{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"泡沫流体以其低密度、高粘度和独特的流变性在油田开采中被广泛应用，然而形成泡沫的必要组分是起泡剂，其最重要的性能就是起泡性能和稳泡性能。但在国内一些高温、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>中，地下泡沫的起泡性能和稳泡性能与室内实验相比均有所下降，未能达到预期的原油采收率。论述了高温、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span>条件下导致泡沫消泡的微观机理；介绍了目前高温、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>常用的单组分起泡剂、复合/复配型起泡剂的基本类型和苛刻的储层条件对不同类型起泡剂泡沫性能的制约性；同时综述了国内外高温、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>常用起泡剂的研究进展及油田应用现状；以分子结构、有效官能团、复配微观规律和绿色环保为主要研究方向，展望了我国高温、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>起泡剂研究发展趋势。","authors":[{"authorName":"赵修太","id":"6055e032-6828-4830-8044-5c26fa903aa9","originalAuthorName":"赵修太"},{"authorName":"王泉","id":"84577d53-c562-4a9f-bdc7-7815aa6298a6","originalAuthorName":"王泉"},{"authorName":"王增宝","id":"32afc9a2-7bfa-4d86-8955-efc5994c8036","originalAuthorName":"王增宝"},{"authorName":"任增磊","id":"f1e254e7-7012-48a7-8711-8ddb0f923b89","originalAuthorName":"任增磊"},{"authorName":"翟东启","id":"98c1f6e8-903c-4c5d-8260-c7f58e8396a4","originalAuthorName":"翟东启"},{"authorName":"马梅花","id":"b920d4ed-2f20-473f-8f9e-3c84ce3e5b5d","originalAuthorName":"马梅花"}],"doi":"10.11896/j.issn.1005-023X.2016.05.014","fpage":"75","id":"75a2a1e0-bf5b-4b27-af54-b022e94183d0","issue":"5","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"d4991fb5-bf11-4254-aca6-ff1ac7d0ce65","keyword":"高温<span style=\"color:red\">油藏</span>","originalKeyword":"高温油藏"},{"id":"8cbccca5-07b5-4dc7-9227-59e83d0d9ece","keyword":"<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>","originalKeyword":"高盐油藏"},{"id":"976f699b-9ee3-43ce-ade8-03bcfeeaeccf","keyword":"油田用剂","originalKeyword":"油田用剂"},{"id":"261105d1-8f13-4589-8ea6-1fde8a93438d","keyword":"起泡剂","originalKeyword":"起泡剂"}],"language":"zh","publisherId":"cldb201605014","title":"高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>常用起泡剂研究进展?","volume":"30","year":"2016"},{"abstractinfo":"针对高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>中存在的水窜问题，开展高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>用调驱剂的攻关研究是大幅度提高高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>采收率的基础。该文综述了高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>深部调驱体系的研究进展，包括：新型聚合物、弱冻胶、沉淀类、体膨颗粒、冻胶分散体、含油污泥、柔性体以及无机凝胶涂层8种深部调驱体系。分析了每种调驱剂的优缺点、调驱机理和现场应用情况。展望了高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>深部调驱体系的发展方向。","authors":[{"authorName":"孙同成","id":"7092d756-97e5-488b-8a81-906c1ed09718","originalAuthorName":"孙同成"},{"authorName":"崔亚","id":"6720393e-c187-4d8f-a7f3-b0fea884b884","originalAuthorName":"崔亚"}],"doi":"","fpage":"99","id":"0fa4e5ac-6964-429e-8cb5-61ea79a0e7e6","issue":"2","journal":{"abbrevTitle":"HCCLLHYYY","coverImgSrc":"journal/img/cover/HCCLLHYYY.jpg","id":"42","issnPpub":"1671-5381","publisherId":"HCCLLHYYY","title":"合成材料老化与应用"},"keywords":[{"id":"ae994a01-0149-4a89-a80b-51004ad90079","keyword":"高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span>","originalKeyword":"高温高盐"},{"id":"2f2392f6-666b-47c4-9681-cf0b164e8220","keyword":"深部调驱","originalKeyword":"深部调驱"},{"id":"4049f4a0-4b49-4051-b58b-32bc8c22eef6","keyword":"研究进展","originalKeyword":"研究进展"},{"id":"c8800a48-2e36-44d2-a60d-20f74d83dfa6","keyword":"发展趋势","originalKeyword":"发展趋势"}],"language":"zh","publisherId":"hccllhyyy201602023","title":"高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>深部调驱体系研究进展","volume":"45","year":"2016"},{"abstractinfo":"在中低渗透高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>聚合物驱技术中,超高相对分子质量聚丙烯酰胺(HPAM)存在不易注入、剪切降粘显著和耐温抗<span style=\"color:red\">盐</span>性能差等问题.本文以丙烯酰胺(AM)和2-丙烯酰胺基-2-甲基丙磺酸(AMPS)为单体,采用过硫酸胺(NH4)2S2O8和甲基丙烯酸N,N-二甲氨基乙酯(DMAEMA)作为支化结构复合引发体系,通过共聚后水解工艺,合成含支化结构耐温抗<span style=\"color:red\">盐</span>驱油共聚物P(AM/AMPSNa/AANa).研究了引发温度、链转移剂用量、引发剂用量对共聚物特性黏数的影响,并通过红外光谱(IR)和13C NMR表征了产物结构.筛选特性黏数1915 mL/g左右的共聚物,进行性能评价.实验结果表明,共聚物具有优异的耐温抗<span style=\"color:red\">盐</span>性能、抗剪切性能、抗老化性、注入性和驱油性能,可应用在中低渗透高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>三次采油中.","authors":[{"authorName":"伊卓","id":"8b187db0-9101-4eb5-9c9e-53476010646f","originalAuthorName":"伊卓"},{"authorName":"杨付林","id":"5ef0b305-12ce-41bd-8039-647135d56310","originalAuthorName":"杨付林"},{"authorName":"刘希","id":"d2d55bf1-5a5c-43a4-a321-f382bf346dab","originalAuthorName":"刘希"},{"authorName":"赵方园","id":"75af5ce3-b7ad-43b7-85e9-a59937d37cfb","originalAuthorName":"赵方园"},{"authorName":"方昭","id":"b4c07ea3-803e-46cb-a97b-8e6403e29b69","originalAuthorName":"方昭"},{"authorName":"杜超","id":"746ae809-0d0a-460f-9c38-3d79dd6583e9","originalAuthorName":"杜超"},{"authorName":"胡晓娜","id":"b34fa957-15a1-4e30-bf4c-c40b1cd7ecb1","originalAuthorName":"胡晓娜"}],"doi":"10.11944/j.issn.1000-0518.2015.05.140451","fpage":"519","id":"b5b656a3-1e9c-4556-8cb8-eed8bf1637e2","issue":"5","journal":{"abbrevTitle":"YYHX","coverImgSrc":"journal/img/cover/YYHX.jpg","id":"73","issnPpub":"1000-0518","publisherId":"YYHX","title":"应用化学"},"keywords":[{"id":"1692a63b-33a4-4776-9e96-428f5f7f9fed","keyword":"中低渗透","originalKeyword":"中低渗透"},{"id":"20a15307-6e33-4a34-86b5-dc86010cd9df","keyword":"驱油聚合物","originalKeyword":"驱油聚合物"},{"id":"9744f7fa-5a6f-4b7c-b134-011b843f8a4b","keyword":"支化结构","originalKeyword":"支化结构"},{"id":"6067c12b-4eb0-43e5-ab92-e384168b12a5","keyword":"耐温抗<span style=\"color:red\">盐</span>","originalKeyword":"耐温抗盐"},{"id":"efc43dcf-2e2f-4325-b49b-29c1ff0090f7","keyword":"抗剪切","originalKeyword":"抗剪切"},{"id":"e773baf1-9ac1-4f61-a790-5e3fdc19795e","keyword":"聚丙烯酰胺","originalKeyword":"聚丙烯酰胺"}],"language":"zh","publisherId":"yyhx201505005","title":"中低渗透高温<span style=\"color:red\">高</span><span style=\"color:red\">盐</span><span style=\"color:red\">油藏</span>驱油共聚物P(AM/AMPSNa/AANa)的合成及性能","volume":"32","year":"2015"},{"abstractinfo":"介绍了电渗析法除<span style=\"color:red\">盐</span>与水矿化技术共同应用于<span style=\"color:red\">高</span>氟、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span>、低硬度饮用水的处理工艺.处理后的水质符合GB5749-85<生活饮用水卫生标准>,锌、锶、锂等微量元素含量达GB8537-87<饮用天然矿泉水指标>.","authors":[{"authorName":"丁慧","id":"883313e7-9437-4dbb-9a79-9fdbed9e8889","originalAuthorName":"丁慧"}],"doi":"10.3969/j.issn.1007-8924.1998.02.012","fpage":"46","id":"1c9595a3-4f48-401d-b30b-7a3ba973dd39","issue":"2","journal":{"abbrevTitle":"MKXYJS","coverImgSrc":"journal/img/cover/MKXYJS.jpg","id":"54","issnPpub":"1007-8924","publisherId":"MKXYJS","title":"膜科学与技术   "},"keywords":[{"id":"04e3ca31-8edf-45c0-b1f5-140b2bb12007","keyword":"电渗析","originalKeyword":"电渗析"},{"id":"6023a14c-0153-42bf-a7cb-139f91eb048e","keyword":"饮用水处理","originalKeyword":"饮用水处理"},{"id":"df4c7c05-041a-49f1-b030-6fd7760dd4e9","keyword":"矿化","originalKeyword":"矿化"}],"language":"zh","publisherId":"mkxyjs199802012","title":"<span style=\"color:red\">高</span>氟、<span style=\"color:red\">高</span><span style=\"color:red\">盐</span>、低硬度饮用水的处理","volume":"18","year":"1998"},{"abstractinfo":"通过铸体薄片、扫描电镜和压汞分析，以及依据<span style=\"color:red\">油藏</span>所处的构造形态、储层成因类型、<span style=\"color:red\">油藏</span>成藏要素等对<span style=\"color:red\">油藏</span>进行解剖分析，探讨鄂尔多斯盆地吴起地区长2油层组侵蚀残余地层<span style=\"color:red\">油藏</span>的控制因素。吴起地区长2油层组储层砂体孔隙类型主要为剩余原生粒间孔和次生溶孔，孔隙结构分选中等；发育上倾尖灭型、透镜体型、小幅背斜构造型和复合成因型4种<span style=\"color:red\">油藏</span>类型。鄂尔多斯盆地延长组侵蚀残余地层<span style=\"color:red\">油藏</span>成藏受古地貌、岩性和构造等多重因素的控制，<span style=\"color:red\">油藏</span>主要分布于古河道两侧的斜坡带上。地层完整的长2油层组内，小幅背斜构造与分流河道砂体叠置，形成规模较大的构造-岩性复合成因<span style=\"color:red\">油藏</span>，是吴起地区长2油层组主要的<span style=\"color:red\">油藏</span>类型。","authors":[{"authorName":"杜凌春","id":"098982e4-d0d4-4981-b1a2-c2e2b07b8f11","originalAuthorName":"杜凌春"},{"authorName":"李凤杰","id":"a25a714e-87cd-42ae-ac97-bac1edf349ea","originalAuthorName":"李凤杰"},{"authorName":"屈雪林","id":"5b35a559-ab3e-4787-a597-6fd9125efee3","originalAuthorName":"屈雪林"},{"authorName":"张雁","id":"0b7a1d5d-6f2a-4d30-b432-0f6a8adc3efe","originalAuthorName":"张雁"},{"authorName":"侯景涛","id":"3033f92f-cb9f-4cda-836d-27e6bd0abd3c","originalAuthorName":"侯景涛"},{"authorName":"苏幽雅","id":"def9e91a-ad77-4e65-9f13-a97726733a1a","originalAuthorName":"苏幽雅"}],"doi":"10.3969/j.issn.1671-9727.2015.06.10","fpage":"719","id":"5b5324b9-5709-4800-98ed-8d55492dd831","issue":"10","journal":{"abbrevTitle":"ZGCLJZ","coverImgSrc":"journal/img/cover/中国材料进展.jpg","id":"80","issnPpub":"1674-3962","publisherId":"ZGCLJZ","title":"中国材料进展"},"keywords":[{"id":"57ec7acc-537b-420a-87c2-2a5d775a9423","keyword":"残余地层","originalKeyword":"残余地层"},{"id":"1bd9e871-276a-4d6d-a932-06542b747b4d","keyword":"<span style=\"color:red\">油藏</span>控制因素","originalKeyword":"油藏控制因素"},{"id":"d72b615c-2628-4469-ba33-1afb784b1218","keyword":"长 2 油层组","originalKeyword":"长 2 油层组"},{"id":"6f01502d-64f5-42bd-bd56-3012d5625812","keyword":"吴起地区","originalKeyword":"吴起地区"},{"id":"7c69f38a-dbfb-4068-a5f6-95265746681a","keyword":"鄂尔多斯盆地","originalKeyword":"鄂尔多斯盆地"}],"language":"zh","publisherId":"zgcljz201510010","title":"吴起地区长2油层组侵蚀残余地层<span style=\"color:red\">油藏</span>控制因素","volume":"","year":"2015"},{"abstractinfo":"建立了蒸汽驱热水驱替部分湿饱和流动热流耦合的物理模型,在其基础上得到包括温度方程、压力方程、饱和度方程、渗流速度方程等在内的数学模型,采用全隐式中心差分方法,得到温度场、压力场等的迭代公式,对某应用示例的数值模拟说明了其过程的热流耦合机制,并指出应对<span style=\"color:red\">油藏</span>实施有效的加热降黏措施,可同时提高原油采收率和采油速率.","authors":[{"authorName":"成庆林","id":"56c4d8c6-9bc6-461f-98d0-a7929598bbcc","originalAuthorName":"成庆林"},{"authorName":"刘扬","id":"ecdfa579-f58c-423a-b323-2c98eced6a75","originalAuthorName":"刘扬"},{"authorName":"王志国","id":"9e5f715d-d591-4859-a699-e6626d090f43","originalAuthorName":"王志国"},{"authorName":"项新耀","id":"8eb61d2d-aa8d-4b1c-91da-9eaab523da76","originalAuthorName":"项新耀"}],"doi":"","fpage":"1451","id":"0d48380a-a8d2-44d4-9856-f4feacc31b23","issue":"9","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报   "},"keywords":[{"id":"be4333cd-71d9-4ef0-a728-d91ac187f1e7","keyword":"<span style=\"color:red\">油藏</span>渗流","originalKeyword":"油藏渗流"},{"id":"5d2af22b-7155-49b8-8ec7-63d0c1df5ccd","keyword":"湿饱和","originalKeyword":"湿饱和"},{"id":"03b08666-8751-45c1-8d6a-dc88c47f6216","keyword":"多孔介质","originalKeyword":"多孔介质"},{"id":"6d62716d-672b-41de-b92e-05928bd5176b","keyword":"热流耦合","originalKeyword":"热流耦合"}],"language":"zh","publisherId":"gcrwlxb200909004","title":"<span style=\"color:red\">油藏</span>多孔介质湿饱和流动的热流耦合分析","volume":"30","year":"2009"},{"abstractinfo":"以磷肥生产过程中的副产物氟硅酸为原料制备<span style=\"color:red\">高</span>纯二氧化硅.氟硅酸与氨水反应,得到氟硅酸铵溶液,加入铵盐沉淀钙镁离子,再加入钙<span style=\"color:red\">盐</span>沉淀铝铁离子,静置后过滤得到净化的氟硅酸铵溶液;将净化液氟硅酸铵与氨水反应生成二氧化硅沉淀,经过滤、热洗、干燥、煅烧,得到<span style=\"color:red\">高</span>纯二氧化硅.样品SiO2符合国标要求.实验表明,以氟硅酸制备<span style=\"color:red\">高</span>纯二氧化硅工艺可行.工艺特点是将低附加值的氟硅酸转化为高附加值的<span style=\"color:red\">高</span>纯SiO2,铵盐钙<span style=\"color:red\">盐</span>除杂适宜,反应步骤少、过程简单、操作条件温和.","authors":[{"authorName":"刘晓红","id":"5a800765-627e-4437-96cb-7069f211098d","originalAuthorName":"刘晓红"},{"authorName":"张琪","id":"0a49c75a-cfd1-47a3-8fb2-a5163713769c","originalAuthorName":"张琪"}],"doi":"","fpage":"651","id":"48985ec3-1069-4331-a433-7fd436976468","issue":"2","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"9e36f60c-e8fb-4dea-ad28-fae3988b532f","keyword":"氟硅酸","originalKeyword":"氟硅酸"},{"id":"3070b1d6-f211-43ea-8be3-a5fe1e0e57ae","keyword":"氨水","originalKeyword":"氨水"},{"id":"e49be10b-a54a-4a02-b01f-97926880d214","keyword":"铵盐","originalKeyword":"铵盐"},{"id":"514bdd3a-abd1-4cf6-9279-bb9d666110ea","keyword":"钙<span style=\"color:red\">盐</span>","originalKeyword":"钙盐"},{"id":"05b3d7fb-23de-4905-9705-da2903e0502e","keyword":"<span style=\"color:red\">高</span>纯SiO2","originalKeyword":"高纯SiO2"}],"language":"zh","publisherId":"gsytb201602057","title":"铵盐钙<span style=\"color:red\">盐</span>除杂制备<span style=\"color:red\">高</span>纯二氧化硅","volume":"35","year":"2016"},{"abstractinfo":"提出了一种新颖的快速制备<span style=\"color:red\">高</span>比表面氧化铈纳米粉体的方法--<span style=\"color:red\">盐</span>助溶液燃烧法,通过XRD、TEM和比表面积分析,研究了燃料/氧化剂的比率、不同<span style=\"color:red\">盐</span>的种类和用量对产物性质的影响.研究发现,在传统的溶液燃烧法中简单的引入KCl导致产物比表面积由14.10 m2·g-1剧增到156.74 m2·g-1,得到了4～6 nm高分散性的纳米氧化铈粒子.通过示意图初步讨论了<span style=\"color:red\">盐</span>助溶液燃烧合成过程高分散纳米氧化铈粒子形成的可能机制,认为由于自蔓延溶液燃烧反应快速释放出大量的热量,使反应体系产生瞬间高温,<span style=\"color:red\">盐</span>会迅速在新形成的纳米晶的表面原位析出形成薄盐层,当快速冷却后,氧化铈纳米晶就被镶嵌在凝固的<span style=\"color:red\">盐</span>基质中,阻止了新生成纳米粒子的重新团聚和烧结,从而得到氧化铈单分散粒子.","authors":[{"authorName":"陈伟凡","id":"5854a8bc-3b31-4969-a800-8dcaf1b27183","originalAuthorName":"陈伟凡"},{"authorName":"李凤生","id":"d63f60d1-ad18-4af2-82e0-cea2fb631ee1","originalAuthorName":"李凤生"},{"authorName":"于吉义","id":"41a16a77-d38c-4fd7-81fc-d9def1617985","originalAuthorName":"于吉义"},{"authorName":"李永绣","id":"ae8b3b80-012a-4639-94b4-141ec998d5ce","originalAuthorName":"李永绣"}],"doi":"","fpage":"408","id":"94d856b1-c7c5-4190-bd49-da882b1cb746","issue":"4","journal":{"abbrevTitle":"ZGXTXB","coverImgSrc":"journal/img/cover/ZGXTXB.jpg","id":"86","issnPpub":"1000-4343","publisherId":"ZGXTXB","title":"中国稀土学报"},"keywords":[{"id":"e79491e4-ccf7-40ce-8f8f-ef8aebb2edbf","keyword":"<span style=\"color:red\">盐</span>助","originalKeyword":"盐助"},{"id":"7f542eb6-50a4-4d24-807c-968a204f0793","keyword":"溶液燃烧法","originalKeyword":"溶液燃烧法"},{"id":"285ddf27-280e-4bb3-a82e-c07787b7f2bc","keyword":"纳米氧化铈","originalKeyword":"纳米氧化铈"},{"id":"d6294058-05c5-42a9-974b-64406d9409c6","keyword":"乙二醇","originalKeyword":"乙二醇"},{"id":"227bf2ab-e2fc-4524-a04d-fb91c1a5cd70","keyword":"<span style=\"color:red\">高</span>比表面积","originalKeyword":"高比表面积"},{"id":"d76905fe-6ff0-4c74-bb90-3fa47ec2881c","keyword":"稀土","originalKeyword":"稀土"}],"language":"zh","publisherId":"zgxtxb200604006","title":"<span style=\"color:red\">盐</span>助溶液燃烧法制备<span style=\"color:red\">高</span>比表面氧化铈纳米粉体","volume":"24","year":"2006"},{"abstractinfo":"在稠油开采过程中,随着热流体的注入和油气的采出,<span style=\"color:red\">油藏</span>多孔介质内部的渗流场、温度场和应力场等重新分布,同时<span style=\"color:red\">油藏</span>多孔介质的物性参数发生变化,稠油热采是一个典型的热流固多场耦合作用过程.由于<span style=\"color:red\">油藏</span>多孔介质内部结构变化多样,精确描述和分析困难,目前多场耦合相关机理模型研究针对特定条件,具有一定的局限性.本文针对<span style=\"color:red\">油藏</span>多孔介质,提出了热流耦合计算的“三箱”分析模型,即不涉及REV(表征单元体,representative volumetric element, 简称REV)内部构成的“黑箱”分析法、对REV内部进行适当简化的“灰箱”分析法,以及对REV内部进行详细分析的“白箱”分析法.利用所建模型,基于<span style=\"color:red\">油藏</span>多孔介质的一些典型数据,进行了耦合计算和分析,得到了一些有意义的结果.","authors":[{"authorName":"王志国","id":"5bdcfcb6-ad3c-4329-b013-f2e30128d673","originalAuthorName":"王志国"},{"authorName":"李大","id":"4770ffc4-01d7-4ea2-bff4-8c614d939f5b","originalAuthorName":"李大"},{"authorName":"杨文哲","id":"863e14f0-37a7-4de9-ba59-9b2498eb03fd","originalAuthorName":"杨文哲"},{"authorName":"张雷","id":"ab21d0ce-dc50-429b-a78d-cbad331e9e3d","originalAuthorName":"张雷"},{"authorName":"宋永臣","id":"465b2ce4-799a-409f-8746-745774df18a4","originalAuthorName":"宋永臣"}],"doi":"","fpage":"2000","id":"cd7aeaaa-690a-4d23-8823-65f995b368a4","issue":"9","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报   "},"keywords":[{"id":"c9f45359-97c5-4dea-949f-dd8428878231","keyword":"热流耦合","originalKeyword":"热流耦合"},{"id":"c2776cee-8e4c-49e2-98e7-e5564c112e8d","keyword":"表征单元体","originalKeyword":"表征单元体"},{"id":"c9575f31-3976-4054-8b25-8fe4ba382d6a","keyword":"“三箱”分析法","originalKeyword":"“三箱”分析法"},{"id":"197488c6-8c1f-482c-b39f-3bfea9a06a24","keyword":"<span style=\"color:red\">油藏</span>多孔介质","originalKeyword":"油藏多孔介质"},{"id":"03dda399-9790-4108-a1e5-939a95993757","keyword":"计算模型","originalKeyword":"计算模型"}],"language":"zh","publisherId":"gcrwlxb201509032","title":"基于“三箱”方法的<span style=\"color:red\">油藏</span>多孔介质热流耦合计算模型","volume":"36","year":"2015"},{"abstractinfo":"采用电化学还原法,温度为900℃,在CaCl2熔<span style=\"color:red\">盐</span>中以烧结的TiO2与钛铁矿混合物(Ti:Fe=1:1原子比)为阴极,石墨棒为阳极,制备出了<span style=\"color:red\">高</span>钛铁合金.探讨了混合物烧结后的相组成变化及<span style=\"color:red\">高</span>钛铁合金的合金化历程.实验结果表明,混合物烧结后,TiO2由锐钛矿结构转变为金红石结构,钛铁矿转化为热力学稳定的Fe2TiO5.钛铁矿的晶体结构由烧结前的三方晶系经950℃以上烧结后,转变为斜方晶系的Fe2TiO5.制备出的<span style=\"color:red\">高</span>钛铁中铁钛含量分别为:77.19％和9.68％(质量分数).其合金化历程为:TiO2先生成CaTiO3,然后继续脱氧还原为金属钛；钛铁矿优先还原出金属铁,然后与生成的金属钛发生合金化反应生成钛铁合金.表明熔<span style=\"color:red\">盐</span>电解nO2与钛铁矿的混合物是一条制备<span style=\"color:red\">高</span>钛铁合金的新途径.优化电解条件提高电流效率可进一步提高电解速度,得到质量更高的<span style=\"color:red\">高</span>钛铁合金.","authors":[{"authorName":"李晴宇","id":"030bd6a6-3e6e-4c2e-9d19-ca7b1677ed3c","originalAuthorName":"李晴宇"},{"authorName":"杜继红","id":"03e47c19-9b77-4cb1-bbd0-7fa2c796ebc4","originalAuthorName":"杜继红"},{"authorName":"奚正平","id":"58f289e3-b944-4e95-acdf-f862a566ebde","originalAuthorName":"奚正平"},{"authorName":"李争显","id":"11fababd-8531-4411-98d7-5b3b7b7e57d4","originalAuthorName":"李争显"},{"authorName":"杨承本","id":"f61dbec3-a9a6-499f-98dc-7cc238c6af74","originalAuthorName":"杨承本"}],"doi":"10.3969/j.issn.0258-7076.2011.06.007","fpage":"829","id":"c401c988-9a76-4a55-b0bc-2adac6acc9f6","issue":"6","journal":{"abbrevTitle":"XYJS","coverImgSrc":"journal/img/cover/XYJS.jpg","id":"67","issnPpub":"0258-7076","publisherId":"XYJS","title":"稀有金属"},"keywords":[{"id":"230dfa14-0f5e-4305-a5ea-c0334d4c9edb","keyword":"钛铁矿","originalKeyword":"钛铁矿"},{"id":"e148fd6b-98e2-4879-b377-3b4b1db2f793","keyword":"TiO2","originalKeyword":"TiO2"},{"id":"704f0945-96e5-48a9-9779-b1c297f1e301","keyword":"熔<span style=\"color:red\">盐</span>电解","originalKeyword":"熔盐电解"},{"id":"1dee98cd-6a51-41aa-878e-d47a9cf88467","keyword":"<span style=\"color:red\">高</span>钛铁合金","originalKeyword":"高钛铁合金"}],"language":"zh","publisherId":"xyjs201106007","title":"熔<span style=\"color:red\">盐</span>电解法制备<span style=\"color:red\">高</span>钛铁合金","volume":"35","year":"2011"}],"totalpage":2677,"totalrecord":26762}