[1] HUNT J A,CHEN Rui,VAN VEEN T,et al.Hydrogels for tissue engineering and regenerative medicine[J].Journal of Materials Chemistry B,2014,2(33):5319-5338.
[2] KOUTSOPOULOS S.Self-assembling peptide nanofiber hydrogels in tissue engineering and regenerative medicine:progress,design guidelines,and applications[J].Journal of Biomedical Materials Research Part A,2016,104(4):1002-1016.
[3] GHAREKHANI H,OLAD A,MIRMOHSENI A,et al.Superabsorbent hydrogel made of NaAlg-g-poly(AA-co-AAm)and rice husk ash:synthesis,characterization,and swelling kinetic studies[J].Carbohydrate Polymers,2017,168:1-13.
[4] ZONATTO F,MUNIZ E C,TAMBOURGI E B,et al.Adsorption and controlled release of potassium,phosphate and ammonia from modified Arabic gum-based hydrogel[J].International Journal of Biological Macromolecules,2017,105:363-369.
[5] ZHANG Y S,KHADEMHOSSEINI A.Advances in engineering hydrogels[J].Science,2017,356(6337):eaaf3627.
[6] WU Siwu,QIU Min,TANG Zhenghai,et al.Carbon nanodots as high-functionality cross-linkers for bioinspired engineering of multiple sacrificial units toward strong yet tough elastomers[J].Macromolecules,2017,50(8):3244-3253.
[7] LI Qiwen,LIU Chenlu,WEN Junru,et al.The design,mechanism and biomedical application of self-healing hydrogels[J].Chinese Chemical Letters,2017,28(9):1857-1874.
[8] 李进,赵梓年,李征征,等.自愈合水凝胶的合成机理及生物医学应用[J].材料导报,2019,33(10):3328-3335.
LI Jin,ZHAO Zinian,LI Zhengzheng,et al.Synthetic mechanism and biomedical application of self-healing hydrogel[J].Materials Reports,2019,33(10):3328-3335.
[9] 王建莉,石海洋,邢艳君,等.双亲微球聚合物随钻堵漏剂的抗温性能评价及非等温热分解动力学研究[J].精细石油化工进展,2013,14(3):15-17.
WANG Jianli,SHI Haiyang,XING Yanjun,et al.Evaluation of heat-resistance and study on non-isothermal decomposition kinetics of amphiphilic polymer plugging agent AMP[J].Advances in Fine Petrochemicals,2013,14(3):15-17.
[10] 田建东,于培志,牟福权.托普台区块高渗透地层随钻堵漏剂配方优化[J].探矿工程(岩土钻掘工程),2015,42(7):10-13.
TIAN Jiandong,YU Peizhi,MOU Fuquan.Optimization of agent formula of plugging while drilling for high permeability formation in Tuoputai block[J].Exploration Engineering (Rock & Soil Drilling and Tunneling),2015,42(7):10-13.
[11] 张文哲,孙金声,白英睿,等.抗高温纤维强化凝胶颗粒堵漏剂[J].钻井液与完井液,2020,37(3):269-274.
ZHANG Wenzhe,SUN Jinsheng,Bai Yingrui,et al.A high temperature resistant gel reinforced with fiber used for lost circulation[J].Drilling Fluid & Completion Fluid,2020,37(3):269-274.
[12] 王骁男,张栋俊,吕忠楷,等.智能凝胶塞在晋中3井的应用[J].钻采工艺,2018,41(5):110-112.
WANG Xiaonan,ZHANG Dongjun,LV Zhongkai,et al.Application of intelligent gel plug in Well Jinzhong-3[J].Drilling & Production Technology,2018,41(5):110-112.
[13] 郭新健,于培志.抗高温化学凝胶堵漏技术在顺北52X井的应用[J].钻井液与完井液,2019,36(2):189-193.
GUO Xinjian,YU Peizhi.Controlling mud losses in Well Shunbei 52X with high temperature chemical gels[J].Drilling Fluid & Completion Fluid,2019,36(2):189-193.
[14] 王先洲,夏景刚,左洪国,等.新型FM超级凝胶复合堵漏技术[J].钻井液与完井液,2016,32(6):50-53.
WANG Xianzhou,XIA Jinggang,ZUO Hongguo,et al.A novel compound lost circulation material FM super gel[J].Drilling Fluid & Completion Fluid,2016,32(6):50-53.
[15] 方俊伟,吕忠楷,何仲,等.化学凝胶堵剂承压堵漏技术在顺北3井的应用[J].钻井液与完井液,2017,34(6):13-17.
FANG Junwei,LV Zhongkai,HE Zhong,et al.Application of chemical gel LCM on well Shunbei-3[J].Drilling Fluid & Completion Fluid,2017,34(6):13-17.
[16] 贺垠博,蒋官澄,王勇,等.异电荷聚电解质自组装水凝胶在无固相煤层气钻井液中的特性[J].石油学报,2018,39(6):719-726.
HE Yinbo,JIANG Guancheng,WANG Yong,et al.Properties of self-assembled hydrogel of oppositely-charged polyelectrolytes in solid-free coalbed methane drilling fluid[J].Acta Petrolei Sinica,2018,39(6):719-726.
[17] TUNCABOYLU D C,SARI M,OPPERMANN W,et al.Tough and self-healing hydrogels formed via hydrophobic interactions[J].Macromolecules,2011,44(12):4997-5005.
[18] TUNCABOYLU D C,ARGUN A,SAHIN M,et al.Structure optimization of self-healing hydrogels formed via hydrophobic interactions[J]. Polymer,2012,53(24):5513-5522.
[19] AKAY G,HASSAN-RAEISI A,TUNCABOYLU D C,et al.Self-healing hydrogels formed in catanionic surfactant solutions[J].Soft Matter,2013,9(7):2254-2261.
[20] ALGI M P,OKAY O.Highly stretchable self-healing poly (N,N-dimethylacrylamide)hydrogels[J].European Polymer Journal,2014,59:113-121.
[21] GULYUZ U,OKAY O.Self-healing polyacrylic acid hydrogels[J].Soft Matter,2013,9(43):10287-10293.
[22] GULYUZ U,OKAY O.Self-healing poly (acrylic acid)hydrogels:effect of surfactant[J].Macromolecular Symposia,2015,358(1):232-238.
[23] TUNCABOYLU D C,ARGUN A,ALGI M P,et al.Autonomic self-healing in covalently crosslinked hydrogels containing hydrophobic domains[J].Polymer,2013,54(23):6381-6388.
[24] LI Siliang,GAO Yang,JIANG Haicheng,et al.Tough,sticky and remoldable hydrophobic association hydrogel regulated by polysaccharide and sodium dodecyl sulfate as emulsifiers[J].Carbohydrate Polymers,2018,201:591-598.
[25] XU Jiajun,REN Xiuyan,GAO Guanghui.Salt-inactive hydrophobic association hydrogels with fatigue resistant and self-healing properties[J].Polymer,2018,150:194-203.
[26] CHEN Jing,AN Ran,HAN Linglin,et al.Tough hydrophobic association hydrogels with self-healing and reforming capabilities achieved by polymeric core-shell nanoparticles[J].Materials Science and Engineering:C,2019,99:460-467.
[27] 王素敏,吴骊珠,张丽萍,等.以2-脲基-4[1H]-嘧啶酮为基础的超分子组装[J].科学通报,2005,50(23):2565-2574.
WANG Sumin,WU Lizhu,ZHANG Liping,et al.Supramolecular assembly based on 2-ureido-4[1H]-pyrimidinone building block[J].Chinese Science Bulletin,2006,51(2):129-138.
[28] HARAGUCHI K,UYAMA K,TANIMOTO H.Self-healing in nanocomposite hydrogels[J].Macromolecular Rapid Communications,2011,32(16):1253-1258.
[29] WANG Tao,ZHENG Shudian,SUN Weixiang,et al.Notch insensitive and self-healing PNIPAm-PAM-clay nanocomposite hydrogels[J].Soft Matter,2014,10(19):3506-3512.
[30] GAO Guorong,DU Gaolai,SUN Yuanna,et al.Self-healable,tough,and ultrastretchable nanocomposite hydrogels based on reversible polyacrylamide/montmorillonite adsorption[J].ACS Applied Materials & Interfaces,2015,7(8):5029-5037.
[31] SU Qiang,DUAN Lijie,ZOU Meifang,et al.The tough allograft adhesive behavior between polyacrylamide and poly(acrylic acid)hydrophobic association hydrogels[J].Materials Chemistry and Physics,2017,193:57-62.
[32] SIJBESMA R P,MEIJER E W.Quadruple hydrogen bonded systems[J].Chemical Communications,2003(1):5-16.
[33] FELDER T,DE GREEF T F A,NIEUWENHUIZEN M M L,et al.Alternation and tunable composition in hydrogen bonded supramolecular copolymers[J].Chemical Communications,2014,50(19):2455-2457.
[34] CUI Jiaxi,DEL CAMPO A.Multivalent H-bonds for self-healing hydrogels[J].Chemical Communications,2012,48(74):9302-9304.
[35] JEON I,CUI Jiaxi,ILLEPERUMA W R,et al.Extremely stretchable and fast self-healing hydrogels[J].Advanced Materials,2016,28(23):4678-4683.
[36] SUN Tiaolin,KUROKAWA T,KURODA S,et al.Physical hydrogels composed of polyampholytes demonstrate high toughness and viscoelasticity[J].Nature Materials,2013,12(10):932-937.
[37] LUO Feng,SUN Taolin,NAKAJIMA T,et al.Oppositely charged polyelectrolytes form tough,self-healing,and rebuildable hydrogels[J].Advanced Materials,2015,27(17):2722-2727.
[38] LUO Feng,SUN Taolin,NAKAJIMA T,et al.Crack blunting and advancing behaviors of tough and self-healing polyampholyte hydrogel[J].Macromolecules,2014,47(17):6037-6046.
[39] LONG Tangjie,LI Yixuan,FANG Xu,et al.Salt-mediated polyampholyte hydrogels with high mechanical strength,excellent self-healing property,and satisfactory electrical conductivity[J].Advanced Functional Materials,2018,28(44):1804416.
[40] WEI Zengjiang,HE Jie,LIANG T,et al.Autonomous self-healing of poly (acrylic acid)hydrogels induced by the migration of ferric ions[J].Polymer Chemistry,2013,4(17):4601-4605.
[41] ANJUM S,GURAVE P,BADIGER M V,et al.Design and development of trivalent aluminum ions induced self-healing polyacrylic acid novel hydrogels[J].Polymer,2017,126:196-205.
[42] ANJUM S,GURAVE P M,GUPTA B.Calcium ion-induced self-healing pattern of chemically crosslinked poly (acrylic acid)hydrogels[J].Polymer International,2018,67(3):250-257.
[43] BAI Tao,LIU Sijun,SUN Fang,et al.Zwitterionic fusion in hydrogels and spontaneous and time-independent self-healing under physiological conditions[J].Biomaterials,2014,35(13):3926-3933.
[44] MEYER C D,JOINER C S,STODDART J F.Template-directed synthesis employing reversible imine bond formation[J].Chemical Society Reviews,2007,36(11):1705-1723.
[45] BERGER J,REIST M,MAYER J M,et al.Structure and interactions in chitosan hydrogels formed by complexation or aggregation for biomedical applications[J].European Journal of Pharmaceutics and Biopharmaceutics,2004,57(1):35-52.
[46] 耿慧敏,崔基炜,郝京诚.仿贻贝水凝胶在组织愈合中的应用研究[J].化学学报,2020,78(2):105-113.
GENG Huimin,CUI Jiwei,HAO Jingcheng.Mussel-inspired hydrogels for tissue healing[J].Acta Chimica Sinica,2020,78(2):105-113.
[47] JING Xin,MI Haoyang,NAPIWOCKI B N,et al.Mussel-inspired electroactive chitosan/graphene oxide composite hydrogel with rapid self-healing and recovery behavior for tissue engineering[J].Carbon,2017,125:557-570.
[48] CHEN Tao,CHEN Yujie,REHMAN H U,et al.Ultratough,self-healing,and tissue-adhesive hydrogel for wound dressing[J].ACS Applied Materials & Interfaces,2018,10(39):33523-33531.
[49] APOSTOLIDES D E,PATRICKIOS C S.Dynamic covalent polymer hydrogels and organogels crosslinked through acylhydrazone bonds:synthesis,characterization and applications[J].Polymer International,2018,67(6):627-649.
[50] DENG Guohua,LI Fuya,YU Hongxia,et al.Dynamic hydrogels with an environmental adaptive self-healing ability and dual responsive sol-gel transitions[J].ACS Macro Letters,2012,1(2):275-279.
[51] WANG Peng,DENG Guohua,ZHOU Lanying,et al.Ultrastretchable,self-healable hydrogels based on dynamic covalent bonding and triblock copolymer micellization[J].ACS Macro Letters,2017,6(8):881-886.
[52] STRACHOTA B,MORAND A,DYBAL J,et al.Control of gelation and properties of reversible Diels-Alder networks:design of a self-healing network[J].Polymers,2019,11(6):930.
[53] SHAO Changyou,WANG Meng,CHANG Huanliang,et al.A self-healing cellulose nanocrystal-poly(ethylene glycol)nanocomposite hydrogel via Diels-Alder click reaction[J].ACS Sustainable Chemistry & Engineering,2017,5(7):6167-6174.
[54] 邱正松,刘均一,周宝义,等.钻井液致密承压封堵裂缝机理与优化设计[J].石油学报,2016,37(S2):137-143.
QIU Zhengsong,LIU Junyi,ZHOU Baoyi,et al.Tight fracture-plugging mechanism and optimized design for plugging drilling fluid[J].Acta Petrolei Sinica,2016,37(S2):137-143.
[55] 邱正松,暴丹,刘均一,等.裂缝封堵失稳微观机理及致密承压封堵实验[J].石油学报,2018,39(5):587-596.
QIU Zhengsong,BAO Dan,LIU Junyi,et al.Microcosmic mechanism of fracture-plugging instability and experimental study on pressure bearing and tight plugging[J].Acta Petrolei Sinica,2018,39(5):587-596.
[56] 暴丹,邱正松,邱维清,等.高温地层钻井堵漏材料特性实验[J].石油学报,2019,40(7):846-857.
BAO Dan,QIU Zhengsong,QIU Weiqing,et al.Experiment on properties of lost circulation materials in high temperature formation[J].Acta Petrolei Sinica,2019,40(7):846-857.
[57] 康毅力,王凯成,许成元,等.深井超深井钻井堵漏材料高温老化性能评价[J].石油学报,2019,40(2):215-223.
KANG Yili,WANG Kaicheng,XU Chengyuan,et al.High-temperature aging property evaluation of lost circulation materials in deep and ultra-deep well drilling[J].Acta Petrolei Sinica,2019,40(2):215-223.
[58] 胡祖彪,李德波,陈秉炜,等.智能凝胶GD-1在陕北黄土层防漏堵漏中的应用[J].钻井液与完井液,2010,27(1):85-86.
HU Zubiao,LI Debo,CHEN Bingwei,et al.The application of an intelligent gel GD-1 in lost circulation control in the yellow claystone formations in Shanbei[J].Drilling Fluid & Completion Fluid,2010,27(1):85-86.
[59] 王广财,王丰年,张军,等.凝胶复合防漏堵漏技术在火焰山腹地表层的应用[J].钻井液与完井液,2017,34(3):49-53.
WANG Guangcai,WANG Fengnian,ZHANG Jun,et al.Application of a composite gel lost circulation material in the top section of wells drilled in the central region of the mountain of fire[J].Drilling Fluid & Completion Fluid,2017,34(3):49-53.
[60] 暴丹,邱正松,叶链,等.热致形状记忆"智能"型堵漏剂的制备与特性实验[J].石油学报,2020,41(1):106-115.
BAO Dan,QIU Zhengsong,YE Lian,et al.Preparation and characteristic experiments of intelligent lost circulation materials based on thermally shape memory polymer[J].Acta Petrolei Sinica,2020,41(1):106-115.
[61] 王小勇,杨立华,何治武,等.智能凝胶尾追微膨胀水泥套损井化学堵漏技术[J].钻井液与完井液,2013,30(6):17-20.
WANG Xiaoyong,YANG Lihua,HE Zhiwu,et al.Intelligent gel and micro-dilatancy cement plugging technology on casing destroyed well[J].Drilling Fluid & Completion Fluid,2013,30(6):17-20.
[62] 张绍营,刘智勤.南海西部深水井智能凝胶堵漏技术与实践[J].中国高新科技,2018(12):62-66.
ZHANG Shaoying,LIU Zhiqin.Plugging technology and practice of smart gel in deep water wells in the western South China Sea[J].China High-Tech,2018(12):62-66.
[63] 颜帮川,蒋官澄,胡文军,等.高温延迟交联聚丙烯酰胺凝胶堵漏剂的研究[J].钻井液与完井液,2019,36(6):679-682.
YAN Bangchuan,JIANG Guancheng,HU Wenjun,et al.Study on high temperature delayed crosslinking PAM gel LCM[J].Drilling Fluid & Completion Fluid,2019,36(6):679-682.
[64] 徐同台.井壁稳定技术研究现状及发展方向[J].钻井液与完井液,1997,14(4):36-43.
XU Tongtai.Current status and development trend of well wall stabilization technology[J].Drilling Fluid & Completion Fluid,1997,14(4):36-43.
[65] ANDERSON R L,RATCLIFFE I,GREENWELL H C,et al.Clay swelling-a challenge in the oilfield[J].Earth-Science Reviews,2010,98(3/4):201-216.
[66] 邱正松,徐加放,吕开河,等."多元协同"稳定井壁新理论[J].石油学报,2007,28(2):117-119.
QIU Zhengsong,XU Jiafang,LV Kaihe,et al.A multivariate cooperation principle for well-bore stabilization[J].Acta Petrolei Sinica,2007,28(2):117-119.
[67] 孔勇,金军斌,林永学,等.封堵防塌钻井液处理剂研究进展[J].油田化学,2017,34(3):556-560.
KONG Yong,JIN Junbin,LIN Yongxue,et al.Research advances of plugging anti-sloughing drilling fluid additives[J].Oilfield Chemistry,2017,34(3):556-560.
[68] 宣扬,蒋官澄,李颖颖,等.基于仿生技术的强固壁型钻井液体系[J].石油勘探与开发,2013,40(4):497-501.
XUAN Yang,JIANG Guancheng,LI Yingying,et al.A biomimetic drilling fluid for wellbore strengthening[J].Petroleum Exploration and Development,2013,40(4):497-501.
[69] 蒋官澄,宣扬,王金树,等.仿生固壁钻井液体系的研究与现场应用[J].钻井液与完井液,2014,31(3):1-5.
JIANG Guancheng,XUAN Yang,WANG Jinshu,et al.Study and application of bionic borehole wall strengthening agent[J].Drilling Fluid & Completion Fluid,2014,31(3):1-5.
[70] 程琳,胡景东,申法忠,等.家3-21X井仿生固壁钻井液技术[J].钻井液与完井液,2015,32(6):26-29.
CHENG Lin,HU Jingdong,SHEN Fazhong,et al.Bionic drilling fluid technology for borehole strengthening used in well Jia-3-21X[J].Drilling Fluid & Completion Fluid,2015,32(6):26-29.
[71] MAIER G P,RAPP M V,WAITE J H,et al.Adaptive synergy between catechol and lysine promotes wet adhesion by surface salt displacement[J].Science,2015,349(6248):628-632.
[72] RYU J H,HONG S,LEE H.Bio-inspired adhesive catechol-conjugated chitosan for biomedical applications:a mini review[J].Acta Biomaterialia,2015,27:101-115.
[73] 汤志川,邱正松,钟汉毅,等.新型壳聚糖-邻苯二酚化学固壁剂合成与性能评价[J].钻井液与完井液,2019,36(5):534-541.
TANG Zhichuan,QIU Zhengsong,ZHONG Hanyi,et al.Synthesis and evaluation of a new chemical borehole wall strengthener made from chitosan-catechol[J].Drilling Fluid & Completion Fluid,2019,36(5):534-541.
[74] 何剑,杨小华,王琳,等.抗高温抗钙水溶性聚合物降滤失剂研究进展[J].中外能源,2016,21(7):32-37.
HE Jian,YANG Xiaohua,WANG Lin,et al.Research progress of water-soluble polymeric filtrate reducer with high-temperature resistance and Calcium tolerance[J].Sino-Global Energy,2016,21(7):32-37.
[75] SEPEHRI S,SOLEYMAN R,VARAMESH A,et al.Effect of synthetic water-soluble polymers on the properties of the heavy water-based drilling fluid at high pressure-high temperature (HPHT)conditions[J].Journal of Petroleum Science and Engineering,2018,166:850-856.
[76] 毛惠,邱正松,沈忠厚,等.疏水缔合聚合物/纳米二氧化硅降滤失剂的研制及作用机理[J].石油学报,2014,35(4):771-778.
MAO Hui,QIU Zhengsong,SHEN Zhonghou,et al.Synthesis and mechanism of hydrophobic associated polymer based nano-silica filtrate reducer[J].Acta Petrolei Sinica,2014,35(4):771-778.
[77] LIU Fan,JIANG Guancheng,PENG Shuanglei,et al.Amphoteric polymer as an anti-calcium contamination fluid-loss additive in water-based drilling fluids[J].Energy & Fuels,2016,30(9):7221-7228.
[78] 蒋官澄,贺垠博,崔物格,等.基于盐响应型两性离子聚合物的饱和盐水钻井液[J].石油勘探与开发,2019,46(2):385-390.
JIANG Guancheng,HE Yinbo,CUI Wuge,et al.A saturated saltwater drilling fluid based on salt-responsive polyampholytes[J].Petroleum Exploration and Development,2019,46(2):385-390.
[79] 贺垠博,蒋官澄,董腾飞,等.盐响应聚合物刺激响应机理及在饱和盐水钻井液中的应用[J].石油勘探与开发,2020,47(5):1052-1058.
HE Yinbo,JIANG Guancheng,DONG Tengfei,et al.Stimulus-responsive mechanism of salt-responsive polymer and its application in saturated saltwater drilling fluid[J].Petroleum Exploration and Development,2020,47(5):1052-1058.
[80] 杨丽丽,杨潇,蒋官澄,等.含离子液体链段抗高温高钙降滤失剂[J].钻井液与完井液,2018,35(6):8-14.
YANG Lili,YANG Xiao,JIANG Guancheng,et al.A high temperature Calcium resistant filter loss reducer containing ionic liquid segments[J].Drilling Fluid & Completion Fluid,2018,35(6):8-14.
[81] 徐昆,谭颖,张文德,等.抗温耐盐型水溶性高分子在钻完井领域应用的研究进展[J].石油化工,2014,43(11):1233-1239.
XU Kun,TAN Ying,ZHANG Wende,et al.Progresses in application of temperature-resistant and salt-tolerant water-soluble polymers to drilling and completion[J].Petrochemical Technology,2014,43(11):1233-1239. |