摘要
土压平衡盾构穿越复杂地层时,必须采取土体改良措施,目前泡沫改良土体已被广泛应用于盾构施工中。我国尚未开发出可替代国外产品的优良泡沫添加剂,伴随盾构国产化进程加快,泡沫添加剂研发与泡沫土性能研究非常迫切。本文围绕土压平衡盾构用新型泡沫剂的开发研制和地铁建设中土压平衡盾构穿越复杂地层时的泡沫剂土体改良的相关特性参数进行研究。在分析进口泡沫剂成分的基础上,运用正交试验方法,开展了新型土压平衡盾构用泡沫剂的研制工作,对自制泡沫剂、进口泡沫剂和国产泡沫剂的基本性能进行对比试验,并对泡沫剂的特性评价标准提出了量化指标;以自制泡沫剂、进口泡沫剂和国产泡沫剂为土体改良材料,开展了泡沫改良砂土和粘土的渗透性、塑流性、剪切强度、压缩性、外摩擦角的对比实验研究,对改良土的各项特性指标进行了综合分析,提出了改良土“塑性流动性”特性评价试验室标准和量化指标;在对红粘土和砂土微观结构研究的基础上,进行了泡沫改良砂土和粘土的微观机理研究。
Soil improvement measures must be taken when EPB shield tunnel in the complex strata, at present, the method of foam modifying soil has been widely used in shield construction. In our country, foaming agent has not yet been developed to replace the exellent abroad products, with the accelaration of localization of shield machine, the research on foaming agent and the properties of the foamed soil are very urgent. On the R& D of a new type of foaming agent used in EPB shield and foam improving soil for tunneling in the complex strata in the subway construction. Based on the composition analyzing of imported foaming agent, the orthogonal test method is adopted to carry out the development of a new type of foaming agent used in EPB shield machine. The basic performances are compared with the homemade foaming agent, imported foaming agent and dometic foaming agent, and the quantitative evaluation criteria on the characteristics of foaming agent is put forward; taking the home-made foam, domestic foam and imports foam as soil improving materials, the experimental research on the permeability, plastic flow, shear strength, compression and external friction angle of foam improved sand and clay is carried out. Based on the comprehensive analysis of the characteristic indexes of the modified soils, the quantitative evaluation criteria on the "liquid plastic" properties of the foam modified soil is put forward; based on the research of microstructure of sand and clay, the research on micro-mechanism of foam improving sand and clay is carried out.
引文
1.国家发改委综合运输研究所,城市交通轨道《2020年科学和技术发展规划》(中国城市轨道交通网)
2.钱七虎,李朝甫,傅德明.隧道掘进机在中国地下工程应用现状及前景展望,地下空间,2002,21(1):1-11
3.周干峙,钱七虎.中国工程院课题组《中国城市地下空间开发利用研究》中国建筑工业出版社,2001.11
4.孙均.市区基坑开挖施工的环境土工问题,地下空间,1999,19(4):257-265
5.刘宝琛.急待深入研究的地铁建设中的岩土力学课题,铁道建筑技术,2000(3):1~3
6.刘建航,侯学渊.盾构法隧道,北京:中国铁道出版社,1991.11
7.王梦恕.我国地下铁道施工方法综述与展望,地下空间,1998,18(2):98~103
8.张庆贺,柏炯.上海软土盾构法隧道的理论与实践,同济大学学报,1998,26(4):387~392
9.刘维宁,张弥.城市地下工程环境影响的控制理论及其应用[J],土木工程学报,1997,30(5):66-75
10.王殿春,可洪有.大—沥区间隧道盾构施工地面沉降原因分析,西部探矿工程,2004(95):94-95
11.仵彦卿.地下水与地质灾害,地下空间,1999,19(4):303~310
12. Biot, M A. General theory of three dimensional consolidation. J. Appl. Phys.,1941(12):155-164
13. Brace W F, Walsh J B. Permeability of granite under high pressure. J. Geophys. Res.,1978,73(6):2225-2236
14. Finno R J, Evaluation of soil response to EPB shielding tunneling, J.of Geot. Eng., ASCE,1985 111 (2): 157-173
15. Rowe P K, Lee K M. An evaluation of simplified techniques for estimating three-dimensional undrained ground movements due to tunneling in soft soils. Canadian Geotechnical Journal,1992(29):39-52
16. Sagaseta, C. Analysis of undrained soil deformation due to ground loss. Geotechnique.1987,37(3):301-320
17.阳军生,刘宝琛.城市隧道施工引起的地表移动及变形.北京:中国铁道出版社,2002
18.陶龙光,巴肇伦.城市地下工程,北京:科学出版社,1996.11
19.刘波.地铁隧道施工引起地层变形反分析预测系统研究,中国矿业大学学报,2004,33(3):277-282
20.刘波,陶龙光.地铁隧道施工引起临近基础沉降的FLAC元数值模拟,煤炭科学技术,2002,30(1):9-11
21.刘波,陶龙光.地铁隧道短台阶矿山法施工地层沉降三维数值分析,隧道建设,2005,25(4):1-4
22.刘波,韩彦辉.FLAC原理、实例与应用指南.北京:人民交通出版社,2005.9
23.陶龙光,刘波.盾构过地铁站施工对地表沉降影响数值模拟,中国矿业大学学报,2003,32(3):236-240
24. Maidl. Active confinement pressure control with foam, a comparison between slurry and earth pressure balanced shields, [J/OL]. Germany,1995. http://www.eesye.gr/uploads/71/71/U._Maidl.pdf
25. S.Queband et al. Use of Chemical foam for Improvements in Drilling by Earth-Pressure Balance Shields in Granular Soils, Tunneling and Underground Space Technology,1998,13(2):173-180
26.张向京,杨果林.膨胀土的化学改良试验研究山西建筑2004,30(19):80
27. Sotiris P. Properties of foam/sand mixture for tunneling application, Master Thesis, Oxford University.2001
28.周静,谭永生.稳定泡沫流体的机理研究明.钻采工艺,1999(6):75-78
29.曾华波.砂层地段土压平衡盾构施工技术探讨,西部探矿工程,2006(126):175-177
30.江琳.新型耐盐抗钙耐高温泡沫剂的研究[D].南充:西南石油学院
31.王寿红,赵杰伟.钻探用泡沫剂发泡机理与性能分析.军工勘察,1994(2):34~39
32.袁春.隔离膜水基钻井液体系研究(硕士论文).西南石油学院
33.尹忠,陈馥.泡沫评价及泡沫剂复配的实验研究,西南石油学院学报,2004,26(4):36-37
34.王云峰,张春光,侯万国.表面活性剂及其在油气田中的应用(第一版).石油工业出版社,1995.6:140~145
35.颜五和,谢尚贤,韩培慧.泡沫与泡沫驱油.油田化学,1990(4):380~383
36.申瑞臣,刘世科.浅析泡沫钻井的优点.石油钻采工艺,1991(3):23~28
37.赵晓东.泡沫稳定性综述.钻井液与完井液,1992(1):7~14,23
38.谢国耀,樊世忠.泡沫稳定性.油田化学,1988.5(1):55~63
39.宋育贤,周云霞,黄正鹏.泡沫流体在油田上的应用.国外油田工程,1997(1):6~8
40.魏康林,朱伟.盾构隧道施工技术发展新方向(J).河海大学学报(自然科学版),2001(29):34~37
41. Snow D.T. Rock fracture spacing:Opening and Porosity. J.S oil Mech. Found. ASCE,1968 4(S M1):73-91
42. E.E. Alonso, J. Vaunat, A. Gens. Modelling the mechanical behaviour of expansive clays. Engineering Geology.1999(54):173-183
43.罗逸,李国华,张慧等.膨胀土化学改性对土体力学行为的影响.水文地质工程地质.1995,6:19-20
44.魏康林.土压平衡盾构施工中泡沫和膨润土改良土体的微观机理分析.现代隧道技术.2007,44(1):73-77
45.罗希权,罗毅,王澄华等.表面活性剂产品手册.中国轻工业出版社,1997,3
46.肖进新,赵振国.表面活性剂应用原理.北京:化学工业出版社,2003.5
47.王云峰,张春光,侯万国.表面活性剂及其在油气田中的应用(第一版).石油工业出版社,1995.6:140~145
48.赵国玺.表面活性剂物理化学(第一版).北京大学出版社,1984.1
49.陈宗淇.胶体化学(第一版).高等教育出版社,1984.10.
50.梁梦兰.表面活性剂和洗涤剂——制备 性质应用(第一版).科学技术文献出版社,1992.5:6~8
51.陈荣沂.表面活性剂化学与应用(第一版).纺织工业出版社,1990.6:2~3
52.M.J希克.阴离子表面活性剂(第一版)[M].张余善,王多闻等译.轻工业出版社,1983.6
53.徐寿昌.有机化学(第一版).高等教育出版社,1992.2
54.陈洁,宋启泽.有机波谱分析(第一版).北京理工大学出版社,1997.4
55.罗澄源.物理化学实验.第三版高等教育出版社,1994.3
56.周凤山.钻井液用泡沫剂性能评价方法的研究.钻井液与完井液,1990.7(3):23-26
57.秦建设,朱伟,林进也.盾构施工中气泡应用效果评价研究.地下空间.2004,24(3):350-358
58. Sagaseta C. Analysis of undrained soil deformation due to ground loss. Geotechnique,1987
59.杨乃刚.泡沫在土压平衡式盾构施工中的应用,建筑机械2005(8):103-105
60.刘程,米裕民.表面活性剂性质理论与应用,北京工业大学出版社,2003.6第一版
61.刘程.表面活性剂应用大全.北京:北京工业大学出版社,1992.12
62.亚尔巴.泡沫稳定性及消泡方法的试验研究[D],吉林大学,2007.6
63.许惠德,马金荣,姜振泉.土质学及土力学.中国矿业大学出版社,1995.3
64.高国瑞.膨胀土的微结构和膨胀势.岩土工程学报,2002,6(2):28-31
65.张乐天,王宗良.中国粘土矿物的电子显微镜研究.北京:地质出版社,1978
66.朱伟,张明晶,张志允.土压平衡盾构气泡发泡剂的试验研究,中国土木工程学会第九届土力学与岩土工程学术会议论文集,2003.10:1321-1326
67.郭涛.盾构用发泡剂性能评价方法研究[D].南京:河海大学,2005.6
68. G Anagnostou, K. Kovari. Face stability conditions with earth-pressure-balanced shields, tunneling and underground space technology,1996,11(2):165-173
69.许惠德,马金荣,姜振泉.土质学及土力学.中国矿业大学出版社,1995.3
70.中华人民共和国水利部.土工试验方法标准.北京:中国计划出版社,1999.10
71.南京水利科学研究院土工研究所.土工试验技术手册.北京:人民交通出版社,2003.4
72.唐益群.土压平衡式盾构在砂性土中施工问题的试验研究,岩石力学与工程学报,2005,24(1):52-56
73.易宏伟,张庆贺,朱忠隆.静力触探在盾构施工对土体扰动研究中的应用[J].世界隧道,2000,(2):7-10
74.唐益群,黄雨,叶为民等.地铁列车荷载作用下隧道周围土体的邻界动应力比和动应变分析[J].岩石力学与工程学报,2003,22(9):1566-1570
75.张庆贺,朱忠隆.盾构推进引起土体扰动理论分析及试验研究[J].岩石力学与工程学报,1999,18(6):699-703
76.易宏伟,孙钧.盾构施工对软粘土的扰动机理分析[J].同济大学学报,2000,28(3):277-281
77.潘强.盾构施工中泡沫剂改良复杂岩土的试验研究[M].中国矿业大学(北京),2007.6
78.杨位洗.地基及基础.北京:中国建筑工业出版社,1998,6
79.刘波,潘强,陶龙光等.国家实用新型专利《地下工程岩土改良泡沫发生器》(专利号200620175127.8)
80.吴群慧.新型泡沫材料在土压平衡盾构穿越富水砂性地层中的研制与应用.隧道-地下工程,2006:54-57
81. Raffaele Vinaia, Claudio Oggeria and Daniele Peila. Soil conditioning of sand for EPB applications:A laboratory research, Department of Land, Environment and Geoengineering, Tunnelling and Underground Space Center
82. Milligan, Milligan, G Soil conditioning and lubricating agents in tunnelling and pipe jacking, In:Proceedings of Underground Construction 2001, London:105-116
83. Williamson et al. Soil conditioning for EPB shield tunneling on the South Bay Ocean Outfall. In:Proceedings of RETC 1999:897-925
84. Boone et al. Use of ground conditioning agents for Earth Pressure Balance machine tunneling[C]. In:AFTES (Ed.), Proceedings of Congres International de Chambery,2005:313-319
85.张凤祥,朱合华,傅德明.盾构隧道(第一版).北京:人民交通出版社,2004.9
86.宋永辉.上海地区粉土中EPB盾构施工扰动及不同土性改良方法的试验研究[D].上海:同济大学
87. Herrenknecht, M. EPB or slurry machine:the choice. Tunnels and Tunneling, June 1994:35-36
88. Guy Houlsby, Robert Marrit. Easing the Way Soil Conditioning, Tunnels and Tunnelling International,2003, (6):48--50
89.魏康林.土压平衡式盾构施工中“理想状态土体”的探讨,1994-2008China Academic Journal Electronic Publishing House,2007
90.张明晶.土压平衡式盾构施工闭塞问题的发生机理及防治措施研究[D],南京:河海大学,2004
91. Miguel Pena. Soil conditioning for sands. Tunnels and Tunneling,2003,28(4):40-42
92.魏康林.土压平衡式盾构施工中喷涌问题的发生机理及其防治措施研究[D],南京:河海大学,2003.3
93.林键.土体改良降低土压平衡式盾构刀盘扭矩的机理研究[D],南京:河海大学,2006.7
94.万里平,孟英峰,赵晓东.泡沫流体稳定性机理研究,新疆石油学院学报,2003(1)
95.郑坚.土压平衡盾构穿越流砂及复杂工况施工环境保护问题研究[D],上海:同济大学,2004.7
96. J. Monnet, S. Chafois, et al. Theoretical and experiment studies of a tunnel face in a grave site. Numerical Model in Geotechnics[M], S.Pietruszczak and G.N.Pande,1989
97. S. Chaffois& P. Lareai, J. Monnet. Study of tunnel face in a grave site, Numerical methods in Geomechnics[M], Swoboda (de), Balkma,1998
98.徐前卫,朱合华,廖少明.砂土地层盾构法施工的模型试验设计研究,地下空间与工程学报,2006,2(3):361-368
99.黄润秋,戚国庆.地铁隧道盾构法施工对环境的影响研究,岩石力学与工程学报,2003,22(增1):2464-2468
100.李向红,傅德明.土压平衡模型盾构掘进试验研究,岩土工程学报,2006,28(9):1101-1105
101.江招胜,郭广才,黄威然.富水砂层中土压平衡盾构施工的技术措施,城市轨道交通研究,2006(7):58-60
102.张军,管小军.分子结构与泡沫剂性能.山东建材,1998(6):8-9
103. H.R. Thomas, P.J. Cleall. Inclusion of expansive clay behaviour in coupled thermo hydraulic mechanical models. Engineering Geology,19999(54):93-108
104.沈珠江.土力学理论研究中的两个问题.岩土工程学报.1992,14(3):99-100
105.严继华.广州地铁复杂岩土性状分析与研究[D].中国矿业大学(北京).2005.6
106.赵杏媛,张有瑜.粘土矿物与粘土矿物分析[M].北京:海洋出版社,1990
107. Markus Tuller, Dani Or. Hydraulic functions for swelling soils:pore scale considerations. Journal of Hydrology,2003,272 (1):50-71
108.张乐天,王宗良.中国粘土矿物的电子显微镜研究[M].北京:地质出版社,1978
109. Yusuf Erzin, Orhan Erol. Swell pressure prediction by suction method. Engineering Geology,2007:1-13
110. Lynn Schreyer-Bennethum. Theory of flow and deformation of swelling porous materials at the macroscale. Computers and Geotechnics,2007:1-12
111. M. Fukue, T. Minato, H. Horibe, N. Taya. The micro-structures of clay given by resistivity measurements. Engineering Geology,1999,54:43-53
112.卢肇钧.非饱和土的抗剪强度与膨胀压力[C].非饱和土理论与实践学术研讨会论文集,1992:90-101
113. Zhi-bin Liu, Bin Shi, Hilary I. Inyang et al. Magnification effects on the interpretation of SEM images of expansive soils. Engineering Geology,2005, (78):89-94
114.夏蒙棼,韩闻生,柯孚久.统计细观损伤力学和损伤演化诱致突变(Ⅱ)[J].力学进展,1995,25(2):145-173
115. Quirk, J.P. Soil permeability in relation to sodicity and salinity. Phil.Trans.R.Soc.Lond.,1986(316):297-317
116. Ohshima, H. Effective Surface Potential and Doubble-layer Interaction of Colloidal Particles. J. Colloid Interf. Sci.,1995(174):45-52
117. Derjaguin, B.V.,Churaev, N.V., Muller, V.M. Surface Forces, Consultants Bureau, New York,1987
118. Derjaguin, B.V. Crrect form of the equation of capillary condensation in porous bodies. Proc. Second Int. Congr. Surf.,1957(2):153-159
119.中国石油天然气总公司.沉积岩粘土矿物相对含量X射线衍射分析方法.中华人民共和国石油天然气行业标准,1995.12
120.刘波,陶龙光,严继华等.广东地铁复杂红层岩土SEM微观实验研究[C].第十届土力学及岩土工程学术会议论文集.2007:406-411
121.谭罗荣.关于粘土岩崩解、泥化机理讨论.岩土力学.2001,22(1):1-5
122. E. Romero, A. Gens, A. Lloret. Water permeability, water retention and microstructure of unsaturated compacted Boom clay. Engineering Geology,1999, (54):117-127
123. Montheilet F, Gilomini P. Predicting the mechanical behavior of two-phase materials with cellular atutoma. Int J plasticity,1996,12(4):561-574
124.曾秋鸾.论广西红粘土的胀缩性能[J].广西地质.2000,13(3):75-77
125. Okagbue C O, Yakubu J A. Limestone ash waste as a substitute for lime in soil improvement for engineering construction. Bull Eng Geol Env,2000,58:107-113
126. Shang J Q, Tang M, Miao Z. Vacuum preloading consolidation of reclaimed land:a case study. Canadian Geolochnical Journal.1998,35(5):740-749
127.中国石油天然气总公司.沉积岩中粘土矿物总量和常见非粘土矿物X射线衍射定量分析方法.中华人民共和国石油天然气行业标准,1995.12
128.陈正汉,卢再华,朱元青.非饱和土理论与实践.力学与实践.2001,(23):8-15
129. Fredlund, Rahardjo. Soil Mechanics for Unsaturated Soils[M]. New York:John and Sons Inc,1993
130.王园.膨胀土的变形性能.工程勘察.1997(5):14-18
131. A.W.Bishop. The measurement of pore pressure in the triaxial test. Pore pressure and suction in soil. 1961:38-46
132.徐志英.岩石力学[M].北京:中国水利水电出版社,2001,9
133.谢定义.21世纪土力学的思考[J].岩土工程学报.1997,19(4)
134. A.W.Bishop, A.K.GEldin. Undrained triaxial test on saturated sands and their significance in the general theory of shear strength. Geotechnique.1950:13-32
135.何开胜.结构性粘土的微观变形机理和弹粘塑损伤模型研究[M].南京水利科学研究院.2001.6
136. A.W.Bishop, GE.Blight. Some aspects of effective stress in saturated and unsaturated soils. Geotechnique. 1963,13(3):177-197
137. D.GFredlund, N.R.Morgenstem. Stress state variables for unsaturated soils[J]. ASCE, Geotech.1977: 447-466
138. Van Olphen, H. An introduction to clay colloid chemistry[M]. John Wiley& Sons, New York.1977
140. Anadarajah, A. And Chen, J. Single correction function for computing rearded van der Waals attraction[J]. Colloid Interface Sci.,1995,6(2):293-300
141. Israelachvili.J.N..Intermolecular and Surface Forces[M], Secongd ed, Academic Press, New York,1991
142.卢肇钧.粘性土抗剪强度研究的现状与展望.土木工程学报,1999,32(4):3-9
143.D.GFredlund, N.RMorgenstem. Closure to paper entitled. Stress state variables for unsaturated soils. ASCE, Geot,Div,1978:1415-1416
144. V.Escario, Saez. The Shear Strength of partly saturated soil. Geotechnique.1986,36(3):453-456
145.卢肇钧,吴肖茗,孙玉珍等.膨胀力在非饱和土强度理论中的作用.岩土工程学报,1997,19(5):20-27
145. VerweyE J.W., O verbeek.J. G. Theory of the stability of lyophobic colloids'M]. Elsevier Publishing Company, Inc., New York.1948
146. Quirk, J.P. Soil permeability in relation to sodicity and salinity. Phil.Trans.R.Soc.Lond.,1986,316:297-317
147. Shu_San Hsiau, Shie_Chen Yang. Numerical simulation of self_diffusion and mixing in a vibrated graunular bed with cohesive effect of liquid bridges[J]. Chemical Engineering Science,2003(58):339-351.
148. B.J.Ennis, J.Li, GTardos, etal. The influence of viscocity on the strength of an axially strained pendular liquid bridge. Chemical Engineering Science,1990(45):3071-3088.
149. R Vinai et al. "Soil conditioning of sand for EPB applications:A laboratory research.", J,Tunnelling and Underground Space Technology,2008(23),308-317.
150.赵国玺,朱步瑶.表面活性剂作用原理[M](第一版),中国轻工业出版社,2003.1
151. Clunie J S, Ingram B T. Adsorption from solutions at the Solid/Liquid Interfaces[M]. Parfitt G D, Rochester C H, ed. Londun:Acad Press,1983.Ch 3
152.陶龙光,刘波.地铁盾构隧道沉降预测系统(STSP)研制及地铁隧道施工的环境影响研究.广州建委科技基金项目研究报告,2003.1
153.周维垣.高等岩石力学[M].北京:水利电力出版社,1990.6
154.钱七虎.岩土工程的第四次浪潮.地下空间,1999,19(4)
155.关宝树,国兆林.隧道及地下工程.西南交通大学出版社,2000
156.易萍丽.现代隧道设计与施工.中国铁道出版社,1997
157.刘宝琛.急待深入研究的地铁建设中的岩土力学课题.铁道建筑技术,2000(3):1~3
158.刘建航,侯学渊.盾构法隧道.北京:中国铁道出版社,1991.11
159.王梦恕.我国地下铁道施工方法综述与展望.地下空间,1998,18(2):98~103
160.张庆贺,柏炯.上海软土盾构法隧道的理论与实践.同济大学学报,1998,26(4):387-392
161.葛修润,任建喜.岩土损伤力学宏细观试验研究.北京:科学出版社,2004
162.陈仲颐,周景星,王洪瑾.土力学.北京:清华大学出版社,1992
163.赵杏媛,张有瑜.粘土矿物与粘土矿物分析.北京:海洋出版社,1990
164.王梦恕.我国地下铁道施工方法综述与展望.地下空间,Vol.18, No.2,1998:98-103
165.姜洪涛.红粘土的成因及其对工程性质的影响.水文地质工程地质,2000.3
166.魏康林,朱伟.盾构隧道施工技术发展新方向(J).河海大学学报(自然科学版),2001.29
167.张向京,杨果林.膨胀土的化学改良试验研究.山西建筑,vol.30. NO.19,2004:80
168.孙均.市区基坑开挖施工的环境土工问题.地下空间,Vol.19, No.4,1999:257-265
169.仵彦卿.地下水与地质灾害.地下空间,Vol.19, No.4,1999:303-310
170.黄润秋.深埋长隧道工程开挖的主要地质灾害问题研究.地质灾害与环境保护,Vol.8, No.1,1997:59~67
171.张镜剑.TBM的应用及其有关问题和展望.岩石力学与工程学报,第18卷第3期,1984.6
172.董云德.上海地铁盾构隧道的设计和施工[J].施工技术,1996,26(1):7~10
173.崔玖江.隧道与地下工程施工技术现状及问题对策[J].施工技术,2001,30(1):3~6
174.何焕雄,曹国金.盾构法施工技术及其在我国的发展和应用.建筑技术开发,Vol.31, No.4,2004.4:106~108
175.傅德明,周文波.土压盾构技术在我国地铁隧道工程中的应用和发展.岩石力学与工程学报,Vo1.23,No.2,2004.7:4888~4892
176.张国京,刘盈.土压平衡盾构施工中土的塑流化技术.市政技术,Vol.23, No.5,2005.9:293-296
177.朱伟,秦建设,魏康林.土压平衡盾构喷涌发生机理研究.岩土工程学报,Vol.26, No.5,2004.9:589-593
178.唐益群.土压平衡盾构在砂性土中施工问题的试验研究.地下工程与隧道,Vol.24, No.1,2005.1:52-56
179.竺维彬,鞠世健.盾构施工泥饼(次生岩块)的成因及对策地下工程与隧道,No.2,2003:25~29
180.白衫,周洁.中国隧道盾构掘进机的发展和应用.隧道机械与施工技术,2004:41~43
181.雏建斌.薄膜润滑实验技术和特性研究[D],北京:清华大学精密仪器与机械学系,1994
182.曲庆文.薄膜润滑性能研究.学位论文,1997.12
183.董勋.润滑理论.上海交通大学出版社,1984.9
184.Peck R B. Deep excavation and tunneling in soft ground[M]. New York, Published by ASCE,1984
185. Robert Sarsby. Environmental Geotechnics[M]. Publisher:Thomas Telford,2000
186.施忠凯.潮湿煤颗粒间液桥力的理论研究,选煤技术,2001(5):11-13
187.李志.料仓中湿颗粒流动规律的数值仿真与试验研究,海南大学学报自然科学版,2004,22(1):23-27
188.赵永椿.细颗粒物团聚促进机制的实验研究,化工学报,2001,58(11):2876-2880
199.刘波,陶龙光.广州地铁复杂红层岩土SEM微观实验研究[C],中国土木工程学会第十届土力学及岩土工程学术会议论文集,2008.5
200. B. Liu, L.G Tao, T. Li, GG Qiao et al. SEM Microstructure and SEM Mechanical Tests of Swelling Red Sandstone in Guangzhou Metro Engineering, boundaries of rock mechanics[C], London:Taylor& Francis Group,2008.5:99-104