振动压实对排水性沥青混合料适应性研究
|
摘要
排水性沥青混合料为典型的骨架—空隙结构混合料,压实后其空隙率在20%左右,具有优良的排水性能和降低噪声性能,可显著提高雨天行车安全性。但排水性沥青混合料排水降噪性能的发挥主要取决于其内部结构,而结构又与采用的成型方式密切相关;成型方式不同,其内部结构可能会有较大差异,从而会影响其性能的发挥。本文从排水沥青混合料的细观结构入手,以振动压实为主线,对排水性沥青混合料细观力学特性、关键原材选择方法、振动压实特性、级配优化、路用性能及压实工艺进行了系统研究,并通过验证试验和实体工程铺筑,对室内研究成果进行了验证,为振动法应用于排水性沥青混合料设计和工程应用提供了理论指导。
通过对排水性沥青混合料组成结构特点和使用特性分析,结合国内外已有研究成果,提出了排水性沥青混合料粗集料、细集料技术标准;针对影响排水性沥青混合料性能的高粘改性沥青,基于层次分析法和模糊数学理论,构建了性能影响因素综合评价模型,提出了高粘改性沥青综合评价指标权重值,建立了高粘改性沥青综合评价方法,优选出了适合实体工程的改性方案。
基于排水性沥青混合料细观结构组成特点,采用离散元方法,构建了能反映振动压实后排水性沥青混合料的颗粒承载运动以及非连续性的理论结构模型,结合单轴贯入试验模拟,研究了不同成型方式、材料参数对排水性沥青混合料细观力学特性的影响规律,提出采用振动压实成型、增加沥青粘度与改善颗粒表面特性可使颗粒配位数提高、混合料内部应力分布均匀,有利于提高排水性沥青混合料抗变形能力。
分析了振动压路机压实特性与表面振动击实仪动力学特性,基于弹跳模型,推导出了表面振动压实仪振动消耗能方程:E K1A0fM gT;使用振动压实仪,系统研究了线压力、频率、振幅对排水性沥青混合料压实效果的影响规律,结合正交灰关联分析方法,提出了影响排水性沥青混合料性能的各配置因素的主次顺序:夹角>频率>上下车配重,以及最佳振动参数组合:H35J120S4X5。
使用表面振动压实仪,通过逐级振动填充试验,进行了排水性沥青混合料级配优化,得到了典型排水性沥青混合料振动压实状态下粗细集料分界筛孔为4.75mm,优化了不同粗、细集料组成的最佳比例,推导出了能反映粗集料骨架稳定特征的微观强度指标与粗集料的体积指标、不同组分的性质(包括密度、含量和当量半径)关系的粗集料剪切模量比GR(振动压实状态下粗集料混合料的剪切模量与干插捣紧装状态下粗集料的剪切模量之比)。
基于优化得到的排水性沥青混合料级配,系统研究了各因素对混合料路用性能的影响规律,证实了振动和揉搓压实较传统马歇尔锤击压实更有利于排水性沥青混合料嵌挤骨架结构的形成,且试验结果表明,振动压实成型试件的动稳定度为静压成型试件的1.532倍。
通过验证试验及实体工程铺筑,分析了振动压实工艺对排水性沥青混合料压实效果的影响规律,提出有限振动压实遍数不会造成混合料矿料级配的严重衰变,优化了排水性沥青混合料振动压实工艺,即:先用12t双钢轮振动压路机以高频、低幅方式振动3遍,然后采用大于11t的双钢轮振动压路机静压2遍,消除轮迹印,两道工序应衔接紧凑。
As a typical of skeleton-gap structure mixtures, the air void of porous asphalt mixture isusually around20%after compaction. The porous asphalt mixture pavement has excellentdrainage performance with low-noise. It can also significantly improve the safety of driving inthe rain. However, the noise reduction performance mainly depends on internal structure ofthe mixture, which is closely related with the compacting method. Different compactingmethods make discrepancy interior structures, which may affect the performance of mixture.Based on the microstructure perspective of porous asphalt mixture, this article analyzed thevibratory compaction as the main research line. The micromechanics characteristics forporous asphalt mixtures, key raw material selection method, vibration compactioncharacteristics, gradation optimization, road performance and compacting technology werestudied in depth. The achievementswere verified in laboratory experiment and the verificationtest that provide the theoretical guidance for the application of vibration compactiontechnology in the design and application of porous asphalt mixture.
Through study of the composition and characteristics of porous asphalt mixture,combining with the existing research results at home and abroad, the technical standards ofcoarse aggregate and fine aggregate for porous asphalt mixture were suggested. For theeffects high sticky asphalt to porous asphalt mixture performance, based on AHP and fuzzymathematics theory, comprehensive evaluation model of factors that affect performance wasconstructed, the comprehensive evaluation index weight value of high viscosity modifiedasphalt was proposed, the comprehensive evaluation method of high-viscosity modifiedasphalt was established, and the modification schemes which are suitable for real engineeringwas selected optimizedly.
Based on the microstructure characteristics of porous asphalt mixture and the discreteelement method, the non-continuous theoretical model that can reflect the movement ofparticles in porous asphalt mixture was constructed. Combined with uniaxial penetration testin the way of numerical virtual simulations, the influenceof Compacting method and materialparameters on microstructure perspective of porous asphalt mixture were analyzed. By adopting vibrating compacting method, increasing bitumen viscosity and improving surfacecharacteristics, homogenizing the internal stress distribution in the mixture can improve thedeformation resistance of the porous asphalt mixture.
Analyzing the relationship between the compaction characteristics of vibratory roller anddynamic properties of surface vibration compaction instrument, the vibration energyconsumption equation of the surface vibration compactor was deduced:E K1A0fM gT.Using a vibrating compactor, the effect of the law that line pressure, frequency, amplitude onporous asphalt mixture compaction were systematically studied. Combined with orthogonalgray relational analysis, the configuration factors of primary and secondary order whichinfluence the performances of the porous asphalt mixture is: angle> frequency> on and off thecounterweight, as well as the optimal vibration parameters combination: H35J120S4X5.
By using pavement vibration compactor and the experiments of vibration andalternativein classification, the drainage asphalt mixture gradation had been optimizated. Theresearch got the conclusions as follows: the vibratory compaction state boundaries sieveaggregate size for porous asphalt mixture is4.75mm, the composition of different coarse andfine aggregates has optimized, the composed of the best ratio deduced reflect stable coarseaggregate skeleton microscopic characteristics of coarse aggregate strength index and thevolume indicator different nature of the components (including density, content andequivalent radius) relations coarse aggregate shear modulus ratio GR (vibratory compactionstate mixture of coarse aggregate shear modulus tamping plug fitted with dry coarse aggregatestate of the shear modulus) were deduced.
Based on the optimized gradation for porous asphalt mixture, the effects of differentfactors on pavement performance were studied in a systematic way.The results show that thevibrating compaction and rubbing compaction are better than Maxell compaction at formingthe interlocking framework of porous asphalt mixture; and the dynamic stability value ofvibrating compaction specimens are1.532times of pressure shaping one.
Trough verification test and pavement construction, the influence of vibratingcompaction craft on the porous asphalt mixture was studied. The results show that withincertain vibrating compaction times, the porous asphalt mixture gradation won't change much more, and the vibrating compaction craft for porous asphalt mixture is optimized: at first, a12t twin steel wheel vibration roller vibrating rolls the asphalt mixture in a highfrequency-low amplitude way for3times, then a twin steel wheel vibration roller over11tpressure rolls for2times to eliminate the wheel path, and the two crafts should be compactconvergence.
通过对排水性沥青混合料组成结构特点和使用特性分析,结合国内外已有研究成果,提出了排水性沥青混合料粗集料、细集料技术标准;针对影响排水性沥青混合料性能的高粘改性沥青,基于层次分析法和模糊数学理论,构建了性能影响因素综合评价模型,提出了高粘改性沥青综合评价指标权重值,建立了高粘改性沥青综合评价方法,优选出了适合实体工程的改性方案。
基于排水性沥青混合料细观结构组成特点,采用离散元方法,构建了能反映振动压实后排水性沥青混合料的颗粒承载运动以及非连续性的理论结构模型,结合单轴贯入试验模拟,研究了不同成型方式、材料参数对排水性沥青混合料细观力学特性的影响规律,提出采用振动压实成型、增加沥青粘度与改善颗粒表面特性可使颗粒配位数提高、混合料内部应力分布均匀,有利于提高排水性沥青混合料抗变形能力。
分析了振动压路机压实特性与表面振动击实仪动力学特性,基于弹跳模型,推导出了表面振动压实仪振动消耗能方程:E K1A0fM gT;使用振动压实仪,系统研究了线压力、频率、振幅对排水性沥青混合料压实效果的影响规律,结合正交灰关联分析方法,提出了影响排水性沥青混合料性能的各配置因素的主次顺序:夹角>频率>上下车配重,以及最佳振动参数组合:H35J120S4X5。
使用表面振动压实仪,通过逐级振动填充试验,进行了排水性沥青混合料级配优化,得到了典型排水性沥青混合料振动压实状态下粗细集料分界筛孔为4.75mm,优化了不同粗、细集料组成的最佳比例,推导出了能反映粗集料骨架稳定特征的微观强度指标与粗集料的体积指标、不同组分的性质(包括密度、含量和当量半径)关系的粗集料剪切模量比GR(振动压实状态下粗集料混合料的剪切模量与干插捣紧装状态下粗集料的剪切模量之比)。
基于优化得到的排水性沥青混合料级配,系统研究了各因素对混合料路用性能的影响规律,证实了振动和揉搓压实较传统马歇尔锤击压实更有利于排水性沥青混合料嵌挤骨架结构的形成,且试验结果表明,振动压实成型试件的动稳定度为静压成型试件的1.532倍。
通过验证试验及实体工程铺筑,分析了振动压实工艺对排水性沥青混合料压实效果的影响规律,提出有限振动压实遍数不会造成混合料矿料级配的严重衰变,优化了排水性沥青混合料振动压实工艺,即:先用12t双钢轮振动压路机以高频、低幅方式振动3遍,然后采用大于11t的双钢轮振动压路机静压2遍,消除轮迹印,两道工序应衔接紧凑。
As a typical of skeleton-gap structure mixtures, the air void of porous asphalt mixture isusually around20%after compaction. The porous asphalt mixture pavement has excellentdrainage performance with low-noise. It can also significantly improve the safety of driving inthe rain. However, the noise reduction performance mainly depends on internal structure ofthe mixture, which is closely related with the compacting method. Different compactingmethods make discrepancy interior structures, which may affect the performance of mixture.Based on the microstructure perspective of porous asphalt mixture, this article analyzed thevibratory compaction as the main research line. The micromechanics characteristics forporous asphalt mixtures, key raw material selection method, vibration compactioncharacteristics, gradation optimization, road performance and compacting technology werestudied in depth. The achievementswere verified in laboratory experiment and the verificationtest that provide the theoretical guidance for the application of vibration compactiontechnology in the design and application of porous asphalt mixture.
Through study of the composition and characteristics of porous asphalt mixture,combining with the existing research results at home and abroad, the technical standards ofcoarse aggregate and fine aggregate for porous asphalt mixture were suggested. For theeffects high sticky asphalt to porous asphalt mixture performance, based on AHP and fuzzymathematics theory, comprehensive evaluation model of factors that affect performance wasconstructed, the comprehensive evaluation index weight value of high viscosity modifiedasphalt was proposed, the comprehensive evaluation method of high-viscosity modifiedasphalt was established, and the modification schemes which are suitable for real engineeringwas selected optimizedly.
Based on the microstructure characteristics of porous asphalt mixture and the discreteelement method, the non-continuous theoretical model that can reflect the movement ofparticles in porous asphalt mixture was constructed. Combined with uniaxial penetration testin the way of numerical virtual simulations, the influenceof Compacting method and materialparameters on microstructure perspective of porous asphalt mixture were analyzed. By adopting vibrating compacting method, increasing bitumen viscosity and improving surfacecharacteristics, homogenizing the internal stress distribution in the mixture can improve thedeformation resistance of the porous asphalt mixture.
Analyzing the relationship between the compaction characteristics of vibratory roller anddynamic properties of surface vibration compaction instrument, the vibration energyconsumption equation of the surface vibration compactor was deduced:E K1A0fM gT.Using a vibrating compactor, the effect of the law that line pressure, frequency, amplitude onporous asphalt mixture compaction were systematically studied. Combined with orthogonalgray relational analysis, the configuration factors of primary and secondary order whichinfluence the performances of the porous asphalt mixture is: angle> frequency> on and off thecounterweight, as well as the optimal vibration parameters combination: H35J120S4X5.
By using pavement vibration compactor and the experiments of vibration andalternativein classification, the drainage asphalt mixture gradation had been optimizated. Theresearch got the conclusions as follows: the vibratory compaction state boundaries sieveaggregate size for porous asphalt mixture is4.75mm, the composition of different coarse andfine aggregates has optimized, the composed of the best ratio deduced reflect stable coarseaggregate skeleton microscopic characteristics of coarse aggregate strength index and thevolume indicator different nature of the components (including density, content andequivalent radius) relations coarse aggregate shear modulus ratio GR (vibratory compactionstate mixture of coarse aggregate shear modulus tamping plug fitted with dry coarse aggregatestate of the shear modulus) were deduced.
Based on the optimized gradation for porous asphalt mixture, the effects of differentfactors on pavement performance were studied in a systematic way.The results show that thevibrating compaction and rubbing compaction are better than Maxell compaction at formingthe interlocking framework of porous asphalt mixture; and the dynamic stability value ofvibrating compaction specimens are1.532times of pressure shaping one.
Trough verification test and pavement construction, the influence of vibratingcompaction craft on the porous asphalt mixture was studied. The results show that withincertain vibrating compaction times, the porous asphalt mixture gradation won't change much more, and the vibrating compaction craft for porous asphalt mixture is optimized: at first, a12t twin steel wheel vibration roller vibrating rolls the asphalt mixture in a highfrequency-low amplitude way for3times, then a twin steel wheel vibration roller over11tpressure rolls for2times to eliminate the wheel path, and the two crafts should be compactconvergence.
引文
[1]徐斌.排水性沥青路面理论与实践[M].北京:人民交通出版社,2011:11-14
[2]王知乐.排水性沥青路面的研究[J].泰州职业技术学院学报,2006,7(3):27-30
[3]久保和章.排水性、低噪音铺设(现况问题点),土木技术特集
[4]孙立军.沥青路面结果行为理论[M].北京:人民交通出版社,2005:12-19
[5]交通部科学研究院.公路运输文摘[N].2004
[6] The Pennsylvania Transportation Institute. The Pennsylvania State University “ProposedDesign Guidelines for Improving Pavement Surface Drainage”.1998
[7]交通部公路科学研究院等.西部交通建设科技项目-山区公路沥青面层排水技术的研究大纲[S].交通部公路科学研究院,2004
[8] Walter J. Tappeiner.“Open-Graded Asphalt Friction Courses.” NAPAIS115
[9] P.M.W. Elsenaar, J. Reichert, and R. Sauterey.“Pavement Characteristics and SkidResistance”.P1-25,TRANSPORTATION RESEARCH RECORD622
[10] Nelson PM,Abbott PG.Acoustical Performance of pervious macadam surfaces forHigh-speed roads. Transportation Research Record,1265,1990,P.25-30
[11] Nelson PM. Designing Porous road surfaces to reduce traffic noise.TRLAnnualReview1994.Crowthorne, UK: transport Research Laboratory, Crowthorne, UK,1994,P.33-41
[12]尹永胜.低噪音沥青路面的研究[D].西安:长安大学,2005
[13] David White oak.壳牌沥青手册:中文版[K].北京:壳牌大中华集团,1995
[14]中西弘光.排水性路面铺装功能持续性的研究[J].广西交通科技,2002,27(4):7-12
[15]张登良.沥青路面[M].北京:人民交通出版社,1999.
[16]李晓军,张肖宁. CT技术在沥青胶结颗粒材料内部结构分析中的应用[J].公路交通科技,2005,22(2):14-23
[17]陈新轩.轮胎压路机压实热拌沥青混合料的机理和作用[J].长安大学学报(自然科学版),2003,23(5):49-51
[18]李智.基于数字图像处理技术的沥青混合料体积组成特性分析[D].哈尔滨:哈尔滨工业大学,2002
[19]徐亦航.排水性沥青路面技术性能研究[D].西安:长安大学,2007
[20] Heystraeten.G.V. and Meraux, C. TenYears, Experience of Porous Asphalt in Belgium.Transportation Research Record1265,1990,P34-40
[21] Kandhal,P.S., and R.B.Malliek. Open Graded Asphalt Friction Courses: State of thePractice[M]. NCAT, Report No.98-7,1998
[22] Kandhal,P.S., and R.B.Malliek. Design of New-Generation Open-Graded FrictionCourses[R].USA: National Center forAsphalt Techonology Report,1999
[23] Brunson, Gary M. Personal Conspondence. Materials Division,ALDOT. January2005
[24] Colwill.D.M, G.J Bowskill, J.C.Nichols, and M.E.Daines. Porous asphalt Trialsin UnitedKingdom. In Transportation Research record1427,TRB, National research Council,Washington D.C.,1993, P.13-21
[25] Federal Highway Administration. Open-Graded Friction Courses FHWAMix DesignMethod. Federal HighwayAdministration, U.S. Department, Washington D.C.,1990
[26] Richard E. Root P.E. Investigation of the Use of Open-Graded Friction Courses inWisconsin[R].2009
[28] Smith R.W., Rice J.M. and Spellman S.R., Design of Open-Graded Friction Courses[R],FHWAReport No.FHWA-RD-74-2, Washington D.C.,1974
[29] Smith H.A. Performance Characteristics of Open-Graded Friction Courses[J].NCHRP.Synthesis of Highway Practice180, TRB,1992
[30] Prithvi S.Kandhal, and Rajib B. Mallick. Design of New-Generation Open-GradedFriction Course. NCAT Report No.99-3,1999
[31] Florida of Transportation."Florida Method of Test for Measurement of WaterPermeability of Compacted Asphalt Paving Mixtures[M]. FM5-565, March1999.
[32] R.B.Mallick, P.S.Kandhal, L.A.Cooley, Jr.,etc. Design Construction and performance ofNew-Generation Open-Graded Friction Courses[R]. National Center forAsphaltTechnology Report,2000
[33] Method of Test for Determining OptimumAsphalt Content for Open-Graded BituminousPaving Mixtures[M]. Georgia Department of Transportation, GDT114, June1989
[34] David A. Anderson, R. Scott Huebner, Joseeph R. Reed, John C. Warner, and John J.Henry.“Improved Surface Drainage of Pavement”,NCHRPWeb Document16,FinalReport, June1998
[35]日本道路协会.排水性铺装技术指南(案)[S].东京:丸善株式会社,1996
[36]郭勇.高速公路排水性沥青混合料应用研究[D].南京:东南大学,2006
[37]《关于排水路面赴美调查报告书》[R],高速公路调查会(日本)1992,4.3
[38]曹可勇.日本的排水性沥青路面,陕西高速,2003.2
[39]日本道路协会.“Method for Measuring Surface Friction Properties.”,《铺装试验法便览》,东京,1999
[40]李会娟.长大桥梁排水性沥青路面材料与结构性能研究[D].西安:长安大学,2010
[41] New Zealand. Open-Graded-Porous-Asphalt [Z].2007
[42] Beecham, S. and B. Myers, Structural and Design Aspects of Porous and PermeableBlock Pavement.2007,43(1): P74-81
[43]江苏省高速公路建设指挥部.江苏省交通科学研究院.开级配抗滑磨耗层(OGFC)沥青路面的试验研究[R].南京:江苏省高速公路建设指挥部、江苏省交通科学研究院,2004.12
[44]曹东伟,刘清泉,唐国奇.排水沥青路面[M].北京:人民交通出社,2009:14-16
[45]徐希娟. SBS纤维改性沥青排水混合料设计与性能研究[D].西安:长安大学,2010
[46]严军,叶奋,黄彭.排水沥青混合料透水性能的评价研究[J].公路交通科技,2002,19(6):35-36
[47]严军,叶奋,王小生等.排水面层沥青混合料组成设计的研究[J].同济大学学报,2003,31(3):300-302
[48]李立寒,李新军,梅海峙等.排水性沥青混合料组成结构与性能的研究[J].建筑材料学报,2003,6(1):40-42
[49]倪富健,覃勉,刘清泉等. TPS改性剂在排水性沥青混合料中的应用研究[J].公路交通科技,2004:21(10):17-21
[50]徐皓,倪富健,陈荣生等.排水性沥青混合料耐久性[J].交通运输工程学报,2005,5(2):27-30
[51]唐国奇,刘清泉,曹东伟.排水性沥青混合料填料对比研究[J].公路交通科技,2006,23(1):9-11
[52]杨军,郭勇,尹朝恩等.排水性沥青混合料析漏损失控制指标[J].交通运输工程学报,2007,7(5):33-36
[53]马翔,倪富健,陈荣生等.沥青指标对排水性沥青混合料性能的影响[J].东南大学学报(自然科学版),2008.38(2):265-268
[54]宋宪发.排水性沥青路面降温性能及衰变规律研究[D].上海:同济大学,2008
[55]郭黎黎.大空隙排水性沥青路面耐久性研究[D].西安:长安大学,2010
[56]邢明亮,杨旭东,付其林.空隙率对排水性沥青路面路用性能的影响研究[J].路基工程,2009,145(4):38-39
[57]孙文洲.橡胶沥青开级配排水沥青路面试验研究[J].上海公路,2009,(4):6-10
[58]裴建中,张嘉林.排水沥青路面空隙空间信息获取方法[J].长安大学学报(自然科学版),2010,30(1):6-8
[59]夏晖,张肖宁.排水性沥青路面的透风散热性能研究[J].科学技术与工程,2010,10(21):5330-5333
[60]张璠,陈荣生,倪富健.排水性沥青路面混合料的渗透性能试验测试技术[J].东南大学学报(自然科学版,2010,40(6):1488-1291
[61]邢明亮.透水性沥青混合料组成设计与性能研究[D].西安:长安大学,2007
[62]李泽昊,钱振东,罗桑等.大孔隙环氧沥青混合料路用性能研究[J].公路,2011,(12):11-14
[63]陈红缨,徐健,王新南等.温拌型排水沥青路面集成技术研究[J].城市道桥与防洪,2011(8):23-26
[64]王慧,刘黎萍,高晓飞等.温拌OGFC混合料性能研究[J].建筑材料学报,2012,15(3):426-429
[65]陈永兴.基于离散单元法的排水性沥青混合料级配优选方法研究[D].长沙:长沙理工大学,2012
[66]程成,马翔,刘松玉.排水性沥青混合料路用性能改善措施[J].建筑材料学报,2013,16(1):164-167
[67]蒋玮.透水性沥青路面混合料配合比设计方法与路用性能研究[D].西安:长安大学,2008
[68]吕艳萍,李淑明.对开级配排水式沥青磨耗层混合料成型标准的探讨[J].公路,2009,3(3):139-142
[69]矫芳芳.排水沥青混合料性能影响因素研究[D].西安:长安大学,2010
[70]解晓光,马松林,王哲人.沥青混合料马歇尔击实法与振动压实法成型工艺的比较研究,中国公路学报,2001,(1):9-12
[71]解晓光,王龙,王哲人.沥青混合料压实工艺与被压材料相互影响的研究,公路,2006,(1):171-175
[72]苏春华.大粒径沥青碎石混合料组成设计与振动成型方法研究[D].西安:长安大学,2011
[73]华南理工大学道路工程研究所.沥青混合料矿料级配及配合比设计方法的修订[R].广州:华南理工大学,2002
[74]姚林虎.沥青混合料试件垂直振动成型方法研究[D].西安:长安大学,2012
[75]尚云龙.沥青混凝土压实工艺的研究[D].哈尔滨:东北林业大学,2003
[76]朱强.基于ATB—30沥青混合料振动成型方法研究[D].西安:长安大学,2011
[77]范静.天津地区排水性路面混合料配合比设计方法与路用性能研究[D].天津:河北工业大学,2010
[78] Synthesis of Current Practice on the Design, Construction, and Maintenance of PorousFriction Courses.2006
[79] Evaluation of Properties of Porous Friction Course Mixes for Different GyrationLevels.2009
[80]朱经训译.日本排水性沥青路面技术指南[M].日本道路协会.2004
[81]于志新.排水性沥青路面在山区高速公路中的应用研究[D].长沙:长沙理工大学,2010
[82]李晓娟. OGFC沥青混合料路用性能研究[D].西安:长安大学,2008
[83]张铭铭.排水性沥青混合料配合比设计及技术性能研究[D].西安:长安大学,2009
[84]文湘.透水性沥青混合料耐久性研究[D].长沙:长沙理工大学,2012
[85]肖云,郑国梁.基于微观分散性分析的SBS改性沥青质量控制[J].公路交通科技,2005,22(12):17-19
[86]许玉琢.模糊理论在配合比设计方案比选中的应用[J].交通标准化,2012,(6):47-50
[87]曹进.模糊综合评判法在沥青混合料性能评价中的应用[J].市政技术,2011,29(1):140-142
[88]张轩.高速公路软基处理后评价方法研究[D].南京:东南大学,2010
[89]彭祖赠,孙韫玉.模糊(Fuzzy)数学及其应用[M].武汉:武汉大学出版社,2007.9
[90]许新权,郑南翔,吴传海等.基于模糊理论的沥青路面结构优选[J].中外公路,2009,29(4):66-69
[91]许新权.基于APT的重载交通沥青路面结构研究[D].西安:长安大学,2008
[92]赵岩.沥青混合料细集料标准研究[D].天津:河北工业大学,2010
[93]林绣贤.关于沥青混凝土路面设计中抗剪指标的建议[J].公路,2004,12:66-69
[94] Sousa J.B., Weiswnan S.L., Deacon J.A., et al. Permanent Pavement Deformationresponse of asphalt aggregate mixes[R].Washington D C: SHRP, National ResearchCouncil.1994
[95] Sousa J.B., Monismith C L. Summary report on permanent deformation in asphaltconcrete[R].SHRP-A/IR-91-104, Washington D C,1991
[96]黄晓明,张裕卿.沥青混合料高温性能试验方法[J].公路交通科技,2008,25(5):1-7
[97]李曦.碎石封层性能影响因素试验研究[D].长沙:长沙理工大学,2009
[98] Subbaraju B H. Model study of stress in asphalt pavement[C].ASTM5thConference.AnnArbor,U.S.:Association ofAsphalt Paving Technologists,1965.
[99]裴建中.沥青路面细观结构特性与衰变行为[M].北京:科学出版社,2010:39-46
[100]谢泽华.沥青混合料高温稳定性三轴试验研究[D].长沙:长沙理工大学,2006
[101]毕玉峰,孙立军.沥青混合料抗剪试验方法研究[J].同济大学学报:自然科学版,2005,33(8):1036-1040
[102]刘国杰,黄晓明.特大桥梁沥青铺装层材料性能试验研究[J].公路交通科技,2007,24(4):67-70
[103]王龙,解晓光,栾海.成型方法对级配碎石混合料抗剪性能的影响[J].公路交通科技,2008,25(5):40-44
[104]毕玉峰.沥青混合料抗剪试验方法及抗剪参数研究[D].上海:同济大学,2004
[105] Cundall P.A.Acomputer model for simulating progressive large scale movements inbloeky system[A]. In: Muller Led. Proeeedings of symposium of the InternationalSociety of Rock Meehanics[C]. Rotterdam: A.A. Balkema,1971:8-12
[106] Cundall P.A. BALL-Aprogram to model granular media using the distinct elementmethod [Z]. Technical Note,Advanced Technology Group, Dames&Moore, London,1978
[107]常明丰.多孔沥青路面微观力学特性与空隙衰变行为研究[D].西安:长安大学,2009
[108]王等明.密集颗粒系统的离散单元模型及其宏观力学行为特征的理论研究[D].甘肃:兰州大学,2009
[109]李美江.道路材料振动压实特性研究[D].西安:长安大学,2002
[110]李冰.振动压路机与振动压实技术[M].北京:人民交通出版社,2001
[111]王燕春.水泥稳定碎石基层路用性能研究[D].太原:太原理工大学,2010
[112]刘华章.振动器振动原理及缺陷改进[J].建筑砌块与砌块建筑,2005,(6):52-54
[113]童飞.从“土壤-机器”系统力学的角度探讨振动压路机的参数设计[D].上海:同济大学,2007
[114]陈胜可.SPSS统计分析(从入门到精通)[M].北京:清华大学出版社,2010
[115]章建龙.水泥稳定碎石振动成型试验研究[D].西安:长安大学,2008
[116]张泓,闻邦椿.振动压路机压实机理的研究[J].建筑机械,2000(3):25-27
[117]冯忠旭,贺钊,王西京.振动压路机数学模型初探[J].西安公路交通大学学报,1996,16(3):102-104
[118]贾谦恒.水泥碎石振动成型设计方法与路面结构优化研究[D].天津:河北工业大学,2009
[119]陈元基等.压实机械与路面机械设计[M].北京:机械工业出版社,1985
[120]吴仁智.振动压路机振动功率计算及试验[J].工程机械,1992,(7):23-28
[121]诸磊.机场道面混凝土正交试验设计及结果方差分析[J].粉煤灰,2005,(2):24-25
[122]王丰胜.影响级配碎石模量的结构因素敏感性分析[J].合肥工业大学学报(自然科学版),2009,(9):1414-1417
[123]张彩利,孟庆营,韩森.基于正交灰关联分析的改性沥青性能影响因素分析[J].公路,2009,(11):191-195
[124]方开泰等.数理统计方法与应用[M].科学出版社,1998
[125] Hand.A.J, J.L. Stiady, T.D. White, A.S.Noureldin, K.Galal. Gradation Effects on HotMixAsphalt Performance[C].TRB, No.1767,2001:152-157
[126]陈忠达,袁万杰,高春海.多级嵌挤密实级配设计方法研究[J].中国公路学报,2006,19(1):32
[127]盛晓军.沥青混合料骨架研究[D].西安:长安大学,2006
[128] JTG E42-2005公路工程集料试验规程[S].北京:人民交通出版社,2005.
[129] Cominskey.R.J, G.A.Huber, T.W.kenedy, and M.Anderson. The Superpave Mix DesignManual for New Construction and Overlays,Report SHRP-A-407[R], NationalResearch Council, Washington D. C,1994.
[130]袁迎捷.基于Superpave的沥青胶浆流变特性与级配优化的研究[D].西安:长安大学,2004
[131]曹卫东,吕伟民,李晓军.集料级配评估的贝雷法[J].中外公路,2005,25(1):85-87
[132]郝培文,徐金枝,周怀治.应用贝雷法进行级配组成设计的关键技术[J].长安大学学报:自然科学版,2004,24(6):126
[133]吕文江,陈爱文,郝培文等.贝雷法参数比对沥青混合料性能的影响[J].长安大学学报,2005,25(4):5-8
[134]张晨晨.细集料干涉对沥青混合料性能的影响[D].重庆交通大学硕士论文.2012
[135] William R V, William J P, Samuel H C, Aggregate Blending forAsphalt Mix DesignBailey Method [J]. Transportation Research Record,2001(17):146-153
[136] William R V. Bailey Method for Gradation Selection in Hot MixAsphaltDesign[R].Washington, DC: Transportation Research Boardm,2002.
[137]林绣贤.论Superpave组成配比的特色[J].华东公路,2002,(1):3-7
[138]林绣贤.沥青混凝土合理集料组成的计算公式[J].华东公路,2003(1):82-84
[139]刘慧.嵌挤骨架型沥青混合料的设计研究[D].大连:大连理工大学博士论文,2010
[140]张肖宁,王绍怀,吴旷怀.沥青混合料组成设计的CAVF法[J].公路,2001,(12):17-21
[141]张肖宁,郭祖辛,吴旷怀.按体积法设计沥青混合料[J].哈尔滨建筑大学学报,1995,28(2):28-36
[142]沙庆林.多碎石沥青混凝土SAC系列的设计与施工[M].北京:人民交通出版社,2005
[143]王富玉. SAC13沥青混合料的设计与施工[D].长春:吉林大学,2007
[144]沙庆林. SAC和其他粗集料断级配的矿料级配设计方法[J].公路,2005,(1):143-150
[145]王林.嵌挤密级配沥青混合料抗滑磨耗层的设计方法[J].华东公路,2001,(2):59-63
[146]周卫峰.基于GTM的沥青混合料配比设计方法研究[D].西安:长安大学,2005
[147]张业茂,陈拴发,胡光伟.逐级填充式沥青混合料粗集料骨架级配设计[J].武汉理工大学学报,2011,33(11):44-48.
[148]刘中林.大碎石沥青混合料LSAM骨架密实型综合设计法[J].公路,2003,(3):93-96
[149]郝培文,张登良,胡西宁.沥青混合料低温抗裂性能评价指标[J].西安公路交通大学学报,2007,20(3):1-5
[150]李红梅.基于路用性能的沥青混合料最佳油石比确定方法研究[D].西安:长安大学,2009
[151]何兴华,王慧通.基于冻融劈裂试验的沥青混合料水稳定性分析[J].现代交通技术,2006,(4):5-8
[152]马沉重.天然岩沥青改性沥青混合料的性能研究[J].筑路机械与施工机械化,2007,(3):22-24
[153]李立寒,曹林涛,罗芳艳等.沥青混合料劈裂抗拉强度影响因素的研究[J].建筑材料学报,2004,7(1):42-45
[2]王知乐.排水性沥青路面的研究[J].泰州职业技术学院学报,2006,7(3):27-30
[3]久保和章.排水性、低噪音铺设(现况问题点),土木技术特集
[4]孙立军.沥青路面结果行为理论[M].北京:人民交通出版社,2005:12-19
[5]交通部科学研究院.公路运输文摘[N].2004
[6] The Pennsylvania Transportation Institute. The Pennsylvania State University “ProposedDesign Guidelines for Improving Pavement Surface Drainage”.1998
[7]交通部公路科学研究院等.西部交通建设科技项目-山区公路沥青面层排水技术的研究大纲[S].交通部公路科学研究院,2004
[8] Walter J. Tappeiner.“Open-Graded Asphalt Friction Courses.” NAPAIS115
[9] P.M.W. Elsenaar, J. Reichert, and R. Sauterey.“Pavement Characteristics and SkidResistance”.P1-25,TRANSPORTATION RESEARCH RECORD622
[10] Nelson PM,Abbott PG.Acoustical Performance of pervious macadam surfaces forHigh-speed roads. Transportation Research Record,1265,1990,P.25-30
[11] Nelson PM. Designing Porous road surfaces to reduce traffic noise.TRLAnnualReview1994.Crowthorne, UK: transport Research Laboratory, Crowthorne, UK,1994,P.33-41
[12]尹永胜.低噪音沥青路面的研究[D].西安:长安大学,2005
[13] David White oak.壳牌沥青手册:中文版[K].北京:壳牌大中华集团,1995
[14]中西弘光.排水性路面铺装功能持续性的研究[J].广西交通科技,2002,27(4):7-12
[15]张登良.沥青路面[M].北京:人民交通出版社,1999.
[16]李晓军,张肖宁. CT技术在沥青胶结颗粒材料内部结构分析中的应用[J].公路交通科技,2005,22(2):14-23
[17]陈新轩.轮胎压路机压实热拌沥青混合料的机理和作用[J].长安大学学报(自然科学版),2003,23(5):49-51
[18]李智.基于数字图像处理技术的沥青混合料体积组成特性分析[D].哈尔滨:哈尔滨工业大学,2002
[19]徐亦航.排水性沥青路面技术性能研究[D].西安:长安大学,2007
[20] Heystraeten.G.V. and Meraux, C. TenYears, Experience of Porous Asphalt in Belgium.Transportation Research Record1265,1990,P34-40
[21] Kandhal,P.S., and R.B.Malliek. Open Graded Asphalt Friction Courses: State of thePractice[M]. NCAT, Report No.98-7,1998
[22] Kandhal,P.S., and R.B.Malliek. Design of New-Generation Open-Graded FrictionCourses[R].USA: National Center forAsphalt Techonology Report,1999
[23] Brunson, Gary M. Personal Conspondence. Materials Division,ALDOT. January2005
[24] Colwill.D.M, G.J Bowskill, J.C.Nichols, and M.E.Daines. Porous asphalt Trialsin UnitedKingdom. In Transportation Research record1427,TRB, National research Council,Washington D.C.,1993, P.13-21
[25] Federal Highway Administration. Open-Graded Friction Courses FHWAMix DesignMethod. Federal HighwayAdministration, U.S. Department, Washington D.C.,1990
[26] Richard E. Root P.E. Investigation of the Use of Open-Graded Friction Courses inWisconsin[R].2009
[28] Smith R.W., Rice J.M. and Spellman S.R., Design of Open-Graded Friction Courses[R],FHWAReport No.FHWA-RD-74-2, Washington D.C.,1974
[29] Smith H.A. Performance Characteristics of Open-Graded Friction Courses[J].NCHRP.Synthesis of Highway Practice180, TRB,1992
[30] Prithvi S.Kandhal, and Rajib B. Mallick. Design of New-Generation Open-GradedFriction Course. NCAT Report No.99-3,1999
[31] Florida of Transportation."Florida Method of Test for Measurement of WaterPermeability of Compacted Asphalt Paving Mixtures[M]. FM5-565, March1999.
[32] R.B.Mallick, P.S.Kandhal, L.A.Cooley, Jr.,etc. Design Construction and performance ofNew-Generation Open-Graded Friction Courses[R]. National Center forAsphaltTechnology Report,2000
[33] Method of Test for Determining OptimumAsphalt Content for Open-Graded BituminousPaving Mixtures[M]. Georgia Department of Transportation, GDT114, June1989
[34] David A. Anderson, R. Scott Huebner, Joseeph R. Reed, John C. Warner, and John J.Henry.“Improved Surface Drainage of Pavement”,NCHRPWeb Document16,FinalReport, June1998
[35]日本道路协会.排水性铺装技术指南(案)[S].东京:丸善株式会社,1996
[36]郭勇.高速公路排水性沥青混合料应用研究[D].南京:东南大学,2006
[37]《关于排水路面赴美调查报告书》[R],高速公路调查会(日本)1992,4.3
[38]曹可勇.日本的排水性沥青路面,陕西高速,2003.2
[39]日本道路协会.“Method for Measuring Surface Friction Properties.”,《铺装试验法便览》,东京,1999
[40]李会娟.长大桥梁排水性沥青路面材料与结构性能研究[D].西安:长安大学,2010
[41] New Zealand. Open-Graded-Porous-Asphalt [Z].2007
[42] Beecham, S. and B. Myers, Structural and Design Aspects of Porous and PermeableBlock Pavement.2007,43(1): P74-81
[43]江苏省高速公路建设指挥部.江苏省交通科学研究院.开级配抗滑磨耗层(OGFC)沥青路面的试验研究[R].南京:江苏省高速公路建设指挥部、江苏省交通科学研究院,2004.12
[44]曹东伟,刘清泉,唐国奇.排水沥青路面[M].北京:人民交通出社,2009:14-16
[45]徐希娟. SBS纤维改性沥青排水混合料设计与性能研究[D].西安:长安大学,2010
[46]严军,叶奋,黄彭.排水沥青混合料透水性能的评价研究[J].公路交通科技,2002,19(6):35-36
[47]严军,叶奋,王小生等.排水面层沥青混合料组成设计的研究[J].同济大学学报,2003,31(3):300-302
[48]李立寒,李新军,梅海峙等.排水性沥青混合料组成结构与性能的研究[J].建筑材料学报,2003,6(1):40-42
[49]倪富健,覃勉,刘清泉等. TPS改性剂在排水性沥青混合料中的应用研究[J].公路交通科技,2004:21(10):17-21
[50]徐皓,倪富健,陈荣生等.排水性沥青混合料耐久性[J].交通运输工程学报,2005,5(2):27-30
[51]唐国奇,刘清泉,曹东伟.排水性沥青混合料填料对比研究[J].公路交通科技,2006,23(1):9-11
[52]杨军,郭勇,尹朝恩等.排水性沥青混合料析漏损失控制指标[J].交通运输工程学报,2007,7(5):33-36
[53]马翔,倪富健,陈荣生等.沥青指标对排水性沥青混合料性能的影响[J].东南大学学报(自然科学版),2008.38(2):265-268
[54]宋宪发.排水性沥青路面降温性能及衰变规律研究[D].上海:同济大学,2008
[55]郭黎黎.大空隙排水性沥青路面耐久性研究[D].西安:长安大学,2010
[56]邢明亮,杨旭东,付其林.空隙率对排水性沥青路面路用性能的影响研究[J].路基工程,2009,145(4):38-39
[57]孙文洲.橡胶沥青开级配排水沥青路面试验研究[J].上海公路,2009,(4):6-10
[58]裴建中,张嘉林.排水沥青路面空隙空间信息获取方法[J].长安大学学报(自然科学版),2010,30(1):6-8
[59]夏晖,张肖宁.排水性沥青路面的透风散热性能研究[J].科学技术与工程,2010,10(21):5330-5333
[60]张璠,陈荣生,倪富健.排水性沥青路面混合料的渗透性能试验测试技术[J].东南大学学报(自然科学版,2010,40(6):1488-1291
[61]邢明亮.透水性沥青混合料组成设计与性能研究[D].西安:长安大学,2007
[62]李泽昊,钱振东,罗桑等.大孔隙环氧沥青混合料路用性能研究[J].公路,2011,(12):11-14
[63]陈红缨,徐健,王新南等.温拌型排水沥青路面集成技术研究[J].城市道桥与防洪,2011(8):23-26
[64]王慧,刘黎萍,高晓飞等.温拌OGFC混合料性能研究[J].建筑材料学报,2012,15(3):426-429
[65]陈永兴.基于离散单元法的排水性沥青混合料级配优选方法研究[D].长沙:长沙理工大学,2012
[66]程成,马翔,刘松玉.排水性沥青混合料路用性能改善措施[J].建筑材料学报,2013,16(1):164-167
[67]蒋玮.透水性沥青路面混合料配合比设计方法与路用性能研究[D].西安:长安大学,2008
[68]吕艳萍,李淑明.对开级配排水式沥青磨耗层混合料成型标准的探讨[J].公路,2009,3(3):139-142
[69]矫芳芳.排水沥青混合料性能影响因素研究[D].西安:长安大学,2010
[70]解晓光,马松林,王哲人.沥青混合料马歇尔击实法与振动压实法成型工艺的比较研究,中国公路学报,2001,(1):9-12
[71]解晓光,王龙,王哲人.沥青混合料压实工艺与被压材料相互影响的研究,公路,2006,(1):171-175
[72]苏春华.大粒径沥青碎石混合料组成设计与振动成型方法研究[D].西安:长安大学,2011
[73]华南理工大学道路工程研究所.沥青混合料矿料级配及配合比设计方法的修订[R].广州:华南理工大学,2002
[74]姚林虎.沥青混合料试件垂直振动成型方法研究[D].西安:长安大学,2012
[75]尚云龙.沥青混凝土压实工艺的研究[D].哈尔滨:东北林业大学,2003
[76]朱强.基于ATB—30沥青混合料振动成型方法研究[D].西安:长安大学,2011
[77]范静.天津地区排水性路面混合料配合比设计方法与路用性能研究[D].天津:河北工业大学,2010
[78] Synthesis of Current Practice on the Design, Construction, and Maintenance of PorousFriction Courses.2006
[79] Evaluation of Properties of Porous Friction Course Mixes for Different GyrationLevels.2009
[80]朱经训译.日本排水性沥青路面技术指南[M].日本道路协会.2004
[81]于志新.排水性沥青路面在山区高速公路中的应用研究[D].长沙:长沙理工大学,2010
[82]李晓娟. OGFC沥青混合料路用性能研究[D].西安:长安大学,2008
[83]张铭铭.排水性沥青混合料配合比设计及技术性能研究[D].西安:长安大学,2009
[84]文湘.透水性沥青混合料耐久性研究[D].长沙:长沙理工大学,2012
[85]肖云,郑国梁.基于微观分散性分析的SBS改性沥青质量控制[J].公路交通科技,2005,22(12):17-19
[86]许玉琢.模糊理论在配合比设计方案比选中的应用[J].交通标准化,2012,(6):47-50
[87]曹进.模糊综合评判法在沥青混合料性能评价中的应用[J].市政技术,2011,29(1):140-142
[88]张轩.高速公路软基处理后评价方法研究[D].南京:东南大学,2010
[89]彭祖赠,孙韫玉.模糊(Fuzzy)数学及其应用[M].武汉:武汉大学出版社,2007.9
[90]许新权,郑南翔,吴传海等.基于模糊理论的沥青路面结构优选[J].中外公路,2009,29(4):66-69
[91]许新权.基于APT的重载交通沥青路面结构研究[D].西安:长安大学,2008
[92]赵岩.沥青混合料细集料标准研究[D].天津:河北工业大学,2010
[93]林绣贤.关于沥青混凝土路面设计中抗剪指标的建议[J].公路,2004,12:66-69
[94] Sousa J.B., Weiswnan S.L., Deacon J.A., et al. Permanent Pavement Deformationresponse of asphalt aggregate mixes[R].Washington D C: SHRP, National ResearchCouncil.1994
[95] Sousa J.B., Monismith C L. Summary report on permanent deformation in asphaltconcrete[R].SHRP-A/IR-91-104, Washington D C,1991
[96]黄晓明,张裕卿.沥青混合料高温性能试验方法[J].公路交通科技,2008,25(5):1-7
[97]李曦.碎石封层性能影响因素试验研究[D].长沙:长沙理工大学,2009
[98] Subbaraju B H. Model study of stress in asphalt pavement[C].ASTM5thConference.AnnArbor,U.S.:Association ofAsphalt Paving Technologists,1965.
[99]裴建中.沥青路面细观结构特性与衰变行为[M].北京:科学出版社,2010:39-46
[100]谢泽华.沥青混合料高温稳定性三轴试验研究[D].长沙:长沙理工大学,2006
[101]毕玉峰,孙立军.沥青混合料抗剪试验方法研究[J].同济大学学报:自然科学版,2005,33(8):1036-1040
[102]刘国杰,黄晓明.特大桥梁沥青铺装层材料性能试验研究[J].公路交通科技,2007,24(4):67-70
[103]王龙,解晓光,栾海.成型方法对级配碎石混合料抗剪性能的影响[J].公路交通科技,2008,25(5):40-44
[104]毕玉峰.沥青混合料抗剪试验方法及抗剪参数研究[D].上海:同济大学,2004
[105] Cundall P.A.Acomputer model for simulating progressive large scale movements inbloeky system[A]. In: Muller Led. Proeeedings of symposium of the InternationalSociety of Rock Meehanics[C]. Rotterdam: A.A. Balkema,1971:8-12
[106] Cundall P.A. BALL-Aprogram to model granular media using the distinct elementmethod [Z]. Technical Note,Advanced Technology Group, Dames&Moore, London,1978
[107]常明丰.多孔沥青路面微观力学特性与空隙衰变行为研究[D].西安:长安大学,2009
[108]王等明.密集颗粒系统的离散单元模型及其宏观力学行为特征的理论研究[D].甘肃:兰州大学,2009
[109]李美江.道路材料振动压实特性研究[D].西安:长安大学,2002
[110]李冰.振动压路机与振动压实技术[M].北京:人民交通出版社,2001
[111]王燕春.水泥稳定碎石基层路用性能研究[D].太原:太原理工大学,2010
[112]刘华章.振动器振动原理及缺陷改进[J].建筑砌块与砌块建筑,2005,(6):52-54
[113]童飞.从“土壤-机器”系统力学的角度探讨振动压路机的参数设计[D].上海:同济大学,2007
[114]陈胜可.SPSS统计分析(从入门到精通)[M].北京:清华大学出版社,2010
[115]章建龙.水泥稳定碎石振动成型试验研究[D].西安:长安大学,2008
[116]张泓,闻邦椿.振动压路机压实机理的研究[J].建筑机械,2000(3):25-27
[117]冯忠旭,贺钊,王西京.振动压路机数学模型初探[J].西安公路交通大学学报,1996,16(3):102-104
[118]贾谦恒.水泥碎石振动成型设计方法与路面结构优化研究[D].天津:河北工业大学,2009
[119]陈元基等.压实机械与路面机械设计[M].北京:机械工业出版社,1985
[120]吴仁智.振动压路机振动功率计算及试验[J].工程机械,1992,(7):23-28
[121]诸磊.机场道面混凝土正交试验设计及结果方差分析[J].粉煤灰,2005,(2):24-25
[122]王丰胜.影响级配碎石模量的结构因素敏感性分析[J].合肥工业大学学报(自然科学版),2009,(9):1414-1417
[123]张彩利,孟庆营,韩森.基于正交灰关联分析的改性沥青性能影响因素分析[J].公路,2009,(11):191-195
[124]方开泰等.数理统计方法与应用[M].科学出版社,1998
[125] Hand.A.J, J.L. Stiady, T.D. White, A.S.Noureldin, K.Galal. Gradation Effects on HotMixAsphalt Performance[C].TRB, No.1767,2001:152-157
[126]陈忠达,袁万杰,高春海.多级嵌挤密实级配设计方法研究[J].中国公路学报,2006,19(1):32
[127]盛晓军.沥青混合料骨架研究[D].西安:长安大学,2006
[128] JTG E42-2005公路工程集料试验规程[S].北京:人民交通出版社,2005.
[129] Cominskey.R.J, G.A.Huber, T.W.kenedy, and M.Anderson. The Superpave Mix DesignManual for New Construction and Overlays,Report SHRP-A-407[R], NationalResearch Council, Washington D. C,1994.
[130]袁迎捷.基于Superpave的沥青胶浆流变特性与级配优化的研究[D].西安:长安大学,2004
[131]曹卫东,吕伟民,李晓军.集料级配评估的贝雷法[J].中外公路,2005,25(1):85-87
[132]郝培文,徐金枝,周怀治.应用贝雷法进行级配组成设计的关键技术[J].长安大学学报:自然科学版,2004,24(6):126
[133]吕文江,陈爱文,郝培文等.贝雷法参数比对沥青混合料性能的影响[J].长安大学学报,2005,25(4):5-8
[134]张晨晨.细集料干涉对沥青混合料性能的影响[D].重庆交通大学硕士论文.2012
[135] William R V, William J P, Samuel H C, Aggregate Blending forAsphalt Mix DesignBailey Method [J]. Transportation Research Record,2001(17):146-153
[136] William R V. Bailey Method for Gradation Selection in Hot MixAsphaltDesign[R].Washington, DC: Transportation Research Boardm,2002.
[137]林绣贤.论Superpave组成配比的特色[J].华东公路,2002,(1):3-7
[138]林绣贤.沥青混凝土合理集料组成的计算公式[J].华东公路,2003(1):82-84
[139]刘慧.嵌挤骨架型沥青混合料的设计研究[D].大连:大连理工大学博士论文,2010
[140]张肖宁,王绍怀,吴旷怀.沥青混合料组成设计的CAVF法[J].公路,2001,(12):17-21
[141]张肖宁,郭祖辛,吴旷怀.按体积法设计沥青混合料[J].哈尔滨建筑大学学报,1995,28(2):28-36
[142]沙庆林.多碎石沥青混凝土SAC系列的设计与施工[M].北京:人民交通出版社,2005
[143]王富玉. SAC13沥青混合料的设计与施工[D].长春:吉林大学,2007
[144]沙庆林. SAC和其他粗集料断级配的矿料级配设计方法[J].公路,2005,(1):143-150
[145]王林.嵌挤密级配沥青混合料抗滑磨耗层的设计方法[J].华东公路,2001,(2):59-63
[146]周卫峰.基于GTM的沥青混合料配比设计方法研究[D].西安:长安大学,2005
[147]张业茂,陈拴发,胡光伟.逐级填充式沥青混合料粗集料骨架级配设计[J].武汉理工大学学报,2011,33(11):44-48.
[148]刘中林.大碎石沥青混合料LSAM骨架密实型综合设计法[J].公路,2003,(3):93-96
[149]郝培文,张登良,胡西宁.沥青混合料低温抗裂性能评价指标[J].西安公路交通大学学报,2007,20(3):1-5
[150]李红梅.基于路用性能的沥青混合料最佳油石比确定方法研究[D].西安:长安大学,2009
[151]何兴华,王慧通.基于冻融劈裂试验的沥青混合料水稳定性分析[J].现代交通技术,2006,(4):5-8
[152]马沉重.天然岩沥青改性沥青混合料的性能研究[J].筑路机械与施工机械化,2007,(3):22-24
[153]李立寒,曹林涛,罗芳艳等.沥青混合料劈裂抗拉强度影响因素的研究[J].建筑材料学报,2004,7(1):42-45
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |