混凝土路面养护技术规范JTJ073.1-2001[S].北京:人民交通出版社,2001.
[39]Bemanian, S.and P.Sebaaly. Cost-effective rehabilitation of Portland cement concrete pavement in Nevada.Transportation Research Reeord(1684).1999:156-164.
[40]Halil Ceylan, Reshma Mathews, et al. REHABILITATION OF CONCRETE PAVEMENTS UTILIZING RUBBLIZATION AND CRACK AND SEAT METHODS. IHRB Project TR-473. Iowa Highway Research Board.2005.
[41]吴国庆.旧水泥混凝土路面打裂施工控制参数及加铺层研究[D].济南:山东大学,2008.
[42]唐学军,苏卫国.路基刚度对冲击压实旧混凝土路面力学行为的影响分析[J].土木工程学报,2006,39(4):121-126.
[43]刘荥,刘效尧,孙江等.冲击碾压混凝土路面的破碎尺度[J].公路交通科技,2004.4:16-18.
[44]张玉宏.水泥混凝土路面碎石化综合技术研究[D].南京:东南大学,2006
[45]周洋.水泥混凝土路面板下脱空机理及其力学分析[D].长沙:湖南大学,2008.
[46]谈至明,谭福平.水泥混凝土路面板底脱空区水运动规律的分析模型[J].水动力学研究与进展,2008,23(3):281-286.
[47]张擎.考虑冲刷脱空的水泥混凝土路面设计研究[D].西安:长安大学,2009,6.
[48]韩西,陈上均,钟历等.砼路面板检测方法综述[J].重庆交通学院学报,2006,25(4):73-76.
[49]林有贵,凌桂芳,周书林等.水泥混凝土路面板底脱空检测方法研究[J].公路交通科技,2005,22(4):20-22.
[50]邱丽章,王端宜.水泥混凝土路面板底脱空的弯沉判据研究[J].公路,2006,11:5-9.
[51]王昌衡,李冬发,童宏贻.水泥混凝土路面板脱空的弯沉值影响因素分析[J].公路工程,2008,33(4):54-57.
[52]汤立群,胡哲,刘逸平等.脱空刚性路面的弯沉影响因素分析[J].暨南大学学报(自然科学版)2005,26(1):107-109.
[53]王显祎,凌建明.水泥混凝土机场道面板角脱空判定分析[J].同济大学学报(自然科学版)2007,35(5):612-616.
[54]杨群,郭忠印,陈立平.考虑板角脱空的公路隧道水泥路面设计方法[J].哈尔滨工业大学学报,2007,39(6):980-983.
[55]曾胜,曾小军,许佳.基于弯沉比的水泥混凝土路面板底脱空识别方法[J].长沙理工大学学报(自然科学版),2008,5(2):14-19.
[56]王鹏,黄莘.地质雷达在梅河高速公路路面脱空检测中的应用[J].公路交通科技,2007,12:12-15.
[57]曾胜,陈明宪.水泥混凝土路面脱空与传荷作用机理研究[J].铁道科学与工程学报2005,2(1):68-72.
[58]曾胜,张显安.水泥混凝土板下脱空状况时接缝处弯沉的影响分析[J].铁道科学与工程学报2005,2(6):31-35.
[59]肖兴强.水泥混凝土路面板底脱空和接缝传荷能力的关系[D].成都:西南交通大学,2007.
[60]Hansen, B.C etc. "Field effects of water pumping beneath concrete pavement slabs". Journal of Transportation Engineer.1991, V117.
[61]Huang, Y.H. "Pavement analysis of rigid pavements with pumping" PhD dissertation, Purdue University, West Lafayette, Ind.,1993.
[62]冯晋利.路面雷达在刚性路面脱空识别中的应用研究[D].郑州:郑州大学,2007
[63]齐月华.基于落锤式弯沉仪FWD评定刚性路面脱空状况[D].郑州:郑州大学,2007.
[64]薛忠军,王端宜,张肖宁等.水泥混凝土路面不同脱空检测方法识别率的对比验证[J].公路,2007,1:90-93.
[65]吕惠卿,张湘伟,成思源.水泥混凝土路面力学性能研究综述[J].重庆大学学报(自然科学版),2005,28(6):60-63.
[66]周玉民,谈至明,刘伯莹.水泥混凝土路面脱空状态下的荷载应力[J].同济大学学报(自然科学版)2007,35(3):341-345.
[67]余文成,谭波.汽车荷载作用下水泥混凝土路面力学性能分析[J].国水运,2008,8(9):239-243.
[68]Uddin,W.:Hackett, R.M. Pavement nondestructive evaluation using finite-element dynamic analysis. The international Society for Optical Engineering, v2945,1996, p282-293
[69]Owais Mustafa Siddiqui. Dynamic analysis of a modern urban bus for assessment of ride quality and dynamic wheel loads. MDD. Concordia University. Montreal, Quebec, Canada.2000.
[70]Doseung Lee. Development of roughness thresholds for the preventive maintenance of pavements based on dynamic loading considerations and damage analysis. PHD. Michigan State University. USA. 2001.
[71]王瑁成,邵敏.有限单元法基本原理和数值方法[M].北京:清华大学出版社,1996.
[72]龚曙光,谢桂兰ANSYS操作命令与参数化编程[M].北京:机械工业出版社,2004.
[73]郝文化.ANSYS土木工程应用实例[M].北京:中国水利水电出版社,2005.
[74]博弈创作室.ANSYS9.0经典产品基础教程与实例详解[M].北京:中国水利水电出版社,2006.
[75]阚前华,谭长建等.ANSYS高级工程应用实例分析与二次开发[M].北京:电子工业出版社,2006.
[76]周文献,孙立军,阚胜男.水泥混凝土路面脱空与压浆处治研究综述[J].公路,2004,12:194-198.
[77]王选仓,李春平.重载水泥混凝土路面研究[J].中国公路学报,1999,12(1):14-20.
[78]刘银生,杨东援.刚性路面有限元分析新见解[J].南公路工程,1999,24(4):10-12.
[79]田波,姚祖康,赵队家等.承受特重车辆作用的水泥混凝土路面应力分析[J].中国公路学报,2000,13(2):16-19.
[80]吴国雄,李拔,谢强.不平整混凝土路面板底响应的动力有限元分析[J].公路,2003,9:70-72.
[81]陈文,廖卫东,朱继东等.旧混凝土路面板底脱空的有限元分析[J].武汉理工大学学报,2003,25(12):23-25.
[82]巨锁基,李宇峙.局部脱空条件下CRCP荷载应力分析[J].公路交通科技,2005,22(5):12-15.
[83]蒋应军,戴经梁.基于温度应力等效的基顶当量回弹模量换算方法[J].公路交通科技,2006,23(7):10-13.
[84]管昌生,高翔.混凝土路面脱空区的有限元数值模拟[J].武汉理工大学学报,2006,28(3):80-82.
[85]蒋应军,戴经梁.刚性路面中关于温度应力计算问题[J].岩土工程学报,2007,29(6):837-842.
[86]张朝清,魏连雨,许爱丽等.整车通过混凝土路面板的计算机仿真[J].河北工业大学学报,2007,36(3):99-103.
[87]吴瑞麟,彭前程,简晓波.基于正交试验思想有限元分析的水泥砼路面板角脱空判定方法研究[J].工程力学2008,25(1):189-192.
[88]石春香,杨群,郭忠印.公路隧道水泥路面板底脱空有限元分析[J].公路交通科技,2008,25(11):6-10.
[89]谢强,何兆益,梁莉.水泥混凝土路面板角脱空的有限差分分析[J].重庆大学学报,2008,31(7):726-728.
[90]赵茂才.水泥混凝土路面板下脱空对使用寿命的影响分析[J].公路交通科技,2004,21(2):1-4.
[91]杨斌,陈栓发,胡长顺.重载及脱空耦合状态下混凝土路面疲劳寿命分析[J].中南公路工程2005,30(3):175-177.
[92]徐永杰,张长千.冲击压实机改造旧水泥混凝土路面的施工技术[J].路基工程,2006,4:93-94.
[93]肖维,王晓磊.水泥混凝土路面碎石化强度机理分析[J].养护机械&施工技术,2006,23(12):4-6.
[94]朱洪涛,范莹莹.碎石基层的塑性变形对混凝土路面力学行为的影响[J].中外公路,2008,28(4):53-58.
[95]胡长顺,阙云.冲击碾压动荷载下水泥混凝土路面结构的力学行为[J].交通运输工程学报,2008,8(4):40-46.
[96]雷丽君.水泥混凝土路面板脱空评定及压浆技术研究[D].西安:长安大学,2002.
[97]林国仁,四楞和五楞冲击压路机破碎路面板的力学效果对比研究[J].公路,2007,12:31-37.
[98]王海飞,徐京涛,王鑫.水泥混凝土路面碎石化施工机械[J].筑路机械与施工机械化,2006,12:1-3.
[99]王松根,李昶,张玉宏等.旧水泥混凝土路面MHB碎石化后强度机理分析[J].公路,2006,12:95-99.
[100]阎宗岭,高艳龙,冯学钢.水泥混凝土路面MHB法碎石化环境影响分析与评价[J].公路交通科技,2008,25(8):47-51.
[101]李昶,张玉宏,张建.冲击压实与MHB类设备对水泥混凝土路面破碎效果的对比[J].公路交通科技,2004,21(11):17-19.
[102]尚云龙.用水泥乳化沥青灌浆材料治理板底脱空[J].黑龙江交通科技,2007,6:1-2.
[103]郭成超,王复明,钟燕辉.水泥混凝土路面脱空高聚物注浆技术研究[J].公路,2008,10:232-236.
[104]李野,高伟.水泥混凝土路面板底脱空压浆材料研究[J].低温建筑材料,2007,6:20-21.
[105]A1-Suleiman, T.I; Saeed, N.A.; Widdup, J. Towards the development of an improved asphalt overlay design procedure for major roads in Dubai. Road and Transport Research, v 9, n 1, p 20-33,2000.
[106]Harvey J.T., Bejarano M.O. Performance of two overlay strategies under heavy vehicle simulator trafficking. Transportation Research Record, n 1769, p 123-133,2001.
[107]Tighe Susan, Haas Ralph, Li Ningyuan. Overlay performance in Canadian strategic highway research program's Long Term Pavement Performance study. Transportation Research Record, n 1778, p 191-200,2001
[108]Labi Samuel, Lamptey Geoffrey, and Konduri Sravanthi, et al. Analysis of long-term effectiveness of thin hot-mix asphaltic concrete overlay treatments. Transportation Research Record,, p 3-12,2005.
[109]Bennert, Thomas, and Maher. Evaluation of current state of flexible overlay design for rigid and composite pavements in the United States. Transportation Research Record, n 1991, p 97-108,2007.
[110]中华人民共和国交通部.公路沥青路面设计规范JTGD50-2006[S]北京:人民交通出版社,2006.
[111]符冠华.沥青混凝土加铺层改造旧水泥混凝土路面的应用研究[D].南京:东南大学,2001.
[112]Gupta, A.K; Jain, S.S; Singh, G.R. Computer Application for Design of Overlays Based on Deflection Data for Flexible Pavement. Indian Highways, V15, n1, Jan,1987,p 16-21.
[113]Ahmed Abdelazim Eltahan. A Mechanistic-Empirical Approach to The Development of A Stochastic Reflection Crack Prediction Model for Flexible Pavement Overlays. Texas A&M University, PHD, December 1996.
[114]Owusu-Antwi, Emmanuel B; Khazanovich, Lev; Titus-Glover, Leslie. Mechanistic-based model for predicting reflective cracking in asphalt concrete-overlaid pavements. Transportation Research Record, n 1629, Nov,1998, p234-241.
[115]Khalid Ahmad Ghuzlan. Fatigue damage analysis in asphalt concrete mixtures based upon dissipated energy concepts. PHD. University of Illinois at Urbana-Champaign.2001.
[116]杨斌.旧水泥混凝土路面沥青加铺层结构研究[D].西安:长安大学,2005.
[117]周鑫.薄层沥青加铺层间技术研究[D].西安:长安大学,2006,6.
[118]祝海燕.沥青加铺旧水泥混凝土路面复合结构研究[D].西安:长安大学,2006.
[119]徐纬.旧水泥混凝土路面沥青加铺层工作状态及力学分析研究[D].西安:长安大学,2007.
[120]袁玉卿.旧水泥路面沥青加铺层间理论与APP油毡防裂技术[D].西安:长安大学,2007.
[121]陈飞,胡光伟.旧水泥混凝土路面上沥青加铺层力学分析的有限元法[J].公路,2001,12:38-40.
[122]武建民,伍石生.用三维有限元方法评价带接缝的旧水泥混凝土路面罩面[J].长安大学学报:自然科学版,2002,22(1):10-13.
[123]金文成,蒋明星,胡小弟.水泥砼路面沥青加罩层间接触条件不同时的力学响应分析[J].中南公路工程,2003,28(2):11-14.
[124]张开鹏,谭华,陈小庭.旧水泥混凝土路面沥青混凝土罩面的三维瞬态有限元分析[J].公路,2005,8:250-253.
[125]祝海燕,王选仓.旧水泥路面薄层沥青罩面结构层间剪应力分析[J].辽宁省交通高等专科学校学报,2006,8(4):1-2.
[126]祝海燕,王选仓,曹宝贵.复合式路面中夹层对旧水泥混凝土板荷载应力影响分析[J].公路,2006,12:100-103.
[127]王朝辉,王选仓,马士宾等.具有不确定属性的道路养护决策优化[J].河北工业大学学报,2006,35(3):108-111.
[128]王朝辉,王选仓.灰色关联度组合赋权在道路养护优化中的应用[J].河北工业大学学报,2006,35(6):106-110.
[129]祝海燕,王选仓,曹宝贵.路基刚度对复合式路面结构内力影响分析[J].路基工程,2007,5:32-34.
[130]傅珍,王选仓,陈星光等.拓宽路基差异沉降特性和影响因素[J].交通运输工程学报,2007,7(1):54-57.
[131]祝海燕,李书,王选仓等.沥青加铺旧混凝土路面复合结构行为分析[J].沈阳建筑大学学报(自然科学版),2007,23(5):723-727.
[132]马士宾,张绍阳,王选仓等.道路环境影响综合评价指标权重确定方法[J].长安大学学报(自然科学版),2007,27(4):37-41.
[133]王朝辉,王选仓,徐纬等.复合式路面沥青混凝土加铺层设计方法探讨[J].公路,2007,6:96-101.
[134]马士宾,王选仓,王朝辉.基于集对论的路面使用性能变权综合评价方法[J].武汉理工大学报(交通科学与工程版),2007,31(6):969-972.
[135]祝海燕,王选仓.沥青加铺混凝土路面的实用计算方法[J].河北工业大学学报,2007,36(6):106-110.
[136]王朝辉,王选仓.复合式路面沥青混凝土层压缩量研究[J].公路,2007,7:103-108.
[137]姜献民,王选仓,柳永江等.贫混凝土基层水泥混凝土路面温度应力分析[J].公路,2008,7:123-127.
[138]王楠,王芳,王选仓等.水泥混凝土加铺层“黑白”中间层结构的荷载应力分析[J].公路,2008,7:131-135.
[139]王芳,王选仓,台电仓等.水泥混凝土加铺层贫混凝土基层荷载应力分析[J].公路,2008,7:135-139.
[140]柳永江,王选仓,顾迎春等.基于唧泥高度的水泥混凝土板底脱空评价方法研究[J].公路,2008,7:140-142.
[141]王朝辉,王选仓.基于沥青加铺层结构疲劳寿命的夹层最佳位置确定[J].中国公路学报,2008,21(1):29-34.
[142]张绍阳,马玉兰,王选仓.基于关联分析的路面病害成因确定方法[J].中国公路学报,2008,21(2):98-103.
[143]祝海燕,王选仓,杨殿海等.弹性地基上有限尺寸复合路面板受力分析[J].沈阳建筑大学学报(自然 科学版),2008,24(1):6-10.
[144]王朝辉,王选仓,杨维国.不同层位格栅加筋的沥青混凝土抗车辙性能研究[J].长沙交通学院学报,2008,24(4):27-31.
[145]王选仓,王朝辉,张燕萍.复合式路面层间处治技术研究与发展[J].筑路机械与施工机械化,2008,25(2):9-12.
[146]袁玉卿,王选仓,王朝辉.路面加铺层间温度与水影响研究[J].筑路机械与施工机械化,2008,25(2):17-21.
[147]张绍阳,王选仓.基于Petri网的公路施工资源总体优化方法[J].长安大学学报(自然科学版),2008,27(4):33-36.
[148]祝海燕,王选仓,曹宝贵.弹性地基上复合路面的受力分析[J].长安大学学报(自然科学版),2008,28(3):25-29.
[149]王朝辉,王选仓,杨维国.格栅加筋沥青加铺层结构轮载疲劳模拟对比试验[J].长安大学学报(自然科学版),2008,28(6):16-30.
[150]王朝辉,王选仓,马士宾.基于区间数逼近法的路面使用性能综合评价[J].公路交通科技,2009,16(1):21-25.