油页岩原位热解与煤地下气化耦合过程研究
|
摘要
将煤炭地下气化技术理论引入到油页岩原位开采应用中,针对我国油页岩多与煤互层伴生的特点,提出并研究了油页岩与煤地下共气化原位开采油页岩技术,在实现油页岩的原位开采的同时提高气化煤气的热值和品质,提高能源综合利用效率。基于油页岩与煤地下共气化的过程特点,采用微观实验手段研究了油页岩原位热解特性,通过模型试验及数值模拟研究了共气化的过程中油页岩层及煤层的温度场演化规律、油气组分互动特性及共气化过程的热流固耦合特征,从而构建了油页岩与煤地下共气化工艺。研究结果表明,300~550℃是油页岩中有机质集中析出的温度区间;400~600℃油页岩中孔隙数量和孔隙体积增长最快的区间,油页岩及半焦孔隙结构具有明显的分形特征,油页岩及600℃半焦分形维数最低;油页岩随着热解温度的升高渗透性先升高后降低,400℃时渗透率最大,孔隙压力增大使渗透率降低;随着油页岩粒径的增大,最大产气量下降,最大产气量对应温度点向高温区移动,页岩油中烷烃含量逐渐降低,芳香族化合物含量逐渐升高;油页岩与煤地下共气化过程中,氧气浓度为40-45%时,煤层升温速率为7℃/min,气化面的扩展速率为0.036m/h,油页岩层与煤层的升温速率一致且进展稳定,煤气中不饱和烃含量增加,热值提高;随着气化温度的升高,煤层与油页岩层的压力梯度逐渐增大。
and coal resources associated in our country,the technology of in-situ mining oil shaleby underground co-gasification coal and oil shale was creatively put forward.Thistechnology can realize in-situ mining oil shale, improve heat-value and quality of gas.Based on the process characteristics of underground co-gasification of the oil shaleand coal,adopting microscopic experiments, the thermal properties of oil shale werestudied and analized systematically; Adopting model test and numerical simulation,the evolution law of temperature field of oil shale layer and coal layer, interactivefeatures and oil and gas and heat fluid solid coupling characteristics duringco-gasification were studied; Combining the results of experiment and model test, theunderground co-gasification technology of oil shale and coal was constructed.Theresults show that:(300~550℃)is the main phase in which most of organic matter wasreleased. pore volume and quailities increase fastly in400℃~600℃; oil shale andsemicoke have obvious fractal characteristic, oil shale and semicoke of600℃havethe lowest fractal dimensions.the permeability of oil shale increases first and thendecreases, corresponding temperature of peak is400℃, with increasing of porepressure, permeability decline; With the increasing of oil shale particle size, themaximum gas production declined, the temperature corresponding to the maximumgas production moved to the high temperature zone. whenφ(O2)is40-45%,temperature-rising rate is7℃/min、extend rate of gasification face is0.036m/h, theextend of temperature field is continuous and stable, the temperature change of oilshale and coal are synchronously. With the increase of temperature, the pressuregradient of coal and oil shale layer improve.
and coal resources associated in our country,the technology of in-situ mining oil shaleby underground co-gasification coal and oil shale was creatively put forward.Thistechnology can realize in-situ mining oil shale, improve heat-value and quality of gas.Based on the process characteristics of underground co-gasification of the oil shaleand coal,adopting microscopic experiments, the thermal properties of oil shale werestudied and analized systematically; Adopting model test and numerical simulation,the evolution law of temperature field of oil shale layer and coal layer, interactivefeatures and oil and gas and heat fluid solid coupling characteristics duringco-gasification were studied; Combining the results of experiment and model test, theunderground co-gasification technology of oil shale and coal was constructed.Theresults show that:(300~550℃)is the main phase in which most of organic matter wasreleased. pore volume and quailities increase fastly in400℃~600℃; oil shale andsemicoke have obvious fractal characteristic, oil shale and semicoke of600℃havethe lowest fractal dimensions.the permeability of oil shale increases first and thendecreases, corresponding temperature of peak is400℃, with increasing of porepressure, permeability decline; With the increasing of oil shale particle size, themaximum gas production declined, the temperature corresponding to the maximumgas production moved to the high temperature zone. whenφ(O2)is40-45%,temperature-rising rate is7℃/min、extend rate of gasification face is0.036m/h, theextend of temperature field is continuous and stable, the temperature change of oilshale and coal are synchronously. With the increase of temperature, the pressuregradient of coal and oil shale layer improve.
引文
1.钱家麟,尹亮.油页岩:中国的补充能源[M].北京:中国石化出版社,2008
2.侯祥麟.中国页岩油工业[M].北京:石油工业出版社.1984
3.秦宏,姜秀民,孙键等.中国油页岩的能源利用[J].节能,1997,12:17-18
4.郭永刚,许修强,王红岩等.非常规能源油页岩开发利用的研究进展[J].江苏化工,2008,36(2):6-9
5.刘招君,董清水,叶松青等.中国油页岩资源现状[J].吉林大学学报,地球科学版,2006,36(6):869-876
6. Dyni J.R.,Geology and resources of some world oil shale deposits[J].Oil Shale,2003,20(3):193-252
7.李术元,钱家麟.世界油页岩开发利用现状及预测[J].中外能源.2011,16(2):8-18
8.钱家麟,王剑秋,李术元.世界油页岩资源利用和发展趋势[J].吉林大学学报(地球科学版),2006,36(6):877-887
9.高书香,曹克广,陈殿义等.油页岩的地下转化工艺[J].承德石油高等专科学校学报,2007,9(6):1-4
10.刘德勋,王红岩,郑德温等.世界油页岩原位开采技术进展[J].天然气工业,2009,29(5):128-148
11. Shell Frontier Oil and Gas Inc.Technology to secure our energy future-mahogany researchproject [EB/OL][2007-02-15].
12. Shell Frontier Oil and Gas Inc.E-ICP project plan of operation-oil shale research anddevelopment project[R].Houston:Bureau of Land Management U.S.2006.
13.国际壳牌研究有限公司.传导加热地下油页岩以赋予其渗透性并随后采油:荷兰,E21b43/28,87100890[P].1988-08-31.
14.刘胜英,王世辉,陈春瑞.壳牌公司页岩油开采技术进展[J].大庆石油学院学报,2007,31(6)53-55
15.美国能源部.Secure fuels from domestic resources:the continuing evolution of America oilshale and tar sands industries[R].[S.l.]:[s.n.],2007.
16.太原理工大学.高温烃类气体对流加热油页岩开采油气的方法:中国,E21B43/24,200710139353.X.[P].2006-09-06.
17.孙可明,赵阳升,杨栋.非均质热弹塑性损伤模型及其在油页岩地下开发热破裂分析中的应用.岩石力学与工程学报[J].2008,27(1):42-52.
18.刘招君.中国油页岩[M].石油工业出版社,2009
19.钱家麟,王剑秋.世界油页岩发展近况[J].中外能源,2007,12(1):42-52
20. Wikipedia.Oil Shale Extration[M].2008.
21. BURNHAMAK,MCCONACHYJR.Comparison of the acceptability of various oil shaleprocesses [R].26th Oil Shale Symposium.Colorado School of Mines,2006.
22. Hubbard A.B.,Robinson C.D..A thermal decomposition study of Colorado oil shale,U.S.Bureou of Mincs,Report Invest.,No.4744,Nov.1950
23. Cane R.F.,oil shale and cannel coal[M],vol.2.,inst.petroleum,london,1951
24. Allred V.O..Kinetics of oil shale pyrolysis[J].Chemical Engineering Progress,1966,62(8):55-60
25. Fausett D.W..Proceedings of the8th Oil Shale Symposium[J].Colorado School of Mines,1975,70(3):273-313
26. Campbell J.H.,Gallegos G.,Gregg M..Gas evolution during oil shale pyrolysis,
2.Kinetics and stoichiometric analysis[J]. Fuel,1980,59(10):727-732
27. Allred V D.Kinetics of oil shale pyrolysis[M],Chem.Eng.Proc,1996
28. M.V.Kok,M.R.Pamir.Comparative pyrolysis and combustion kinetics of oil shale[J],Anal.Appl.Pyrolysis,2000,55(2):185-194
29. Y.Wang and S.lee. A single particle model for pyrolysis of oil shale[J], Fuel Science andTechnology International,1986,4(4):447-481.
30. BAUMAN J,BHIDE R,DEO M.An evalution of porosity and permeability changes in oilshale due to thermal stresses [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
31. TWARI P,DEO M.Experimental analysis of the multiscale oil shale pyrolysis [C]//31st oilshale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
32. FACELI J,ORENDT A,BADU S,et al.Atomistic modeling of oil shale kerogen andasphaltenes [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
33. AL–THYABAT S,ABD-ALRAZAG E.Preliminary evaluation of Jordanian oil shaleupgrading by froth flotation [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
34. ALNAWAFLEH H,FRAGE F.Characterization and shale oil yield evalution of Jordanian oilshale [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
35. WOLFSON A,ELMUGRABI Y,LEVI R,et al.Green process for simultaneous extractionof oil shale and enrichment of ethanol[J].oil shale,2011,28(4):516-527
36.王剑秋,李术元,杨克勇.利用热重仪进行颗粒页岩干馏的研究[J].石油大学学报,自然科学版,1988,12(4-5):104-109
37.王道钰,王德进,钱家麟.油页岩和省油岩热解平行和连续反应模型的研究和数值计算[J].华东石油学院学报,1985,(3):95-99
38. Nuttall H.E,郭天民,Schader S..Thakur D S.,世界上几种主要油页岩的热解动力学[C],油页岩科学研究论文集,华东石油学院出版,北京,1984,128-148
39.丁福臣,王剑秋,钱家麟.油页岩压力热解动力学研究[J].石油学报(石油加工),1991,7(4):20-27
40.王廷芬,陆绍信.抚顺油页岩热解动力学方程探索[J].华东石油学院学报,1982,5(3):1-8
41.李术元,钱家麟,秦匡宗,朱亚杰.油页岩热解本征动力学的研究[J],Ⅱ.不同数学模型的计算结果.石油学报(石油加工),1986,2(3):1-10
42.杨继涛,陈廷蕤.热重法确定抚顺油页岩热解动力学参数[J].华东石油学院学报,1983,(2):188-194
43.杨继涛,陈廷蕤.茂名油页岩非等温热解的动力学研究[J].石油炼制,1983,(12):41-47
44.杨继涛,陈廷蕤,抚顺油页岩热分解过程的热重法研究[J].石油学报,1984,5(2):107-117
45.李术元.块状油页岩的热解及其传热传质的研究[D].北京,石油大学,1989
46.李术元,钱家麟,秦匡宗,朱亚杰.沥青作为中间产物的油页岩热解动力学的研究[J].燃料化学学报,1987,15(2):118-123
47.王廷芬.关于油页岩燃烧性能的差热分析法研究[J].华东石油学院学报,1983,7(1):97-107
48.王廷芬,王剑秋.用热分析法研究油页岩与空气的反应[J].北光通讯.1987,(1):22-32
49. Wang J.Q.,Zhang Q.,Qian J.L..Pressurized combustion behavior of oil shale and coaland its kinetics[C].Proceddings of the2ndinternational symposium on coal combustionscience and technology,Beijing, China,October7-10,1991,137-143
50.张庆轩,王贤清,钱家麟,朱亚杰.颗粒油页岩燃烧动力学模型的研究[J].石油学报(石油加工),1987,3(3):1-9
51.李术元,钱家麟,王剑秋,块状油页岩热解过程的研究,Ⅰ热解反应动力学参数[J].石油学报(石油加工),1990,6(4):86-93
52.李术元,钱家麟,王剑秋,块状油页岩热解过程的研究,Ⅱ页岩块内部热传导过程[J].石油学报(石油加工)1991,7(1):20-27
53.李术元,钱家麟,王剑秋.抚顺炉加工约旦页岩时干馏段的核算[J].石油学报(石油加工),1992,8(1):94-100
54.王剑秋,李术元,杨克勇.利用热重仪进行颗粒页岩干馏的研究[J].石油大学学报,自然科学版,1988.12(4-5):104-109
55.李少华,柏静儒.升温速率对油页岩热解特征的影响[J].化学工程,2007,35(1):64-67.
56.孙佰仲,谭平,贾春霞等.油页岩燃烧过程的DSC实验研究[J].东北电力大学学报,2008,28(6):105-108
57.于海龙,姜秀民.升温速率对油页岩燃烧特征与动力学参数的影响[J].燃烧科学与技术,2003,9(1):54-57.
58.于海龙,姜秀民.颗粒粒度对油页岩热解特性和动力学参数的影响[J].中原工学院学报,2007,18(1):1-5.
59.于海龙,姜秀民.桦甸油页岩热解特征的研究[J].燃料化学学报,2001,29(5):450-453.
60.雷怀玉,王红岩.柳树河油页岩的热解特征及动力学[J].吉林大学学报(地球科学版),2012,42(1)::25-29.
61. FANG Chaohe,YAO Jiangjun.ZHENG Dewen.Microwave processing of oil shale andcharacterization of shale oil generated by microwave retorting [C]//31stoil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
62.刘洪林,刘德勋,方朝合等.利用微波加热开采地下油页岩的技术[J].石油学报,2010,31(4):623-625
63.刘钧荣,秦积舜等.温度对岩石渗透率影响的实验研究[J].石油大学学报(自然科学版),2001,25(4):51-53.
64.梁冰,高红梅等.岩石渗透率与温度关系的理论分析和试验研究[J].岩石力学与工程学报,2005,24(12):2009-2012
65.李志强,鲜学福.煤体渗透率随温度和应力变化的实验研究[J].辽宁工程技术大学学报(自然科学版),2009,28(4):156-159
66.赵阳升,冯增朝,杨栋.对流加热油页岩开采油气的方法:中国,200510012473[P].2005.10.01
67.康志勤,吕兆兴,杨栋等.油页岩原位注蒸汽开发的固—流—热—化学耦合数学模型研究[J].西安石油大学学报(自然科学版),2008,23(4):29-34
68.康志勤,赵阳升,杨栋.利用原位电法加热技术开发油页岩的物理原理及数值分析[J].石油学报,2008,29(4):592-595
69.杨栋,赵静,康志勤,赵阳升.电法原位加热油页岩采油技术与数值分析[J].辽宁工程技术大学学报(自然科学版),2010,29(3):365-368
70.杨栋,薛晋霞,康志勤等.抚顺油页岩干馏渗透实验研究[J],西安石油大学学报(自然科学版),2007,22(2):23-25
71.刘中华,杨栋,薛晋霞等.干馏后油页岩渗透规律的实验研究[J],太原理工大学学报,2007,37(4):414-416
72.李术元,唐勋,王娟.油页岩地下干馏热压模拟实验研究[M]//王红岩,刘振文,宁宁.油页岩资源及开发工艺技术.北京:石油工业出版社,2010,80-85.
73. MA Yue,MA Guili,LI Shuyuan.Study of oil shale pyrolysis to simulate in-situ conversionprocess[C]//31stoil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
74.韩向新,姜秀民.油页岩颗粒孔隙结构在燃烧过程中的变化[J].中国电机工程学报,2007,27(2):27-30
75.刘柏谦.油页岩及其流化床燃烧[M].长春:吉林科学技术出版社,1999.
76.孙佰仲,周明正,刘洪鹏,等.油页岩流化燃烧过程中表面特性的变化[J].动力工程,2008,28(2):250-254
77.孙佰仲,王擎,李少华,等.桦甸油页岩及半焦孔结构的特性分析[J].动力工程,2008,28(1):163-167
78.王廷芬,陆绍信,朱亚杰.我国油页岩热性质的研究,Ⅱ油页岩、半焦和页岩灰比热容的测定[J].燃料化学学报,1987,15(4):311-316
79.陆绍信、陈廷蕤,沈志虹,等.我国油页岩热性质研究——油页岩的热膨胀性能[J].石油学报(石油加工),1990,6(2):95-99
80.陆绍信,王廷芬.约旦油页岩热物理性质及热解性能的研究[R].华东石油学院北京研究生部,1987
81.余力.煤炭地下气化学术论文集[C].北京,2003
82.余力,梁杰,余学东.煤炭资源开发与利用新方法—煤炭地下气化技术[J].科技导报,1999(4)
83.余力.研究与开发煤炭地下气化技术[J].科技导报,1999(2)
84.余力.―长通道、大断面‖煤炭地下气化新工艺[J].中国煤炭,2002,28(12):7-10
85.江道罴.对煤炭地下气化的认识与实践[J].煤矿设计,2001(4):9-12
86.郎成忠.页岩油工业分析方法[Z].抚顺石油炼制研究所.抚顺,1980
87. ASTM D3904—90Standard test method for oil shale (Resource ecaluation by the Fischerassay procedure)[Z]
88.秦匡宗,郭绍辉.茂名和抚顺油页岩组成结构的研究,Ⅳ.矿物质的含量和组成[J].燃料化学学报,1987.15(1):1-8
89.李强.油页岩原位热裂解温度场数值模拟及实验研究[D].吉林,吉林大学.2012
90.康志勤.油页岩热解特性及原位注热开采油气的模拟研究[D].太原,太原理工大学,2008
91.刘丽丽.大粒度油页岩热解特性实验研究[D].北京,中国矿业大学,2011
92. Rajeshwar K.,Nottenburg R.,Dubow J..Review Thermophysical properties of oilshales[J].Journal of Materials Science,1979,14:2025-2052
93. Yang J T..Investigation on pyrolysis of Huangxian oil shale between550~750℃,In ZhuY.J.,ed.Proceedings of International Conference on Oil Shale and Shale Oil[J].Beijing,Chemical Industry Press,1988:263-270
94.耿丽文,郭树才.我国几种油页岩热重法热解动力学研究[R].大连工学院煤化工研究室,大连,1984
95.吴肇亮,徐伟民,杨国华,等.生油岩热解生烃反应动力学的几种数学模型的适用性讨论[C].全国油气资源量研讨会论文,扬州,1990
96.王道钰,王德进,钱家麟.油页岩和生油岩热解平行和连续反应模型的研究和数值计算[J].华东石油学院学报,1985(3):95-99
97. Nuttal H E,Guo T M.Pyrolysis kinetics of several world key oil shales[J].ACS Symposiumseries,230,269~300,1983
98.向银花,王洋,张建民,等.煤焦气化过程中比表面积和孔容积变化规律及影响因素研究[J].燃料化学学报,2002,30(2):108-112
99.陈鸿.煤焦燃尽动力学及孔隙结构的研究[D].武汉:华中理工大学,1993
100.刘辉,吴少华,姜秀民,等.快速热解褐煤焦的低温氮吸附等温线形态分析[J].煤炭学报,2005,30(4):508-512
101.张慧.煤孔隙的成因类型及其研究[J].煤炭学报,2001,26(1):39-43
102.秦跃平,傅贵.煤孔隙分形特征及其吸水性能的研究[J].煤炭学报,2000,25(1):55-59
103.宋微娜,董永利,周国江,等.油页岩结构组成及应用研究[J].黑龙江水专学报,2010,37(3):70-73
104. J. R. Dyni. Geology and Resources of Some World Oil shale Deposits[J]. OilShale.2003,20(3):193-252
105.严继民,张培元.吸附与凝聚[M].北京:科学出版社,1979
106.陈萍,唐修义.低温氮吸附法与煤中微孔隙特征的研究[J].煤炭学报,2001,26(5):552-556
107.殷艳玲.孔隙结构分形维数测试与应用研究进展[J].内蒙古石油化工,2008,(9):109-111
108. Angulo R F, A lvaradov and Gonzalez H. F ractal dimensions from mercury in trusioncapillary tests[R].SPE23695,1992
109. Thampaon A H. Katz A J, Krohn C E, the microgeometry and transportproperties ofsandtones[J]. Advances in physic,1987,36(5):625-631
110.李大勇,藏式宾,任晓娟,等.用分形理论研究低渗透储层孔隙结构[J].辽宁化工,2010,39(7):723-726
111.李留仁,赵艳艳,李忠兴,等.多孔介质微观孔隙结构分形特征及分形系数的意义[J].石油大学学报(自然科学版),2004,28(3):105-108
112.童宏树,胡宝林.鄂尔多斯盆地煤储层低温氮吸附孔隙分形特征研究[J].煤炭技术,2004,23(7):1-3
113. Katz A J,Thompson A H.Fractal sandstone pore:implication for conductivity and poreformation[J].Phys.Rev.Lett.,1986,33B(9):6366-6374
114.张玉涛,王德明,仲晓星.煤孔隙分形特征及其随温度的变化规律[J].煤炭科学技术,2007,35(11):46-49
115.张占存.煤的吸附特征及煤中孔隙的分布规律[J].煤矿安全,2006,9:1-4
116.刘均荣,秦积顺,吴晓东.温度对岩石渗透率影响的实验研究[J].石油大学学报,2001,25(4):51-53
117.张广洋,胡耀华,姜德义,等.煤的渗透性实验研究[J].贵州工业大学学报,1995,24(4):65-68.
118.李志强,鲜学福,隆晴明.不同温度应力条件下煤体渗透率实验研究[J].2009,38(4)
119.陈占清,缪协兴.影响岩石渗透率的因素分析[J].
120.高浩锋,张金功,罗文琴,等.砂岩、泥质岩和煤岩渗透率的研究[J].石油化工应用,2011,30(4):4-7
121.易俊,姜永东,鲜学福.应力场、温度场瓦斯渗流特性实验研究[J].中国矿业,2007,16(5):113-117
122.梁冰,高红梅,兰永伟.岩石渗透率与温度关系的理论分析和试验研究[J].岩石力学与工程学报,2005,24(12):2009-2012
123.陈祖安,伍向阳,方华.岩石气体介质渗透率的瞬态测量方法[J].地球物理学报,1999,42(增刊):167-171
124.隆清明,赵旭升,牟景珊.孔隙气压对煤层气体渗透性影响的试验研究[J].矿业安全与环保,2008,35(1):10-13
125.肖晓春,潘一山.滑脱效应影响的低渗煤层气运移实验研究[J].岩土工程学报,2009,31(10):1554-1557
126.陈代珣.渗透气体滑脱现象与渗透率变化的关系[J].力学学报,2002,34(1):96-100
127. A.M. Rubel, E. Davis, The effect of shale particle size on the products from the bench scalefixed bed pyrolysis of Kentucky Sunbury shale[C]. Eastern Oil Shale Symposium. KentuckyEnergy Cabinet, Lexington, Kentucky,1985:43:95-99
128. Nasir Ahmad1, Paul T. Williams. Influence of particle grain size on the yield andcomposition of products from the pyrolysis of oil shales[C]. Journal of Analytical andApplied Pyrolysis.1998,46:31-49
129. J.O. Jabera, S.D. Proberta, P.T. Williams. Evaluation of oil yield from Jordanian oil shales[J].Energy.1999,24:761-781
130. J. Hanna, W.E. Lamont, Effect of sulphur and particle size on Fischer assay oil yields from oilshale[C]. Eastern Oil Shale Symposium, Kentucky Energy Cabinet, Lexington, Kentucky,1987,35:343-348
131.张强林,王媛.岩体THM耦合应用研究现状综述[J].河海大学学报,2007,35(5):538-541
132. NeauPane K M, Yamabe T, Yoshinaka R. Simulation of a fully coupledthermo-hydro-mechanical system in freezing and thawing rock[J].Int J Rock Mech Min Sci,1999,36(2):563-580
133.周江,福井正则.岩体中渗流-热-应力耦合作用的理论研究[J].山西矿业学院学报,1995,13(1):76-81
134.赖远明,吴紫汪,朱元林,等.寒区隧道温度场、渗流场和应力场耦合问题的非线性分析[J].岩土工程学报,1999,21(5):529-533
135.刘亚晨,刘泉声,吴玉山,等.核废料贮库围岩介质不可逆过程热力学和热弹性[J].岩石力学与工程学报,2000,19(5):361-365
136.黄涛,杨立中,陈一立.工程岩体地下水渗流-应力-温度耦合作用数学模型的研究[J].西南交通大学学报,1999,34(1):11-15
137.贺玉龙,杨立中,杨吉义.非饱和岩体三场耦合控制方程[J].西南交通大学学报,2006,41(4):419-423
138.康志勤,吕兆兴,杨栋,等.油页岩原位注蒸汽开发的固—流—热化学耦合数学模型研究[J].西安石油大学学报(自然科学版),2008,23(4):35-38
139.刘善利,赵坚.饱和岩体热流固耦合数学模型研究[Z].中国科技论文在线
140.杨兰和,煤炭地下气化干馏气渗流运动多场耦合数值模拟[J].西安交通大学学报,2002,36(7):752-756
141.张强林,王媛.岩体THM耦合模型控制方程建立[J].西安石油大学学报,2007,22(2):139-145
142.王自明,油藏热流固耦合模型研究及应用初探[D].博士学位论文
143.顾泽同,葛永乐,翁中杰等.工程热应力[M].北京:国防工业出版社,1987
144.孔祥言,李道伦,徐献芝等.热-流-固耦合渗流的数学模型研究[J].水动力学研究与进展.2005,20(2):269-275
145.杨兰和.煤炭地下气化三维非线性动态温度场数值模拟[J].中国矿业大学学报,2000,29(2):140-143
146.杨兰和.煤炭地下气化三维非稳定对流扩散的数学模型[J].西安交通大学学报,2000,34(1):44-48
147.杨兰和.煤炭地下气化三维渗流数学模型的研究[J].中国矿业大学学报,2000,29(5):528-531
148.杨兰和.两阶段煤炭地下气化温度场模型[J].化工学报,2001,52(3):273-276
149. Yang Lanhe, Liang Jie, Yu Li.Double fire-two stage method and parameter calculation ofunderground coal gasification[J].Journal of China University of Mining&Technology,2000,10(2):116~119
150.吴世跃.煤层中的耦合运动理论及其应用—具有吸附作用的气固耦合运动理论[M].北京:,科学出版社,2009
2.侯祥麟.中国页岩油工业[M].北京:石油工业出版社.1984
3.秦宏,姜秀民,孙键等.中国油页岩的能源利用[J].节能,1997,12:17-18
4.郭永刚,许修强,王红岩等.非常规能源油页岩开发利用的研究进展[J].江苏化工,2008,36(2):6-9
5.刘招君,董清水,叶松青等.中国油页岩资源现状[J].吉林大学学报,地球科学版,2006,36(6):869-876
6. Dyni J.R.,Geology and resources of some world oil shale deposits[J].Oil Shale,2003,20(3):193-252
7.李术元,钱家麟.世界油页岩开发利用现状及预测[J].中外能源.2011,16(2):8-18
8.钱家麟,王剑秋,李术元.世界油页岩资源利用和发展趋势[J].吉林大学学报(地球科学版),2006,36(6):877-887
9.高书香,曹克广,陈殿义等.油页岩的地下转化工艺[J].承德石油高等专科学校学报,2007,9(6):1-4
10.刘德勋,王红岩,郑德温等.世界油页岩原位开采技术进展[J].天然气工业,2009,29(5):128-148
11. Shell Frontier Oil and Gas Inc.Technology to secure our energy future-mahogany researchproject [EB/OL][2007-02-15].
12. Shell Frontier Oil and Gas Inc.E-ICP project plan of operation-oil shale research anddevelopment project[R].Houston:Bureau of Land Management U.S.2006.
13.国际壳牌研究有限公司.传导加热地下油页岩以赋予其渗透性并随后采油:荷兰,E21b43/28,87100890[P].1988-08-31.
14.刘胜英,王世辉,陈春瑞.壳牌公司页岩油开采技术进展[J].大庆石油学院学报,2007,31(6)53-55
15.美国能源部.Secure fuels from domestic resources:the continuing evolution of America oilshale and tar sands industries[R].[S.l.]:[s.n.],2007.
16.太原理工大学.高温烃类气体对流加热油页岩开采油气的方法:中国,E21B43/24,200710139353.X.[P].2006-09-06.
17.孙可明,赵阳升,杨栋.非均质热弹塑性损伤模型及其在油页岩地下开发热破裂分析中的应用.岩石力学与工程学报[J].2008,27(1):42-52.
18.刘招君.中国油页岩[M].石油工业出版社,2009
19.钱家麟,王剑秋.世界油页岩发展近况[J].中外能源,2007,12(1):42-52
20. Wikipedia.Oil Shale Extration[M].2008.
21. BURNHAMAK,MCCONACHYJR.Comparison of the acceptability of various oil shaleprocesses [R].26th Oil Shale Symposium.Colorado School of Mines,2006.
22. Hubbard A.B.,Robinson C.D..A thermal decomposition study of Colorado oil shale,U.S.Bureou of Mincs,Report Invest.,No.4744,Nov.1950
23. Cane R.F.,oil shale and cannel coal[M],vol.2.,inst.petroleum,london,1951
24. Allred V.O..Kinetics of oil shale pyrolysis[J].Chemical Engineering Progress,1966,62(8):55-60
25. Fausett D.W..Proceedings of the8th Oil Shale Symposium[J].Colorado School of Mines,1975,70(3):273-313
26. Campbell J.H.,Gallegos G.,Gregg M..Gas evolution during oil shale pyrolysis,
2.Kinetics and stoichiometric analysis[J]. Fuel,1980,59(10):727-732
27. Allred V D.Kinetics of oil shale pyrolysis[M],Chem.Eng.Proc,1996
28. M.V.Kok,M.R.Pamir.Comparative pyrolysis and combustion kinetics of oil shale[J],Anal.Appl.Pyrolysis,2000,55(2):185-194
29. Y.Wang and S.lee. A single particle model for pyrolysis of oil shale[J], Fuel Science andTechnology International,1986,4(4):447-481.
30. BAUMAN J,BHIDE R,DEO M.An evalution of porosity and permeability changes in oilshale due to thermal stresses [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
31. TWARI P,DEO M.Experimental analysis of the multiscale oil shale pyrolysis [C]//31st oilshale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
32. FACELI J,ORENDT A,BADU S,et al.Atomistic modeling of oil shale kerogen andasphaltenes [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
33. AL–THYABAT S,ABD-ALRAZAG E.Preliminary evaluation of Jordanian oil shaleupgrading by froth flotation [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
34. ALNAWAFLEH H,FRAGE F.Characterization and shale oil yield evalution of Jordanian oilshale [C]//31st oil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
35. WOLFSON A,ELMUGRABI Y,LEVI R,et al.Green process for simultaneous extractionof oil shale and enrichment of ethanol[J].oil shale,2011,28(4):516-527
36.王剑秋,李术元,杨克勇.利用热重仪进行颗粒页岩干馏的研究[J].石油大学学报,自然科学版,1988,12(4-5):104-109
37.王道钰,王德进,钱家麟.油页岩和省油岩热解平行和连续反应模型的研究和数值计算[J].华东石油学院学报,1985,(3):95-99
38. Nuttall H.E,郭天民,Schader S..Thakur D S.,世界上几种主要油页岩的热解动力学[C],油页岩科学研究论文集,华东石油学院出版,北京,1984,128-148
39.丁福臣,王剑秋,钱家麟.油页岩压力热解动力学研究[J].石油学报(石油加工),1991,7(4):20-27
40.王廷芬,陆绍信.抚顺油页岩热解动力学方程探索[J].华东石油学院学报,1982,5(3):1-8
41.李术元,钱家麟,秦匡宗,朱亚杰.油页岩热解本征动力学的研究[J],Ⅱ.不同数学模型的计算结果.石油学报(石油加工),1986,2(3):1-10
42.杨继涛,陈廷蕤.热重法确定抚顺油页岩热解动力学参数[J].华东石油学院学报,1983,(2):188-194
43.杨继涛,陈廷蕤.茂名油页岩非等温热解的动力学研究[J].石油炼制,1983,(12):41-47
44.杨继涛,陈廷蕤,抚顺油页岩热分解过程的热重法研究[J].石油学报,1984,5(2):107-117
45.李术元.块状油页岩的热解及其传热传质的研究[D].北京,石油大学,1989
46.李术元,钱家麟,秦匡宗,朱亚杰.沥青作为中间产物的油页岩热解动力学的研究[J].燃料化学学报,1987,15(2):118-123
47.王廷芬.关于油页岩燃烧性能的差热分析法研究[J].华东石油学院学报,1983,7(1):97-107
48.王廷芬,王剑秋.用热分析法研究油页岩与空气的反应[J].北光通讯.1987,(1):22-32
49. Wang J.Q.,Zhang Q.,Qian J.L..Pressurized combustion behavior of oil shale and coaland its kinetics[C].Proceddings of the2ndinternational symposium on coal combustionscience and technology,Beijing, China,October7-10,1991,137-143
50.张庆轩,王贤清,钱家麟,朱亚杰.颗粒油页岩燃烧动力学模型的研究[J].石油学报(石油加工),1987,3(3):1-9
51.李术元,钱家麟,王剑秋,块状油页岩热解过程的研究,Ⅰ热解反应动力学参数[J].石油学报(石油加工),1990,6(4):86-93
52.李术元,钱家麟,王剑秋,块状油页岩热解过程的研究,Ⅱ页岩块内部热传导过程[J].石油学报(石油加工)1991,7(1):20-27
53.李术元,钱家麟,王剑秋.抚顺炉加工约旦页岩时干馏段的核算[J].石油学报(石油加工),1992,8(1):94-100
54.王剑秋,李术元,杨克勇.利用热重仪进行颗粒页岩干馏的研究[J].石油大学学报,自然科学版,1988.12(4-5):104-109
55.李少华,柏静儒.升温速率对油页岩热解特征的影响[J].化学工程,2007,35(1):64-67.
56.孙佰仲,谭平,贾春霞等.油页岩燃烧过程的DSC实验研究[J].东北电力大学学报,2008,28(6):105-108
57.于海龙,姜秀民.升温速率对油页岩燃烧特征与动力学参数的影响[J].燃烧科学与技术,2003,9(1):54-57.
58.于海龙,姜秀民.颗粒粒度对油页岩热解特性和动力学参数的影响[J].中原工学院学报,2007,18(1):1-5.
59.于海龙,姜秀民.桦甸油页岩热解特征的研究[J].燃料化学学报,2001,29(5):450-453.
60.雷怀玉,王红岩.柳树河油页岩的热解特征及动力学[J].吉林大学学报(地球科学版),2012,42(1)::25-29.
61. FANG Chaohe,YAO Jiangjun.ZHENG Dewen.Microwave processing of oil shale andcharacterization of shale oil generated by microwave retorting [C]//31stoil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
62.刘洪林,刘德勋,方朝合等.利用微波加热开采地下油页岩的技术[J].石油学报,2010,31(4):623-625
63.刘钧荣,秦积舜等.温度对岩石渗透率影响的实验研究[J].石油大学学报(自然科学版),2001,25(4):51-53.
64.梁冰,高红梅等.岩石渗透率与温度关系的理论分析和试验研究[J].岩石力学与工程学报,2005,24(12):2009-2012
65.李志强,鲜学福.煤体渗透率随温度和应力变化的实验研究[J].辽宁工程技术大学学报(自然科学版),2009,28(4):156-159
66.赵阳升,冯增朝,杨栋.对流加热油页岩开采油气的方法:中国,200510012473[P].2005.10.01
67.康志勤,吕兆兴,杨栋等.油页岩原位注蒸汽开发的固—流—热—化学耦合数学模型研究[J].西安石油大学学报(自然科学版),2008,23(4):29-34
68.康志勤,赵阳升,杨栋.利用原位电法加热技术开发油页岩的物理原理及数值分析[J].石油学报,2008,29(4):592-595
69.杨栋,赵静,康志勤,赵阳升.电法原位加热油页岩采油技术与数值分析[J].辽宁工程技术大学学报(自然科学版),2010,29(3):365-368
70.杨栋,薛晋霞,康志勤等.抚顺油页岩干馏渗透实验研究[J],西安石油大学学报(自然科学版),2007,22(2):23-25
71.刘中华,杨栋,薛晋霞等.干馏后油页岩渗透规律的实验研究[J],太原理工大学学报,2007,37(4):414-416
72.李术元,唐勋,王娟.油页岩地下干馏热压模拟实验研究[M]//王红岩,刘振文,宁宁.油页岩资源及开发工艺技术.北京:石油工业出版社,2010,80-85.
73. MA Yue,MA Guili,LI Shuyuan.Study of oil shale pyrolysis to simulate in-situ conversionprocess[C]//31stoil shale symposium,Colorado School of Mines,Golden,Colorado,October,2001.
74.韩向新,姜秀民.油页岩颗粒孔隙结构在燃烧过程中的变化[J].中国电机工程学报,2007,27(2):27-30
75.刘柏谦.油页岩及其流化床燃烧[M].长春:吉林科学技术出版社,1999.
76.孙佰仲,周明正,刘洪鹏,等.油页岩流化燃烧过程中表面特性的变化[J].动力工程,2008,28(2):250-254
77.孙佰仲,王擎,李少华,等.桦甸油页岩及半焦孔结构的特性分析[J].动力工程,2008,28(1):163-167
78.王廷芬,陆绍信,朱亚杰.我国油页岩热性质的研究,Ⅱ油页岩、半焦和页岩灰比热容的测定[J].燃料化学学报,1987,15(4):311-316
79.陆绍信、陈廷蕤,沈志虹,等.我国油页岩热性质研究——油页岩的热膨胀性能[J].石油学报(石油加工),1990,6(2):95-99
80.陆绍信,王廷芬.约旦油页岩热物理性质及热解性能的研究[R].华东石油学院北京研究生部,1987
81.余力.煤炭地下气化学术论文集[C].北京,2003
82.余力,梁杰,余学东.煤炭资源开发与利用新方法—煤炭地下气化技术[J].科技导报,1999(4)
83.余力.研究与开发煤炭地下气化技术[J].科技导报,1999(2)
84.余力.―长通道、大断面‖煤炭地下气化新工艺[J].中国煤炭,2002,28(12):7-10
85.江道罴.对煤炭地下气化的认识与实践[J].煤矿设计,2001(4):9-12
86.郎成忠.页岩油工业分析方法[Z].抚顺石油炼制研究所.抚顺,1980
87. ASTM D3904—90Standard test method for oil shale (Resource ecaluation by the Fischerassay procedure)[Z]
88.秦匡宗,郭绍辉.茂名和抚顺油页岩组成结构的研究,Ⅳ.矿物质的含量和组成[J].燃料化学学报,1987.15(1):1-8
89.李强.油页岩原位热裂解温度场数值模拟及实验研究[D].吉林,吉林大学.2012
90.康志勤.油页岩热解特性及原位注热开采油气的模拟研究[D].太原,太原理工大学,2008
91.刘丽丽.大粒度油页岩热解特性实验研究[D].北京,中国矿业大学,2011
92. Rajeshwar K.,Nottenburg R.,Dubow J..Review Thermophysical properties of oilshales[J].Journal of Materials Science,1979,14:2025-2052
93. Yang J T..Investigation on pyrolysis of Huangxian oil shale between550~750℃,In ZhuY.J.,ed.Proceedings of International Conference on Oil Shale and Shale Oil[J].Beijing,Chemical Industry Press,1988:263-270
94.耿丽文,郭树才.我国几种油页岩热重法热解动力学研究[R].大连工学院煤化工研究室,大连,1984
95.吴肇亮,徐伟民,杨国华,等.生油岩热解生烃反应动力学的几种数学模型的适用性讨论[C].全国油气资源量研讨会论文,扬州,1990
96.王道钰,王德进,钱家麟.油页岩和生油岩热解平行和连续反应模型的研究和数值计算[J].华东石油学院学报,1985(3):95-99
97. Nuttal H E,Guo T M.Pyrolysis kinetics of several world key oil shales[J].ACS Symposiumseries,230,269~300,1983
98.向银花,王洋,张建民,等.煤焦气化过程中比表面积和孔容积变化规律及影响因素研究[J].燃料化学学报,2002,30(2):108-112
99.陈鸿.煤焦燃尽动力学及孔隙结构的研究[D].武汉:华中理工大学,1993
100.刘辉,吴少华,姜秀民,等.快速热解褐煤焦的低温氮吸附等温线形态分析[J].煤炭学报,2005,30(4):508-512
101.张慧.煤孔隙的成因类型及其研究[J].煤炭学报,2001,26(1):39-43
102.秦跃平,傅贵.煤孔隙分形特征及其吸水性能的研究[J].煤炭学报,2000,25(1):55-59
103.宋微娜,董永利,周国江,等.油页岩结构组成及应用研究[J].黑龙江水专学报,2010,37(3):70-73
104. J. R. Dyni. Geology and Resources of Some World Oil shale Deposits[J]. OilShale.2003,20(3):193-252
105.严继民,张培元.吸附与凝聚[M].北京:科学出版社,1979
106.陈萍,唐修义.低温氮吸附法与煤中微孔隙特征的研究[J].煤炭学报,2001,26(5):552-556
107.殷艳玲.孔隙结构分形维数测试与应用研究进展[J].内蒙古石油化工,2008,(9):109-111
108. Angulo R F, A lvaradov and Gonzalez H. F ractal dimensions from mercury in trusioncapillary tests[R].SPE23695,1992
109. Thampaon A H. Katz A J, Krohn C E, the microgeometry and transportproperties ofsandtones[J]. Advances in physic,1987,36(5):625-631
110.李大勇,藏式宾,任晓娟,等.用分形理论研究低渗透储层孔隙结构[J].辽宁化工,2010,39(7):723-726
111.李留仁,赵艳艳,李忠兴,等.多孔介质微观孔隙结构分形特征及分形系数的意义[J].石油大学学报(自然科学版),2004,28(3):105-108
112.童宏树,胡宝林.鄂尔多斯盆地煤储层低温氮吸附孔隙分形特征研究[J].煤炭技术,2004,23(7):1-3
113. Katz A J,Thompson A H.Fractal sandstone pore:implication for conductivity and poreformation[J].Phys.Rev.Lett.,1986,33B(9):6366-6374
114.张玉涛,王德明,仲晓星.煤孔隙分形特征及其随温度的变化规律[J].煤炭科学技术,2007,35(11):46-49
115.张占存.煤的吸附特征及煤中孔隙的分布规律[J].煤矿安全,2006,9:1-4
116.刘均荣,秦积顺,吴晓东.温度对岩石渗透率影响的实验研究[J].石油大学学报,2001,25(4):51-53
117.张广洋,胡耀华,姜德义,等.煤的渗透性实验研究[J].贵州工业大学学报,1995,24(4):65-68.
118.李志强,鲜学福,隆晴明.不同温度应力条件下煤体渗透率实验研究[J].2009,38(4)
119.陈占清,缪协兴.影响岩石渗透率的因素分析[J].
120.高浩锋,张金功,罗文琴,等.砂岩、泥质岩和煤岩渗透率的研究[J].石油化工应用,2011,30(4):4-7
121.易俊,姜永东,鲜学福.应力场、温度场瓦斯渗流特性实验研究[J].中国矿业,2007,16(5):113-117
122.梁冰,高红梅,兰永伟.岩石渗透率与温度关系的理论分析和试验研究[J].岩石力学与工程学报,2005,24(12):2009-2012
123.陈祖安,伍向阳,方华.岩石气体介质渗透率的瞬态测量方法[J].地球物理学报,1999,42(增刊):167-171
124.隆清明,赵旭升,牟景珊.孔隙气压对煤层气体渗透性影响的试验研究[J].矿业安全与环保,2008,35(1):10-13
125.肖晓春,潘一山.滑脱效应影响的低渗煤层气运移实验研究[J].岩土工程学报,2009,31(10):1554-1557
126.陈代珣.渗透气体滑脱现象与渗透率变化的关系[J].力学学报,2002,34(1):96-100
127. A.M. Rubel, E. Davis, The effect of shale particle size on the products from the bench scalefixed bed pyrolysis of Kentucky Sunbury shale[C]. Eastern Oil Shale Symposium. KentuckyEnergy Cabinet, Lexington, Kentucky,1985:43:95-99
128. Nasir Ahmad1, Paul T. Williams. Influence of particle grain size on the yield andcomposition of products from the pyrolysis of oil shales[C]. Journal of Analytical andApplied Pyrolysis.1998,46:31-49
129. J.O. Jabera, S.D. Proberta, P.T. Williams. Evaluation of oil yield from Jordanian oil shales[J].Energy.1999,24:761-781
130. J. Hanna, W.E. Lamont, Effect of sulphur and particle size on Fischer assay oil yields from oilshale[C]. Eastern Oil Shale Symposium, Kentucky Energy Cabinet, Lexington, Kentucky,1987,35:343-348
131.张强林,王媛.岩体THM耦合应用研究现状综述[J].河海大学学报,2007,35(5):538-541
132. NeauPane K M, Yamabe T, Yoshinaka R. Simulation of a fully coupledthermo-hydro-mechanical system in freezing and thawing rock[J].Int J Rock Mech Min Sci,1999,36(2):563-580
133.周江,福井正则.岩体中渗流-热-应力耦合作用的理论研究[J].山西矿业学院学报,1995,13(1):76-81
134.赖远明,吴紫汪,朱元林,等.寒区隧道温度场、渗流场和应力场耦合问题的非线性分析[J].岩土工程学报,1999,21(5):529-533
135.刘亚晨,刘泉声,吴玉山,等.核废料贮库围岩介质不可逆过程热力学和热弹性[J].岩石力学与工程学报,2000,19(5):361-365
136.黄涛,杨立中,陈一立.工程岩体地下水渗流-应力-温度耦合作用数学模型的研究[J].西南交通大学学报,1999,34(1):11-15
137.贺玉龙,杨立中,杨吉义.非饱和岩体三场耦合控制方程[J].西南交通大学学报,2006,41(4):419-423
138.康志勤,吕兆兴,杨栋,等.油页岩原位注蒸汽开发的固—流—热化学耦合数学模型研究[J].西安石油大学学报(自然科学版),2008,23(4):35-38
139.刘善利,赵坚.饱和岩体热流固耦合数学模型研究[Z].中国科技论文在线
140.杨兰和,煤炭地下气化干馏气渗流运动多场耦合数值模拟[J].西安交通大学学报,2002,36(7):752-756
141.张强林,王媛.岩体THM耦合模型控制方程建立[J].西安石油大学学报,2007,22(2):139-145
142.王自明,油藏热流固耦合模型研究及应用初探[D].博士学位论文
143.顾泽同,葛永乐,翁中杰等.工程热应力[M].北京:国防工业出版社,1987
144.孔祥言,李道伦,徐献芝等.热-流-固耦合渗流的数学模型研究[J].水动力学研究与进展.2005,20(2):269-275
145.杨兰和.煤炭地下气化三维非线性动态温度场数值模拟[J].中国矿业大学学报,2000,29(2):140-143
146.杨兰和.煤炭地下气化三维非稳定对流扩散的数学模型[J].西安交通大学学报,2000,34(1):44-48
147.杨兰和.煤炭地下气化三维渗流数学模型的研究[J].中国矿业大学学报,2000,29(5):528-531
148.杨兰和.两阶段煤炭地下气化温度场模型[J].化工学报,2001,52(3):273-276
149. Yang Lanhe, Liang Jie, Yu Li.Double fire-two stage method and parameter calculation ofunderground coal gasification[J].Journal of China University of Mining&Technology,2000,10(2):116~119
150.吴世跃.煤层中的耦合运动理论及其应用—具有吸附作用的气固耦合运动理论[M].北京:,科学出版社,2009