{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用液态金属冷却(LMC)高温度梯度定向凝固炉制备&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;和&<span style=\"color:red\">lt</span>;011&<span style=\"color:red\">gt</span>;取向的DD407单晶高温合金, 研究了晶体取向对枝晶间距和微观偏析的影响. 结果表明, 晶体取向对单晶高温合金的枝晶间距和微观偏析有明显的影响. 枝晶间距随着&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;取向偏差角的增加而增加,但随&<span style=\"color:red\">lt</span>;011&<span style=\"color:red\">gt</span>;取向偏差角的增加而减小,且&<span style=\"color:red\">lt</span>;011&<span style=\"color:red\">gt</span>;取向的枝晶间距因为侧枝的分枝而明显大于&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;取向. 成分分析表明, 在不同取向的单晶中, Al,Ti和Ta富集于枝晶间, 是正偏析元素, 而W严重富集于枝晶干, 为负偏析元素,当&<span style=\"color:red\">lt</span>;011&<span style=\"color:red\">gt</span>;取向平行轴向时元素的偏析程度最轻.","authors":[{"authorName":"杨初斌刘林赵新宝刘刚张军傅恒志","id":"1d5849b8-7eba-4048-bf59-d5c4174f4666","originalAuthorName":"杨初斌刘林赵新宝刘刚张军傅恒志"}],"categoryName":"|","doi":"10.3724/SP.J.1037.2011.00142","fpage":"1246","id":"df442a9a-b4e6-44fe-bb94-b7ee6619cec4","issue":"10","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"3d8160a9-21cc-4c42-bc9c-b51e73daa15d","keyword":"晶体取向","originalKeyword":"晶体取向"},{"id":"60536ff5-63a1-413c-a01a-2f1610646313","keyword":" Ni&ndash;based single crystal superalloy","originalKeyword":" Ni&ndash;based single crystal superalloy"},{"id":"fbc25ccc-b41e-4570-9290-dffc84a472c3","keyword":" dendrite arm spacing","originalKeyword":" dendrite arm spacing"},{"id":"5956801f-f8c6-4415-814c-27bdb389bcd7","keyword":" microsegregation","originalKeyword":" microsegregation"},{"id":"4310c873-f877-4a4c-ae97-187887e83dd6","keyword":" directional solidification","originalKeyword":" directional solidification"}],"language":"zh","publisherId":"0412-1961_2011_10_17","title":"&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;和&<span style=\"color:red\">lt</span>;011&<span style=\"color:red\">gt</span>;取向DD407单晶高温合金枝晶间距和微观偏析","volume":"47","year":"2011"},{"abstractinfo":"采用悬浮区熔法, 加入籽晶控制生长取向, 以<span style=\"color:red\">4</span> mm/h的生长速度, 制备了轴向&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;择优取向的 Fe<<span style=\"color:red\">sub</span>>81</<span style=\"color:red\">sub</span>>Ga<<span style=\"color:red\">sub</span>>19</<span style=\"color:red\">sub</span>>单晶. 极图测试结果发现, 采用偏离轴向&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;方向约5<sup>o</sup>的籽晶生长得到的单晶, 生长始端和生长末端轴向取向分别偏离&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;取向5<sup>o</sup>和<span style=\"color:red\">4</span><sup>o</sup>, 上下取向差仅为1<sup>o</sup>. 另一单晶采用轴向&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;取向籽晶生长得到, 当施加60 MPa压力时, 饱和磁致伸缩性能达到0.0324%. 测试了&<span style=\"color:red\">lt</span>;100&<span style=\"color:red\">gt</span>;, &<span style=\"color:red\">lt</span>;110&<span style=\"color:red\">gt</span>;和&<span style=\"color:red\">lt</span>;111&<span style=\"color:red\">gt</span>; 取向单晶的初始磁化曲线, 利用初始磁化曲线, 计算得出Fe<<span style=\"color:red\">sub</span>>81</<span style=\"color:red\">sub</span>>Ga<<span style=\"color:red\">sub</span>>19</<span style=\"color:red\">sub</span>>单晶的磁晶各向异性常数值<em>K</em><<span style=\"color:red\">sub</span>>1</<span style=\"color:red\">sub</span>>和<em>K</em><<span style=\"color:red\">sub</span>>2</<span style=\"color:red\">sub</span>>, 分别为1.3&times;10<sup><span style=\"color:red\">4</span></sup>和-2.6&times;10<sup><span style=\"color:red\">4</span></sup> J/m<sup><span style=\"color:red\">3</span></sup>.","authors":[{"authorName":"陈立彪朱小溪李川刘敬华蒋成保徐惠彬","id":"0dbfc088-4288-4d2f-9e50-1ca815440897","originalAuthorName":"陈立彪朱小溪李川刘敬华蒋成保徐惠彬"}],"categoryName":"|","doi":"10.3724/SP.J.1037.2010.00343","fpage":"169","id":"bdbf567f-7d79-40a2-a056-6406b23c4e4e","issue":"2","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"a219fd15-44f4-4a20-b43d-0d38acee9d88","keyword":"Fe<<span style=\"color:red\">sub</span>>81</<span style=\"color:red\">sub</span>>Ga<<span style=\"color:red\">sub</span>>19</<span style=\"color:red\">sub</span>>单晶","originalKeyword":"Fe<sub>81</sub>Ga<sub>19</sub>单晶"},{"id":"9eff2326-3a88-453f-b698-37582863d951","keyword":"&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>; orientation","originalKeyword":"&lt;001&gt; orientation"},{"id":"4c74e8c0-e777-4ccb-bcbf-58f38b2947f2","keyword":"magnetostriction","originalKeyword":"magnetostriction"},{"id":"9784a40b-2ae4-4655-b5a1-c1f6db4b861d","keyword":"magnetocrystalline anisotropy","originalKeyword":"magnetocrystalline anisotropy"}],"language":"zh","publisherId":"0412-1961_2011_2_3","title":"Fe<<span style=\"color:red\">sub</span>>81</<span style=\"color:red\">sub</span>>Ga<<span style=\"color:red\">sub</span>>19</<span style=\"color:red\">sub</span>>合金&<span style=\"color:red\">lt</span>;001&<span style=\"color:red\">gt</span>;取向单晶生长及磁致伸缩性能","volume":"47","year":"2011"},{"abstractinfo":"采用区熔定向凝固方法, 以480 mm/h速度制备了&<span style=\"color:red\">lt</span>;110&<span style=\"color:red\">gt</span>;取向Tb<<span style=\"color:red\">sub</span>>0.36</<span style=\"color:red\">sub</span>>Dy<<span style=\"color:red\">sub</span>>0.64</<span style=\"color:red\">sub</span>>(Fe<<span style=\"color:red\">sub</span>>0.85</<span style=\"color:red\">sub</span>>Co<<span style=\"color:red\">sub</span>>0.15</<span style=\"color:red\">sub</span>>)<<span style=\"color:red\">sub</span>>2</<span style=\"color:red\">sub</span>>合金棒. 通过测试在0---0.325 T磁场范围内合金 棒的应力--应变回线, 计算了应力幅<em>&sigma;</em><<span style=\"color:red\">sub</span>>m</<span style=\"color:red\">sub</span>>分别为-10,-30和-50 MPa的阻尼系数&Delta; <em>W</em>/<em>W</em>. 结果表明, 零磁场下的&Delta; <em>W</em>/<em>W</em>最大; 随磁场强度增大, 同一<em>&sigma;</em><<span style=\"color:red\">sub</span>>m</<span style=\"color:red\">sub</span>>条件下的&Delta; <em>W</em>/<em>W</em>逐渐降低. 在低磁场中, &Delta; <em>W</em>/<em>W</em>随<em>&sigma;</em><<span style=\"color:red\">sub</span>>m</<span style=\"color:red\">sub</span>>的增加而降低; 在高磁场中,&nbsp; &Delta; <em>W</em>/<em>W</em>随<em>&sigma;</em><<span style=\"color:red\">sub</span>>m</<span style=\"color:red\">sub</span>>的增加而升高. 利用不同预压应力下的磁致伸缩--磁化强度关系曲线, 分析了磁场--应力复合加载条件下非180&deg;磁畴和畴壁的运动形式. 依据局部内应力理论, 解释了合金棒的磁机械阻尼系数随外磁场强度和应力幅值变化的规律.","authors":[{"authorName":"张昌盛马天宇严密裴永茂高旭","id":"4a115f63-c272-45f5-a1f6-05d38bf716c3","originalAuthorName":"张昌盛马天宇严密裴永茂高旭"}],"categoryName":"|","doi":"","fpage":"749","id":"59265ecc-83f2-482d-9760-0a2e4fd2b1f6","issue":"6","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"9a67cfb1-1591-4b9b-80b9-fee10303b6bc","keyword":"Tb--Dy--Fe合金","originalKeyword":"Tb--Dy--Fe合金"},{"id":"610ef150-9793-456c-bcbc-1699eddfcb4b","keyword":" magnetostriction","originalKeyword":" magnetostriction"},{"id":"0a414b2b-4a21-4a2b-945f-15bfd3838af1","keyword":" magnetomechanical damping","originalKeyword":" magnetomechanical damping"},{"id":"59146232-1e0e-4954-b928-98a326cf6e68","keyword":" magnetization","originalKeyword":" magnetization"}],"language":"zh","publisherId":"0412-1961_2009_6_17","title":"&<span style=\"color:red\">lt</span>;110&<span style=\"color:red\">gt</span>;取向Tb<<span style=\"color:red\">sub</span>>0.36</<span style=\"color:red\">sub</span>>Dy<<span style=\"color:red\">sub</span>>0.64</<span style=\"color:red\">sub</span>>(Fe<<span style=\"color:red\">sub</span>>0.85</<span style=\"color:red\">sub</span>>Co<<span style=\"color:red\">sub</span>>0.15</<span style=\"color:red\">sub</span>>)<<span style=\"color:red\">sub</span>>2</<span style=\"color:red\">sub</span>>合金的磁机械阻尼特性","volume":"45","year":"2009"},{"abstractinfo":"Various viscosity-composition curves of polymer blends are summarized in eight groups. To represent these curves. \"<span style=\"color:red\">sub</span>-cluster equations\" are derived on the basis of so called \"<span style=\"color:red\">sub</span>-cluster theoryThe essential concepts of <span style=\"color:red\">sub</span>-cluster theory and the derivation of those \"<span style=\"color:red\">Sub</span>-cluster equations\" are briefly introduced.","authors":[{"authorName":"Riguang JIN  and Hangquan LI (Beijing Institute of Chemical Technology","id":"1f711862-4f6d-4fed-bd9c-484683f32f41","originalAuthorName":"Riguang JIN  and Hangquan LI (Beijing Institute of Chemical Technology"},{"authorName":" Beijing","id":"57e508eb-42f9-4c88-9bbc-734fee9136bf","originalAuthorName":" Beijing"},{"authorName":" 100029","id":"ce00f8cd-5679-4175-80d8-21e16a326ea5","originalAuthorName":" 100029"},{"authorName":" China)(To whom correspondence should be addressed)","id":"eb91d13b-98ac-4bf1-bd1b-bed9371eff85","originalAuthorName":" China)(To whom correspondence should be addressed)"}],"categoryName":"|","doi":"","fpage":"111","id":"bc45688e-4f99-4d0d-8941-0ec786711380","issue":"2","journal":{"abbrevTitle":"CLKXJSY","coverImgSrc":"journal/img/cover/JMST.jpg","id":"11","issnPpub":"1005-0302 ","publisherId":"CLKXJSY","title":"材料科学技术（英文）"},"keywords":[],"language":"en","publisherId":"1005-0302_1994_2_3","title":"Study of Polymer Blends with <span style=\"color:red\">Sub</span>-cluster Theory Part I Essential Concepts and Equations of <span style=\"color:red\">Sub</span>-cluster Theory","volume":"10","year":"1994"},{"abstractinfo":"对<span style=\"color:red\">LT-3</span>铝合金真空钎焊工艺进行了研究,利用显微硬度仪、扫描电镜和X射线衍射仪对未焊接母材和钎缝中生成的相和组织进行了分析,并对钎焊接头的断口形貌进行了分析.结果表明:钎缝的显微硬度平均值要比芯层显微硬度的平均值高24.5 MHV;钎缝中生成了网状的共晶组织和多种新的金属间化合物;钎缝断裂过程属于混合断裂,断口界面上可以看到多种断裂形貌.","authors":[{"authorName":"冯涛","id":"4a44567f-8e04-4e46-9ec6-a0994889648f","originalAuthorName":"冯涛"},{"authorName":"楼松年","id":"d8c1728f-6d37-4b32-9f26-9bc9b39e4b7f","originalAuthorName":"楼松年"},{"authorName":"李亚江","id":"0935ad23-7ff3-44d0-a2b0-877dcc3013eb","originalAuthorName":"李亚江"}],"doi":"10.3969/j.issn.1000-3738.2005.06.014","fpage":"44","id":"0189c3be-5919-45b4-b0a4-4b9c66081496","issue":"6","journal":{"abbrevTitle":"JXGCCL","coverImgSrc":"journal/img/cover/JXGCCL.jpg","id":"45","issnPpub":"1000-3738","publisherId":"JXGCCL","title":"机械工程材料"},"keywords":[{"id":"c22b5ced-67d5-4a63-af7c-92a372b488bf","keyword":"<span style=\"color:red\">LT-3</span>铝合金","originalKeyword":"LT-3铝合金"},{"id":"3e5865e6-9f14-45b0-9f58-c7138733a91b","keyword":"真空钎焊","originalKeyword":"真空钎焊"},{"id":"0f810ae9-a111-47f0-a381-7e594aa8d6b9","keyword":"显微组织","originalKeyword":"显微组织"}],"language":"zh","publisherId":"jxgccl200506014","title":"<span style=\"color:red\">LT-3</span>铝合金真空钎焊钎缝微观组织分析","volume":"29","year":"2005"},{"abstractinfo":"To confirm <span style=\"color:red\">sub</span>-regular solution model valid for predicting the activity of component in binary oxide systems, seven systems in the whole concentration and twelve systems presenting saturation concentration have been studied. The total average relative errors of component 1 and 2 are 3.2% and 4.1% respectively by application of the <span style=\"color:red\">sub</span>-regular solution model into the systems within the whole concentration. However, the total average relative errors are 16% and 1088% in the systems presenting saturation concentration. The results show that <span style=\"color:red\">sub</span>-regular solution model is not good for predicting the systems presenting saturation concentration, especially for the systems containing acidic or neutral oxide. The reason may be that the influence of the two types of oxide on the configuration is greater in binary oxide systems. These oxides can be present in the form of complex anion partly, <span style=\"color:red\">Si</span>-O, Al-O, Ti-O and so on, for example (SiO<span style=\"color:red\">4</span>)<span style=\"color:red\">4</span>-. That is contrary to <span style=\"color:red\">sub</span>-regular solution model which is supposed that the oxide systems consist of cation and O2-. But compared with regular solution model and quasi-regular solution model, <span style=\"color:red\">sub</span>-regular solution model is closer to the characteristics of actual solution and the calculated results are superior.","authors":[{"authorName":"HOU Yan-qing","id":"fe7e4dd0-492f-467d-bc17-b5c53db1df23","originalAuthorName":"HOU Yan-qing"},{"authorName":"XIE Gang","id":"d0ce1e47-d78b-41c8-939f-75fc5efd03a6","originalAuthorName":"XIE Gang"},{"authorName":"TAO Dong-ping","id":"9a2f04cb-d90c-47e7-b12b-586585916fc9","originalAuthorName":"TAO Dong-ping"},{"authorName":"LI Rong-xing","id":"e00b59ca-929f-4bdd-9e48-8a4f632eb019","originalAuthorName":"LI Rong-xing"},{"authorName":"YU Xiao-hua","id":"64d1cd91-63ae-49b5-9c39-f4311a68859e","originalAuthorName":"YU Xiao-hua"}],"categoryName":"|","doi":"","fpage":"33","id":"17c021d1-7d93-4039-bd44-b979e952f527","issue":"7","journal":{"abbrevTitle":"GTYJXBYWB","coverImgSrc":"journal/img/cover/GTYJXBEN.jpg","id":"1","issnPpub":"1006-706X","publisherId":"GTYJXBYWB","title":"钢铁研究学报(英文版)"},"keywords":[{"id":"b95fdf24-450a-4fd0-b76c-22a94b142990","keyword":"<span style=\"color:red\">sub</span>-regular solution model ","originalKeyword":"sub-regular solution model "},{"id":"8e03e76d-2ddf-4455-b5e8-6fc08c149bb1","keyword":"  binary oxide system ","originalKeyword":"  binary oxide system "},{"id":"e9d0af1c-ac08-4ad1-8a56-83becbf4dde0","keyword":"  activity","originalKeyword":"  activity"}],"language":"en","publisherId":"1006-706X_2012_7_10","title":"Activity Calculation by Application of <span style=\"color:red\">Sub</span>-Regular Solution Model in Binary Oxide Systems","volume":"19","year":"2012"},{"abstractinfo":"With TEM( Transmission Electron Microscope) ,ithasobserved and analyzedthatforming  processof <span style=\"color:red\">Sub</span>  grainsand position offormingfatigue microcracksarein Welded metalsofthe16 Mnsteelundertensile  tensilestress. Theresultsindicatedthattheforming processof <span style=\"color:red\">Sub</span>    grainsfrom dislocationtanglecellstotheSub  grains. Thepositionofformingfatigue micro  crackisattheoxidativeinterfaceand granular noncrgstallines and <span style=\"color:red\">Sub</span>  boundaries. Thece    mentiteineutectoidsafterfracture may beproduced microcracks.","authors":[{"authorName":"S.Z.Dong ","id":"622d3d1c-2800-4271-9c71-90fac22b69d1","originalAuthorName":"S.Z.Dong "},{"authorName":"J.B.Li","id":"b5dee218-6658-4ea8-ade6-24388175dfc9","originalAuthorName":"J.B.Li"},{"authorName":" X.H.Zhang and J.Zhang  Shenyang University ","id":"9569d418-5ee4-41c8-80ee-d552f23129d1","originalAuthorName":" X.H.Zhang and J.Zhang  Shenyang University "},{"authorName":"Shenyang 110044 ","id":"60e12103-e920-4c53-8405-2eb8fee4263d","originalAuthorName":"Shenyang 110044 "},{"authorName":"China","id":"6a910f72-9b60-49e5-aa83-dc169a902823","originalAuthorName":"China"}],"categoryName":"|","doi":"","fpage":"713","id":"75f98a09-1049-44ef-81ec-186199ad9b3b","issue":"4","journal":{"abbrevTitle":"JSXBYWB","coverImgSrc":"journal/img/cover/amse.jpg","id":"49","issnPpub":"1006-7191","publisherId":"JSXBYWB","title":"金属学报(英文版)"},"keywords":[{"id":"5fc340fd-198a-45fb-b8bc-53221abe35d4","keyword":"fatigueload","originalKeyword":"fatigueload"},{"id":"d425153a-722d-4176-8874-84b0e5be46fb","keyword":"null","originalKeyword":"null"},{"id":"2ce25bca-5a06-4bd5-b747-22c103e040b3","keyword":"null","originalKeyword":"null"},{"id":"f11abf52-9ac6-47c3-820a-d4aa2bae37ed","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_1999_4_44","title":"STUDY IN FO RMATION OF <span style=\"color:red\">SUB</span>  GRAINS AND MICROCRACKS IN  WEIDED METAIS UNDER FATIGUE LOAD","volume":"12","year":"1999"},{"abstractinfo":"采用物理共混法,制备PvA/sA/<span style=\"color:red\">GT</span>的三元复合凝胶微球,用于盐酸四环素的包载和药物的释放研究.选择5:5:2、5:5:<span style=\"color:red\">3</span>和5:5:<span style=\"color:red\">4</span>三种比例制备的微球,研究在模拟胃液和肠液的条件(空白微球对照)下,<span style=\"color:red\">GT</span>量和pH变化对释药性能和降解性能的影响.结果表明:5:5:<span style=\"color:red\">4</span>比例相变的微球的释药性能和降解性能都最好;模拟胃液较模拟肠液能加快微球的降解,进而加速微球的释药速率;是否栽药对微球的降解性能无影响,但是微球的降解会加速微球的释药速率.","authors":[{"authorName":"赵玉强","id":"b811d706-962d-4b27-b61e-d05cd142a03b","originalAuthorName":"赵玉强"},{"authorName":"张琨","id":"eaecb2d8-0d2d-4202-9803-5ae5aec26856","originalAuthorName":"张琨"},{"authorName":"张志斌","id":"9392f239-3212-415e-b98f-22a81bafa1ec","originalAuthorName":"张志斌"}],"doi":"","fpage":"379","id":"3dee2220-7ca6-41de-84cf-ae8793f5ba2c","issue":"Z2","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"ed53e25b-fae2-40cf-99f2-cb4a0a2c17b9","keyword":"聚乙烯醇","originalKeyword":"聚乙烯醇"},{"id":"69e1eb79-d940-464e-819a-7e0f9a512fc6","keyword":"海藻酸钠","originalKeyword":"海藻酸钠"},{"id":"dd7587b1-68b8-4a71-ab4b-ee21f917d311","keyword":"明胶","originalKeyword":"明胶"},{"id":"3d4a0b02-4e4c-463a-9e13-967bc902e13c","keyword":"盐酸四环素","originalKeyword":"盐酸四环素"},{"id":"7e2a9e7f-5895-47a5-9f81-2099d12a3978","keyword":"缓释","originalKeyword":"缓释"}],"language":"zh","publisherId":"cldb2008Z2109","title":"PVA/SA/<span style=\"color:red\">GT</span>三元复合酸敏凝胶微球的性能研究","volume":"22","year":"2008"},{"abstractinfo":"本文研究SOFC/<span style=\"color:red\">GT</span>/ST三重复合动力系统.首先基于Aspen Plus建立了SOFC/<span style=\"color:red\">GT</span>/ST的性能分析模型,分析了各主要参数对SOFC/<span style=\"color:red\">GT</span>/ST复合动力系统性能的影响规律.研究结果表明:复合动力系统尽量在高的压力,温度在900℃左右的条件下,有较高系统效率;较高的燃料利用率(Ut)有利于提高系统效率.本文研究成果为开拓研究高效SOFC/<span style=\"color:red\">GT</span>/ST复合动力系统提供了有益的参考.","authors":[{"authorName":"王宇","id":"84f987ba-2be8-46ca-91ef-1e659cf7606e","originalAuthorName":"王宇"},{"authorName":"段立强","id":"98472f73-7945-457c-83c8-9b33d8f43158","originalAuthorName":"段立强"},{"authorName":"杨勇平","id":"afc0a6fb-f351-4388-9d4d-6e902b919c39","originalAuthorName":"杨勇平"}],"doi":"","fpage":"382","id":"406c39f6-6c5d-4866-9daa-7a78a7eb8693","issue":"3","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":"217cc581-0bde-4d95-b411-924d7079e78a","keyword":"SOFC","originalKeyword":"SOFC"},{"id":"de8dfd5c-6ca7-4dee-9e78-85c29db454dd","keyword":"<span style=\"color:red\">GT</span>","originalKeyword":"GT"},{"id":"f15c4f9b-1050-48db-82d1-8f990b6368f3","keyword":"ST","originalKeyword":"ST"},{"id":"77559b38-6064-467c-b069-1011cb571ee9","keyword":"复合动力系统","originalKeyword":"复合动力系统"},{"id":"5abc5a03-31b5-4624-8ff9-24407843e7f3","keyword":"性能优化","originalKeyword":"性能优化"}],"language":"zh","publisherId":"gcrwlxb201103006","title":"SOFC/<span style=\"color:red\">GT</span>/ST三重复合动力系统特性研究","volume":"32","year":"2011"},{"abstractinfo":"采用放电等离子烧结技术制备<span style=\"color:red\">GT</span>35钢结硬质合金,研究了放电等离子烧结<span style=\"color:red\">GT</span>35钢结硬质合金及其热处理后的显微组织与性能.结果表明:与传统粉末冶金方法制备的钢结硬质合金相比,放电等离子烧结制备的<span style=\"color:red\">GT</span>35钢结硬质合金显微组织均匀、晶粒细小、无碳化物偏析.经过1 000℃×6 min+ 200℃×1.5 h的热处理后,硬度比传统粉末烧结制备的钢结硬质合金提高了1.5～3.5HRC,耐磨性也显著提高.","authors":[{"authorName":"蒋朋","id":"e98d1c23-ae71-4f37-ba7f-46764f96cb90","originalAuthorName":"蒋朋"},{"authorName":"吕玉廷","id":"91cf9c4b-788a-4e91-9c6b-a4edc299debd","originalAuthorName":"吕玉廷"},{"authorName":"曹佑青","id":"b48b0ab1-c25f-43a5-904d-79e52d1a34f2","originalAuthorName":"曹佑青"},{"authorName":"吴建峰","id":"b500bd44-291b-4dbd-9be8-2f6ebc9a0400","originalAuthorName":"吴建峰"},{"authorName":"徐金富","id":"9006a422-692d-4083-bc7d-ad66dcd603ab","originalAuthorName":"徐金富"}],"doi":"","fpage":"70","id":"ddf68df6-0f15-4a26-9c16-cd12ed7e4ec7","issue":"6","journal":{"abbrevTitle":"BQCLKXYGC","coverImgSrc":"journal/img/cover/BQCLKXYGC.jpg","id":"4","issnPpub":"1004-244X","publisherId":"BQCLKXYGC","title":"兵器材料科学与工程   "},"keywords":[{"id":"22c24302-95c1-49f0-90a0-f8b0c8c83c34","keyword":"硬质合金","originalKeyword":"硬质合金"},{"id":"0d12a6da-7ddf-4b9d-9595-bcd0ada466c7","keyword":"<span style=\"color:red\">GT</span>35","originalKeyword":"GT35"},{"id":"57acbead-fbf6-4b3d-8559-0c6872942c2e","keyword":"放电等离子烧结","originalKeyword":"放电等离子烧结"},{"id":"9f5f19e3-b9b0-4957-b265-9c55408b9b5b","keyword":"铬钼合金钢","originalKeyword":"铬钼合金钢"},{"id":"67391cbe-49a6-43bc-8aa8-5e5a9afa7fc0","keyword":"TiC","originalKeyword":"TiC"}],"language":"zh","publisherId":"bqclkxygc201206021","title":"放电等离子烧结<span style=\"color:red\">GT</span>35钢结硬质合金的组织与性能","volume":"35","year":"2012"}],"totalpage":9107,"totalrecord":91070}