{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"以宝钢SS400为研究对象，在实验室和宝钢2050热轧机上进行了3次控轧控冷工艺优化及工业实验。通过工业生产实验验证，经拉伸和冲击实验及断口形貌SEM分析和成品SEM分析发现，采用控轧控冷优化工艺和工业实验可以大大地细化晶粒、改善其组织和性能，使SS400铁素体晶粒尺寸接近4～5μm,且冲击韧性良好，延伸率可达30%，屈服强度达到400MPa以上。","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"a631efe9-a44a-41e1-b717-5660b700299d","originalAuthorName":"张红梅"},{"authorName":"杜林秀","id":"46d32bf6-92d6-4bfb-a2dc-e37ffcbd799b","originalAuthorName":"杜林秀"},{"authorName":"李维娟","id":"702ffa2c-8aed-4e9f-a380-4b4c9b7fa1d1","originalAuthorName":"李维娟"},{"authorName":"刘相华","id":"a38ca4f8-a4bd-43b5-b4c1-de1004b77ad9","originalAuthorName":"刘相华"},{"authorName":"王国栋","id":"93ba25a3-7b2f-4873-a43c-36ce4f09674c","originalAuthorName":"王国栋"},{"authorName":"袁建光","id":"49bf2774-b913-4f58-a73d-d7c02b835132","originalAuthorName":"袁建光"},{"authorName":"胡林","id":"bbb0b09d-2822-42fb-aa02-d870b611095a","originalAuthorName":"胡林"}],"doi":"10.3969/j.issn.1001-1447.2001.03.007","fpage":"27","id":"254b42ad-7b2e-4f5f-8f41-a54a0e04f2c1","issue":"3","journal":{"abbrevTitle":"GTYJ","coverImgSrc":"journal/img/cover/GTYJ.jpg","id":"29","issnPpub":"1001-1447","publisherId":"GTYJ","title":"钢铁研究"},"keywords":[{"id":"19bbf142-6026-4ac1-bb1e-f7eabc3e73e3","keyword":"控轧控冷工艺","originalKeyword":"控轧控冷工艺"},{"id":"c6df62ab-e216-438b-b7de-6218f80404d2","keyword":"细化晶粒","originalKeyword":"细化晶粒"},{"id":"7cefda61-a19d-480f-a6cf-2b2f11d61f77","keyword":"铁素体","originalKeyword":"铁素体"},{"id":"6557de87-bf03-416f-90c4-5bed45a22fae","keyword":"断口形貌","originalKeyword":"断口形貌"}],"language":"zh","publisherId":"gtyj200103007","title":"400MPa超级钢控轧控冷优化工艺及工业实验","volume":"1","year":"2001"},{"abstractinfo":"以含Nb细晶高强IF钢热轧板为研究对象,研究了冷轧压下率对实验钢冷轧织构以及再结晶织构形成影响.结果表明,退火后铁素体晶粒细化,强度提高.实验钢经冷轧后主要的织构为{112} <110>、{111} <112>、{111} <110>、{001}<110>,并且随冷轧压下率增加,织构组分无变化,各组分强度整体增加.再经退火后,在α线上织构减弱,甚至一些织构逐渐消失.提高冷轧压下率时,织构峰值逐渐由{001}<110>转为{111} <110>.对于γ取向线,峰值由{111} <110>取向变为{111} <112>取向,最终{111} <112>比{111} <110>取向强度大.实验钢再结晶机制由定向形核和选择生长共同作用的结果,并且随冷轧压下率增大,{111}面织构强度增大,所以r(塑性应变比)值增大,深冲性能提高.","authors":[{"authorName":"马多","id":"7414405e-2fe4-43fc-b149-f3b5b97eae26","originalAuthorName":"马多"},{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"880f54f1-d72a-4ec1-892b-03cc702af1bb","originalAuthorName":"张红梅"},{"authorName":"孙成钱","id":"4847d1eb-97c9-4d95-948b-ac3753e8b3fe","originalAuthorName":"孙成钱"},{"authorName":"王洪斌","id":"8fd3443e-1943-46de-b21d-774b90034cde","originalAuthorName":"王洪斌"},{"authorName":"贾宏斌","id":"4164d318-e5af-4871-96cf-67556da09534","originalAuthorName":"贾宏斌"},{"authorName":"陈越","id":"2475230b-a869-4399-9896-8ef22666c56f","originalAuthorName":"陈越"},{"authorName":"郭雅楠","id":"5d44599a-7569-41c3-9aaa-68d2e3ea964b","originalAuthorName":"郭雅楠"}],"doi":"","fpage":"91","id":"3001701b-39e6-47fa-871a-01423a00a008","issue":"2","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"8775a884-bd19-482c-9897-926b79a90813","keyword":"细晶高强IF钢","originalKeyword":"细晶高强IF钢"},{"id":"70b1ec72-d3de-4e03-b233-cf350f1b6b83","keyword":"冷轧压下率","originalKeyword":"冷轧压下率"},{"id":"67df0b8b-7efe-4ce7-83f6-b6760fd392db","keyword":"织构","originalKeyword":"织构"}],"language":"zh","publisherId":"jsrclxb201502017","title":"冷轧压下率对含Nb细晶高强IF钢织构形成机制的影响","volume":"36","year":"2015"},{"abstractinfo":"以实验室的热模拟变形实验和轧制实验为基础，依据形变诱导相变理论，制定了现场轧制工艺。通过细晶强化和相变强化，使普通SS400钢的屈服强度达到了400MPa，开发出超级Super-SS400钢。","authors":[{"authorName":"王国栋","id":"39182fe8-3f56-4529-b257-75639a418946","originalAuthorName":"王国栋"},{"authorName":"刘相华","id":"bac5dbb6-e975-4af8-aa65-33fa5bab0957","originalAuthorName":"刘相华"},{"authorName":"李维娟","id":"528aec03-db52-42d2-a109-70f3be85d76e","originalAuthorName":"李维娟"},{"authorName":"杜林秀","id":"a42df194-4bc2-4329-8e02-e1f16b78d5fc","originalAuthorName":"杜林秀"},{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"3e769bbe-7ac6-400e-a163-e5c6356775c8","originalAuthorName":"张红梅"},{"authorName":"袁建光","id":"93233a94-111a-4715-9daf-888753b4527a","originalAuthorName":"袁建光"},{"authorName":"<span style=\"color:red\">张</span>丕军","id":"8d9221d7-38f1-4a5a-bad5-1519427cb0bf","originalAuthorName":"张丕军"}],"doi":"","fpage":"39","id":"8587d8f4-e4f3-43ef-9bb7-9e00e4988e5a","issue":"5","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"1a6340a3-5570-4659-aa7f-a4bf7bc60111","keyword":"SS400钢","originalKeyword":"SS400钢"},{"id":"69a8a668-34e9-4253-aa6e-bc8a28ba0115","keyword":"轧制规程","originalKeyword":"轧制规程"},{"id":"a0ef0898-62d1-40a2-bac4-6e58c238d7f4","keyword":"晶粒细化","originalKeyword":"晶粒细化"},{"id":"0871b50c-a5e3-4eaa-a3c4-d28eab6f2c26","keyword":"屈服强度","originalKeyword":"屈服强度"}],"language":"zh","publisherId":"gt200105011","title":"超级Super-SS400钢的工业轧制实验","volume":"36","year":"2001"},{"abstractinfo":"以热轧Si-Mn系双相钢为研究对象,在实验室通过控制轧制和控制冷却实验,研究了变形工艺参数对高强热轧双相钢显微组织和力学性能的影响.研究表明,具有高密度位错亚晶结构的马氏体形貌和分布对双相钢的力学性能有很大影响,通过控制卷取温度、冷却速度和精轧温度,可以得到不同的微观组织形貌和力学性能的热轧双相钢.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"45415e27-361d-4d75-baba-28ad0c5a249a","originalAuthorName":"张红梅"},{"authorName":"孙彬斌","id":"99488382-7b34-48e5-9314-c3a0fc427d3f","originalAuthorName":"孙彬斌"},{"authorName":"贾志伟","id":"cee1bebd-8b4e-4779-86f6-7055014175a7","originalAuthorName":"贾志伟"},{"authorName":"乔立峰","id":"01c24f4e-2b99-4aa6-b106-998b7527094a","originalAuthorName":"乔立峰"},{"authorName":"许云波","id":"a6714e1e-fd8a-46c0-9456-241f7b5759fd","originalAuthorName":"许云波"},{"authorName":"刘振宇","id":"7565a9c7-7baf-47d4-b0b5-5ff90f6d1d19","originalAuthorName":"刘振宇"},{"authorName":"王国栋","id":"57f3fa94-4b90-45f2-ac91-131dca9ad2b6","originalAuthorName":"王国栋"}],"doi":"10.3969/j.issn.1009-6264.2007.04.018","fpage":"78","id":"a12a505c-9c9c-480e-a3be-77c3b3d6c7e1","issue":"4","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"7415524a-0812-4a31-b11f-f2accfbee985","keyword":"Si-Mn系双相钢","originalKeyword":"Si-Mn系双相钢"},{"id":"e161888b-7602-475c-98b9-acee6f513736","keyword":"组织","originalKeyword":"组织"},{"id":"ee1580ee-f909-4c4f-a39a-e23b10c2d80c","keyword":"变形工艺","originalKeyword":"变形工艺"},{"id":"dbfb3071-47e4-4123-8d84-0c59e5feec76","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"jsrclxb200704018","title":"热轧双相钢显微组织和力学性能","volume":"28","year":"2007"},{"abstractinfo":"采用规则溶液亚点阵模型计算了新型含Nb细晶高强IF钢在不同温度(1073～ 1473 K)下碳氮化物析出相的平衡体积分数、组成成分及化学驱动力,各元素的平衡质量分数;采用经典形核长大模型计算了实验钢在不同温度(1073 ～ 1473 K)下位错处形核的临界核心尺寸、临界形核功及相对形核速率.结果表明,随着温度的降低,析出相的平衡体积分数增大,NbC在析出相中比例逐渐增加,NbN在析出相中比例逐渐降低,析出相的化学驱动力增大,固溶在钢中的各元素的质量分数降低;在位错处形核的临界核心尺寸、临界形核功减小,相对形核率增大.至1073 K时,N元素已基本析出,C和N在析出相的成分中基本达到平衡.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"d9445665-1293-450b-aab3-1fc4d693613b","originalAuthorName":"张红梅"},{"authorName":"陈越","id":"cd85bbad-9eaa-466a-a2a1-8258fed87f89","originalAuthorName":"陈越"},{"authorName":"孙成钱","id":"8aba3290-8bd7-472c-9156-ca11c6b43d9d","originalAuthorName":"孙成钱"},{"authorName":"王洪斌","id":"179bf3bb-4c2f-405b-ab0f-45d87b72774d","originalAuthorName":"王洪斌"},{"authorName":"贾宏斌","id":"a8b85a08-bcfc-465b-bca7-aa619f9fa08d","originalAuthorName":"贾宏斌"},{"authorName":"郭雅楠","id":"bd61df78-01b2-4f89-8fd7-f0feb804eea7","originalAuthorName":"郭雅楠"},{"authorName":"马多","id":"dec57398-1e30-49b2-8c40-eae3d5c062cb","originalAuthorName":"马多"}],"doi":"","fpage":"226","id":"d27792f6-6713-4afd-8b26-c5bafdcf0a4d","issue":"4","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"47ed8987-cfbf-4c96-a58c-c24059647f34","keyword":"含Nb细晶高强IF钢","originalKeyword":"含Nb细晶高强IF钢"},{"id":"ddc293e6-2750-45bb-8ac6-fceda921b41f","keyword":"碳氮化物","originalKeyword":"碳氮化物"},{"id":"eee2d69d-d81a-43c4-a77c-8bd30d50b004","keyword":"析出行为","originalKeyword":"析出行为"},{"id":"79b87308-80e1-4d41-951a-0a1fa0c1b282","keyword":"热力学计算","originalKeyword":"热力学计算"},{"id":"b759b659-3362-4080-bd6b-76d2ef818896","keyword":"动力学计算","originalKeyword":"动力学计算"}],"language":"zh","publisherId":"jsrclxb201504040","title":"含Nb细晶高强IF钢的析出热力学和动力学","volume":"36","year":"2015"},{"abstractinfo":"选择新型细晶高强IF钢为研究对象,在实验室进行了热轧、冷轧及罩式退火实验.利用光学显微镜、透射电镜复型和电子背散射衍射(EBSD)技术,研究了不同退火时间对细晶高强IF钢显微组织、析出相及织构的影响.结果表明,选择合适的退火时间,晶粒变得细小、均匀.细晶高强IF钢在退火过程中析出大量的NbC、Nb(CN)相;随退火时间延长,钢中析出相粒子偏聚长大.为了获得较强的有利织构及优异的冲压性能,实验钢退火时间应选定在5 min.","authors":[{"authorName":"陈越","id":"7fe6a2e5-f85d-498a-a3c6-218c9c479af5","originalAuthorName":"陈越"},{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"670aca88-80f1-43ad-b476-8e70537023ac","originalAuthorName":"张红梅"},{"authorName":"孙成钱","id":"dee8eaca-dcd1-468b-b0d3-fa2e123e28e4","originalAuthorName":"孙成钱"},{"authorName":"王洪斌","id":"f3d8b74e-8fc5-41c3-b5b7-00ff29cf2196","originalAuthorName":"王洪斌"},{"authorName":"马多","id":"fda8020a-9178-4f31-a1b8-7603ea0d885a","originalAuthorName":"马多"},{"authorName":"郭雅楠","id":"2758fea5-6dc9-43be-9242-6e1be4283c28","originalAuthorName":"郭雅楠"},{"authorName":"贾宏斌","id":"d4817d7b-ccaa-4328-a98c-e1d0ca4bd5af","originalAuthorName":"贾宏斌"}],"doi":"","fpage":"140","id":"e47b7259-04d2-4279-a817-dab97b6df0a4","issue":"4","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"c180d4ac-229a-46cf-a735-e541e0dacc52","keyword":"细晶高强IF钢","originalKeyword":"细晶高强IF钢"},{"id":"fd0a820c-d357-4636-993d-13ff5e47efcc","keyword":"退火时间","originalKeyword":"退火时间"},{"id":"efad9f45-a4bf-439f-a2c8-6c3e9608ab6a","keyword":"析出相","originalKeyword":"析出相"},{"id":"a00216b9-02fc-48c8-a9d4-bc50087ee73e","keyword":"织构","originalKeyword":"织构"}],"language":"zh","publisherId":"jsrclxb201504024","title":"细晶高强IF钢退火时间研究","volume":"36","year":"2015"},{"abstractinfo":"采用透射电子显微镜(TEM),对细晶高强IF钢在不同退火温度条件下无沉淀析出区(PFZ)的形成机制及其对材料力学性能的影响规律进行研究.结果表明,由于析出相粒子的固溶和粗大化与晶界迁移造成的扫动效应,导致仅在晶界一侧形成独特的无沉淀析出区,退火过程中无沉淀析出区优先在晶界经过的区域形成.在退火过程中,随着退火温度的升高,细晶高强IF钢无沉淀析出区的平均宽度增大,其屈服强度降低,n值逐渐增加.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"6da45773-93d2-4f5b-8ceb-4168cabfb80f","originalAuthorName":"张红梅"},{"authorName":"贾宏斌","id":"176f8e08-aa9e-429a-a361-238718239f52","originalAuthorName":"贾宏斌"},{"authorName":"董行","id":"5ffd0cc4-14cc-4152-a066-63e605a63546","originalAuthorName":"董行"},{"authorName":"王洪斌","id":"d04ff7fc-9e94-426a-8b33-578b6a069aa3","originalAuthorName":"王洪斌"}],"doi":"","fpage":"144","id":"01309135-5550-44a0-adfe-c619da6c18f3","issue":"6","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"25a37314-51b2-43d5-a88e-f9a1f72b1e76","keyword":"细晶高强IF钢","originalKeyword":"细晶高强IF钢"},{"id":"573877e9-6641-4105-8cd2-f79643cf4954","keyword":"无沉淀析出区","originalKeyword":"无沉淀析出区"},{"id":"226326ef-4ddc-4219-a726-93132d2dea2d","keyword":"退火温度","originalKeyword":"退火温度"},{"id":"d7060c2c-c5eb-400c-95a8-2a6cbcc79e78","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"jsrclxb201506027","title":"细晶高强IF钢无沉淀析出区的形成机制及其对材料性能的影响","volume":"36","year":"2015"},{"abstractinfo":"对不同温度下变形和变形后再加热到奥氏体区的低碳钢SS400的显微组织进行了研究.结果表明:变形使奥氏体和铁素体晶界呈锯齿状;锯齿状的奥氏体晶界优先成为铁素体的形核位置;锯齿状的铁素体晶界有利于铁素体再结晶核心的形成.","authors":[{"authorName":"李维娟","id":"e407349d-fcb1-40ce-9926-02dbaf911073","originalAuthorName":"李维娟"},{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"65d7813c-cf33-4b80-8dac-ebf157e2c803","originalAuthorName":"张红梅"},{"authorName":"王国栋","id":"cc9700ae-af98-4d07-936a-8ddca8160273","originalAuthorName":"王国栋"},{"authorName":"刘相华","id":"7f854ecd-7d01-4464-bf36-df10c519321d","originalAuthorName":"刘相华"}],"doi":"","fpage":"27","id":"03a3328a-0198-4960-ae09-953ad07758a9","issue":"6","journal":{"abbrevTitle":"GTYJXB","coverImgSrc":"journal/img/cover/GTYJXB.jpg","id":"30","issnPpub":"1001-0963","publisherId":"GTYJXB","title":"钢铁研究学报"},"keywords":[{"id":"329aa123-09d4-4a78-9ccf-b92273058b8b","keyword":"变形","originalKeyword":"变形"},{"id":"bead34e0-e652-4cc8-9d78-d4a37e0d8bad","keyword":"晶界","originalKeyword":"晶界"},{"id":"bfeb6df6-c568-4007-a12e-15263ba1c4ed","keyword":"奥氏体","originalKeyword":"奥氏体"},{"id":"88ad9047-cde7-4a3b-b180-a143eb721a2a","keyword":"铁素体","originalKeyword":"铁素体"},{"id":"9a05afcd-dec2-4dac-9785-e94d509f8659","keyword":"低碳钢","originalKeyword":"低碳钢"}],"language":"zh","publisherId":"gtyjxb200106007","title":"变形晶界对低碳钢显微组织的影响","volume":"13","year":"2001"},{"abstractinfo":"用溶液插层法制备了PLA/MgAlCu-LDH共混溶液,通过涂膜法制备了不同MgAlCu-LDH含量的PLA/MgAlCu-LDH复合膜,采用扫描电镜(SEM)、红外光谱(FTIR)、X射线衍射(XRD)、力学性能测试仪器对制备的复合膜的形貌、结构及性能进行测试表征.结果表明:部分PLA分子链插入到MgAlCu-LDH片层间隙中,使得MgAlCu-LDH层间距变大,MgAlCu-LDH作为插层剂对整个共混聚合物的韧性和强度有明显的影响;PLA/MgAl-Cu-LDH复合材料的杨氏模量随MgAlCu-LDH含量的增加而增加,加入少量MgAlCu-LDH时PLA/MgAlCu-LDH复合材料的抗拉强度、屈服强度和断裂伸长率均增加,在室温下拉伸时,PLA/MgAlCu-LDH 3％(质量分数)复合材料的抗拉强度、屈服强度和断裂伸长率分别比PLA提高14.5％、11.5％和23.7％.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"1d5d1e49-4c6e-4355-a858-817ea20faa11","originalAuthorName":"张红梅"},{"authorName":"朱同贺","id":"2d2c65d5-e88d-4384-b703-1687faab2bf7","originalAuthorName":"朱同贺"}],"doi":"10.11896/j.issn.1005-023X.2015.02.020","fpage":"91","id":"0554fee8-f847-44bc-acad-2256226feadd","issue":"2","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"81d27d5c-15a5-4dc2-8f70-28f6f91ac651","keyword":"聚乳酸(PLA)","originalKeyword":"聚乳酸(PLA)"},{"id":"32748e7d-ec01-4bc1-a7ac-de9b47041617","keyword":"镁铝铜水滑石(MgAlCu-LDH)","originalKeyword":"镁铝铜水滑石(MgAlCu-LDH)"},{"id":"617aa9b5-bc8a-4b48-b58c-70699ef74528","keyword":"共混","originalKeyword":"共混"},{"id":"8a17636a-3d5c-4ee9-a1f7-43bdbd757822","keyword":"表征","originalKeyword":"表征"}],"language":"zh","publisherId":"cldb201502020","title":"PLA/MgAlCu-LDH复合材料的制备、表征及性能研究","volume":"29","year":"2015"},{"abstractinfo":"在Gleeble1500热模拟机上以SS400钢为研究对象,用冷加工+回火再结晶和冷加工+α→γ逆相变等工艺,研究了冷变形对马氏体(铁素体)再结晶行为的影响以及奥氏体晶粒细化的方法.结果表明:低温变形对板条马氏体的再结晶行为有一定影响,并且由于低温变形后快速升温的铁素体回复、再结晶与奥氏体(铁素体)相变等相继发生,从而得到比较细小的奥氏体晶粒.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">红梅</span>","id":"db08294d-6eb8-4f03-9f21-36d584debb2d","originalAuthorName":"张红梅"},{"authorName":"王振敏","id":"110f3156-45ef-4eb8-be02-23e380dd9619","originalAuthorName":"王振敏"},{"authorName":"李维娟","id":"1fb3c5a1-48d2-4b02-8193-993ec1b5cf68","originalAuthorName":"李维娟"},{"authorName":"王国栋","id":"568f797c-7fb0-484c-ab40-447aa0672aaf","originalAuthorName":"王国栋"},{"authorName":"刘相华","id":"26d59115-1f3d-48f3-bcc0-1a35b36d188e","originalAuthorName":"刘相华"}],"doi":"10.3969/j.issn.1000-3738.2004.07.002","fpage":"4","id":"0d39256f-4343-4d2a-bf96-35a040ef76f0","issue":"7","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":"62b3b5f6-84f1-493e-ab2f-84cc0839c227","keyword":"奥氏体","originalKeyword":"奥氏体"},{"id":"de0903f1-a3a1-41fa-ba64-21bfb6783f00","keyword":"逆相变","originalKeyword":"逆相变"},{"id":"eb4593fe-5df4-46e9-90be-72085894316f","keyword":"铁素体","originalKeyword":"铁素体"},{"id":"1c825c34-b74d-42e4-9719-fbfd1b0665ef","keyword":"晶粒细化","originalKeyword":"晶粒细化"},{"id":"97a4883e-8886-4078-937d-147bd80a5c2b","keyword":"马氏体","originalKeyword":"马氏体"}],"language":"zh","publisherId":"jxgccl200407002","title":"奥氏体晶粒细化的研究","volume":"28","year":"2004"}],"totalpage":25,"totalrecord":241}