{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"设计了一种低碳Fe-Mn-Nb-Cu-B系屈服强度690 MPa级工程机械结构用钢,利用扫描电镜(SEM)和透射电镜(TEM)等仪器研究了不同回火温度对实验钢的组织和性能的影响.结果表明:回火温度对屈服强度和抗拉强度均有较大影响,都呈现出先降低再升高再降低的规律.600℃回火时的综合力学性能较好,屈服强度比未回火时增加了145 MPa;并且屈强比和硬度随回火温度的变化趋势同抗拉强度和屈服强度的变化规律是相同的.分析认为:回火前后力学性能的变化的主要原因是与回火后有更多弥散的尺寸在20 nm以下的新的细小(Nb,Ti) (N,C)粒子析出以及发生位错的回复和M-A岛的分解有关.","authors":[{"authorName":"蒋长虹","id":"d830244d-358d-4955-a794-e56f3ff59e9b","originalAuthorName":"蒋长虹"},{"authorName":"惠亚军","id":"565159b6-277c-43ba-b051-a6f568260730","originalAuthorName":"惠亚军"},{"authorName":"赵爱民","id":"fb6b4cd3-c52b-4a4d-b790-c0b3e8ef971c","originalAuthorName":"赵爱民"},{"authorName":"赵征志","id":"8985a470-2906-4e01-8991-f35dba9b5f95","originalAuthorName":"赵征志"},{"authorName":"黄耀","id":"e217fbf7-19b0-4236-a3d9-93a32ce68224","originalAuthorName":"黄耀"},{"authorName":"李蕾","id":"2d80e23a-ef7f-44d4-b905-b58343526f2a","originalAuthorName":"李蕾"},{"authorName":"李文远","id":"6269c287-231b-4206-8f0c-1d7a7f3f19c6","originalAuthorName":"李文远"},{"authorName":"武会宾","id":"f8a0824f-ae1d-44d1-8829-f3c35ddb434f","originalAuthorName":"武会宾"}],"doi":"","fpage":"103","id":"0dfcd9f6-a51d-4f74-956f-87b3b623d63c","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":"de2c51dd-e94b-40d2-ba99-077293a08476","keyword":"低碳Fe-Mn-Nb-Cu-B钢回火温度","originalKeyword":"低碳Fe-Mn-Nb-Cu-B钢回火温度"},{"id":"3eef2c7f-73c5-4b8c-a589-c3e2c6267585","keyword":"显微组织","originalKeyword":"显微组织"},{"id":"69f1affe-292a-4f1a-92d0-58e7dea75fdd","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"jsrclxb201306021","title":"回火温度对690 MPa级工程机械用钢组织与性能的影响","volume":"34","year":"2013"},{"abstractinfo":"采用CCT-AY-Ⅱ型钢板连续退火机模拟分析了退火时间对中锰TRIP钢0.1C-6Mn组织性能的影响规律.采用SEM、EBSD等微观方法观察不同工艺下制备的中锰TRIP的微观组织,利用XRD法测量了残留奥氏体量,实验测量了其力学性能.结果表明,650℃退火1 min时伸长率就达到了18%,抗拉强度1260 MPa,强塑积23 GPa%.通过EBSD证明试验钢退火马氏体只发生了回复,没有发生再结晶,且获得了超细晶组织.通过对保温3 min试验钢残留奥氏体研究,试验钢高的伸长率是由TRIP效应和组织的超细晶共同提供的.","authors":[{"authorName":"尹鸿祥","id":"1d98d5c7-4b77-46e1-a242-f21a86704c90","originalAuthorName":"尹鸿祥"},{"authorName":"赵爱民","id":"c7d3e116-37bb-4605-a482-2fed1857750f","originalAuthorName":"赵爱民"},{"authorName":"赵征志","id":"c1aeea90-690a-4d35-b9fe-e5cb5cd0d18a","originalAuthorName":"赵征志"},{"authorName":"李振","id":"e27408ce-7d4f-44df-b592-ccec36a92078","originalAuthorName":"李振"},{"authorName":"黄耀","id":"432505bd-d0b8-413d-bbed-00fd79c7e300","originalAuthorName":"黄耀"},{"authorName":"代乐乐","id":"7b92c554-240b-4df0-90d5-4b1348aa5e65","originalAuthorName":"代乐乐"},{"authorName":"曹佳丽","id":"6dad69ad-9fb2-47f9-a62b-c325b28ccdcd","originalAuthorName":"曹佳丽"}],"doi":"","fpage":"64","id":"2819b9e4-4911-4e64-a98a-bc703d9c231e","issue":"9","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":"40578a52-10bc-4d94-9808-2f61b6c45be3","keyword":"中锰钢","originalKeyword":"中锰钢"},{"id":"c1d7b99d-0cd5-44ce-af15-9acc62f74391","keyword":"亚稳奥氏体","originalKeyword":"亚稳奥氏体"},{"id":"f71f9f01-d64d-4e4a-83a4-bc9232570527","keyword":"超细晶","originalKeyword":"超细晶"},{"id":"c2db9ca2-99fe-4078-8237-2192fa7f7f5a","keyword":"两相区退火","originalKeyword":"两相区退火"}],"language":"zh","publisherId":"jsrclxb201309012","title":"退火时间对超细晶中锰TRIP钢组织性能的影响","volume":"34","year":"2013"},{"abstractinfo":"采用ODF织构分析方法,对390MPa级超低碳BH钢板热轧、冷轧、退火过程织构演变规律进行研究,并对不同冷轧月下量和不同退火工艺织构进行分析。结果表明:经冷轧变形后的钢板有较强的择优取向,具有典型的{112}〈110〉和{111}〈110〉织构,形变织构中的不利织构{001}〈110〉较强;冷轧压下率为80%时再结晶退火后钢板具有较强的Y织构,{111}〈112:织构取向密度高达11.7;退火温度和保温时间对a织构影响不大,提高退火温度和延长保温时间使y织构增强,r值增加。","authors":[{"authorName":"陈银莉","id":"e9a61769-5320-42ec-b86b-a56541a9e196","originalAuthorName":"陈银莉"},{"authorName":"苏岚","id":"556b5341-1aaa-48d0-b27b-288a4f403cfb","originalAuthorName":"苏岚"},{"authorName":"赵爱民","id":"5652a9f7-6744-495a-b6ed-3b8089e40e87","originalAuthorName":"赵爱民"},{"authorName":"吴雷","id":"982d0303-a98b-4075-9557-339e7fe9eb28","originalAuthorName":"吴雷"},{"authorName":"李本海","id":"ecb8b9cd-aade-4126-9aa3-667f2eb5c184","originalAuthorName":"李本海"},{"authorName":"刘光明","id":"df93c32b-d67a-4707-8469-9e8570982538","originalAuthorName":"刘光明"},{"authorName":"滕华湘","id":"bd15f78c-8ddf-43fd-842e-346748be48a7","originalAuthorName":"滕华湘"}],"doi":"","fpage":"117","id":"2b58eab2-585a-480e-995b-94f57d0d2648","issue":"1","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":"c5f31ab3-c452-4b42-bfe5-6f9d644c2b0b","keyword":"织构分析","originalKeyword":"织构分析"},{"id":"1f9c65ad-62af-4fe0-8c2e-c3e7ec0bb12b","keyword":"BH钢板","originalKeyword":"BH钢板"},{"id":"57c5d15a-05e0-4815-ab8e-32d33e12a9ff","keyword":"超低碳","originalKeyword":"超低碳"},{"id":"cf0c58be-a064-47a7-9eb1-03fe5694d667","keyword":"演变","originalKeyword":"演变"},{"id":"faa4e45d-f8fe-4efc-84ec-73d96c532d9f","keyword":"冷轧变形","originalKeyword":"冷轧变形"},{"id":"6cebe752-d098-49fa-812c-f4fcfa97b69d","keyword":"保温时间","originalKeyword":"保温时间"},{"id":"c7d38de7-3593-4418-969a-b92f0987c363","keyword":"退火温度","originalKeyword":"退火温度"},{"id":"de440ebb-0403-486c-82a3-b6dd0a5026fd","keyword":"再结晶退火","originalKeyword":"再结晶退火"}],"language":"zh","publisherId":"jsrclxb201201022","title":"390MPa级超低碳BH钢织构演变规律","volume":"33","year":"2012"},{"abstractinfo":"在实验室试制了800 MPa级别的高强度低成本C-Mn-Si系双相钢,研究了双相钢的双相处理工艺、组织和性能.通过对三种不同成分的双相钢在(α+γ)两相区的加热淬火处理获得了不同F+M比例的双相钢钢板,其性能可通过调整双相处理工艺来调节.结果表明,800 MPa级冷轧双相钢最优加热温度为760~800℃,缓冷速度为10℃/s.","authors":[{"authorName":"张增良","id":"9e5a8b94-9ee9-419b-b243-5ef7dfbf606b","originalAuthorName":"张增良"},{"authorName":"宋仁伯","id":"40aeea11-a8e8-48cf-8a5d-8f04cc3190b6","originalAuthorName":"宋仁伯"},{"authorName":"程知松","id":"08791382-a263-4e19-ab89-872bb1d56a41","originalAuthorName":"程知松"},{"authorName":"赵爱民","id":"d2fe7bf9-6a6a-4f86-acf3-45babda1732e","originalAuthorName":"赵爱民"},{"authorName":"赵征志","id":"b81e92a3-e22a-4729-8460-fcd3c75ab3cd","originalAuthorName":"赵征志"},{"authorName":"刘光明","id":"b5d77086-14e4-4de6-8968-58c514e5999c","originalAuthorName":"刘光明"},{"authorName":"熊爱明","id":"25c7b195-03ec-4c83-9a93-da064acae410","originalAuthorName":"熊爱明"}],"doi":"10.3969/j.issn.1001-7208.2007.05.030","fpage":"160","id":"b75518bf-aefc-4fdc-9ee1-37d86911fbe0","issue":"5","journal":{"abbrevTitle":"SHJS","coverImgSrc":"journal/img/cover/SHJS.jpg","id":"59","issnPpub":"1001-7208","publisherId":"SHJS","title":"上海金属"},"keywords":[{"id":"896b00b7-d444-4171-8462-cdb258953556","keyword":"冷轧双相钢","originalKeyword":"冷轧双相钢"},{"id":"d5eb1a58-8977-468b-9cd4-7ae28544eadb","keyword":"连续退火","originalKeyword":"连续退火"},{"id":"c925cc7e-edc5-4e94-8e28-24c239f631e0","keyword":"组织","originalKeyword":"组织"},{"id":"00ebf040-f270-4206-8147-80aee496902d","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"shjs200705030","title":"800 MPa级冷轧双相钢的工艺与组织性能研究","volume":"29","year":"2007"},{"abstractinfo":"采用电磁搅拌制备出含球状固相的1Cr18Ni9Ti不锈钢半固态流变浆料,并将这种浆料直接轧制成厚度为2~5 mm板材,然后观察分析了不同尺寸轧件的微观组织.结果表明:固相分数为0.3~0.6的半固态流变浆料具有较好的流动性,在重力作用下,流变浆料可以从电磁搅拌器输送至轧机进行直接轧制.但在轧制过程中会产生液相偏析和固相颗粒的塑性变形.沿轧件宽度和厚度边缘液相分数高,中心部位液相分数低;小尺寸轧件的液相偏析程度较小,而大尺寸轧件的液相偏析程度大;大尺寸轧件中心的固相颗粒发生了一定程度的塑性变形,沿着轧制方向,固相颗粒明显拉长.这说明在轧制变形过程中,半固态流变浆料的液相和固相颗粒流动速度不同,液相的流动速度快,当中心部位的固相分数增加到一定值时,固相颗粒将发生塑性变形.","authors":[{"authorName":"赵爱民","id":"809630fc-90cb-4c69-ae14-6861143aba2a","originalAuthorName":"赵爱民"},{"authorName":"康永林","id":"867f7948-c4a0-4ed9-b2ab-ad113042ff8c","originalAuthorName":"康永林"},{"authorName":"毛卫民","id":"9a02ec97-9446-4063-a203-c1f8ead5852b","originalAuthorName":"毛卫民"},{"authorName":"高军芳","id":"4acb115c-a7af-441d-8e12-e3ea1669bdf1","originalAuthorName":"高军芳"},{"authorName":"张乐平","id":"108443ba-1690-4669-9ef6-6f1482c770c0","originalAuthorName":"张乐平"},{"authorName":"焦殿辉","id":"d674f264-84c8-47ce-b712-2f58fa7c530d","originalAuthorName":"焦殿辉"},{"authorName":"李具仓","id":"4075e8dc-0125-4e5c-9213-950e3bd8b7ae","originalAuthorName":"李具仓"}],"doi":"","fpage":"27","id":"ea1c1319-b58a-4e77-9795-00c88458f857","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":"0ded802e-e031-4d5d-a6ff-a9cb7180a43a","keyword":"1Cr18Ni9Ti","originalKeyword":"1Cr18Ni9Ti"},{"id":"efd9287c-37a7-428f-9409-e65663a35c43","keyword":"不锈钢","originalKeyword":"不锈钢"},{"id":"1f90aa48-af69-4939-97f2-8e3f70e01fc1","keyword":"电磁搅拌","originalKeyword":"电磁搅拌"},{"id":"69bafbcf-1e0e-4643-a384-5f8fb1563cc8","keyword":"凝固","originalKeyword":"凝固"},{"id":"631e9492-af80-442f-8d66-f2046cd8838a","keyword":"流变浆料","originalKeyword":"流变浆料"},{"id":"133b1be6-8456-440e-afe7-fe7e598ac112","keyword":"直接轧制","originalKeyword":"直接轧制"}],"language":"zh","publisherId":"gtyjxb200406006","title":"1Cr18Ni9Ti不锈钢的半固态流变浆料的直接轧制","volume":"16","year":"2004"},{"abstractinfo":"对喷射沉积Al-30%Si合金组织及其在半固态保温过程中的转变进行了试验研究.喷射沉积Al30%Si合金沉积态组织是由细小的Si相与α基体组成,提出这种组织是由于离异共晶引起的,并运用该机制对组织中Si相的集聚进行了解释,认为其形成机制为:其一,在沉积阶段凝固过程中大量细小的Si发生了粗化和团聚;其二,大量的Si在沉积时会发生碰撞而靠在一起,在随后的离异共晶凝固过程中,共晶硅附着在初生硅上从而将原来相互独立的Si联结在一起.在半固态保温过程中,基体发生熔化而出现球形α,而Si相则发生粗化,且粗化速度与保温温度和时间有关.","authors":[{"authorName":"甄子胜","id":"0d4d3220-d2c1-473a-8c81-a115efa30206","originalAuthorName":"甄子胜"},{"authorName":"赵爱民","id":"cdf2d623-c24b-4847-9487-e356507e006a","originalAuthorName":"赵爱民"},{"authorName":"毛卫民","id":"cbba1b0c-1234-4341-8bb6-75b150415f9e","originalAuthorName":"毛卫民"},{"authorName":"姚书芳","id":"cde7a01c-e55f-46a3-a7d2-8a0c6d5cad58","originalAuthorName":"姚书芳"},{"authorName":"钟雪友","id":"42b22f81-53be-434d-9af0-674352eb741e","originalAuthorName":"钟雪友"},{"authorName":"冯立军","id":"b9a9ca5f-19d6-4eef-861f-fa3119791c1b","originalAuthorName":"冯立军"},{"authorName":"封素芹","id":"e6c03053-262e-4bf8-864b-e26a143260b1","originalAuthorName":"封素芹"}],"doi":"10.3969/j.issn.1005-0299.2001.02.012","fpage":"162","id":"f78ad3f3-53be-4f59-8eb9-b87df859a4ae","issue":"2","journal":{"abbrevTitle":"CLKXYGY","coverImgSrc":"journal/img/cover/CLKXYGY.jpg","id":"14","issnPpub":"1005-0299","publisherId":"CLKXYGY","title":"材料科学与工艺"},"keywords":[{"id":"49552a4c-d4ac-4e2b-8b64-c01cdbf1d7b4","keyword":"喷射沉积","originalKeyword":"喷射沉积"},{"id":"58d5062b-1d72-4e0c-a2e7-865d655c6546","keyword":"高硅铝合金","originalKeyword":"高硅铝合金"},{"id":"6f31f645-fe22-44a7-beda-5052be70c0aa","keyword":"半固态","originalKeyword":"半固态"},{"id":"453c1a35-0463-4112-9ce5-19d652bd2db9","keyword":"Si相粗化","originalKeyword":"Si相粗化"},{"id":"9fdae002-6c60-4803-a69a-db71267e8b46","keyword":"快速凝固","originalKeyword":"快速凝固"}],"language":"zh","publisherId":"clkxygy200102012","title":"喷射沉积Al-30Si组织及其半固态保温转变规律","volume":"9","year":"2001"},{"abstractinfo":"对用电磁搅拌装置制备的半固态奥氏体不锈钢1Cr18Ni9Ti钢进行了直接轧制成形试验.轧制前后微观组织的分析结果表明:半固态1Cr18Ni9Ti钢具有球形或近球形的初生固相颗粒,并大多呈聚集状态;轧制变形后,液固相发生分离,产生液相偏析;只有当固相率达到50%时,初生固相颗粒在轧制过程中才会发生塑性变形,同时初生固相颗粒内部的δ相由多边形状转变为板条形状.","authors":[{"authorName":"宋仁伯","id":"c6bce84a-23bd-4ac4-9f34-1e50f7a3afa8","originalAuthorName":"宋仁伯"},{"authorName":"康永林","id":"945d02ae-d780-473d-9d60-1589b0a38b6e","originalAuthorName":"康永林"},{"authorName":"孙建林","id":"2d4390b6-5707-496f-ad77-c32affc29ca7","originalAuthorName":"孙建林"},{"authorName":"董洪波","id":"485d99b3-62ac-40b8-8ea2-137b05c660ac","originalAuthorName":"董洪波"},{"authorName":"王吉文","id":"8a2d3c92-b43a-4efb-85d7-5bb9454aab2a","originalAuthorName":"王吉文"},{"authorName":"赵爱民","id":"5268e42d-7c7b-41bf-91f9-512e54252cd5","originalAuthorName":"赵爱民"},{"authorName":"毛卫民","id":"11ff6a0b-8f24-4c60-9a2e-2c203c13f60f","originalAuthorName":"毛卫民"}],"doi":"10.3969/j.issn.1000-3738.2002.09.002","fpage":"4","id":"f951508d-5e81-4101-b65d-dde704d4f966","issue":"9","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":"0ba99308-2dfe-41e2-8185-cd16e517cf6c","keyword":"半固态","originalKeyword":"半固态"},{"id":"96b434f8-3478-4dea-911b-9cd986ee492b","keyword":"电磁搅拌","originalKeyword":"电磁搅拌"},{"id":"cf04c04b-4047-4ee5-8940-94d34c8d5073","keyword":"固相率","originalKeyword":"固相率"},{"id":"7f241204-d500-4253-9be5-57e73906855e","keyword":"液相偏析","originalKeyword":"液相偏析"}],"language":"zh","publisherId":"jxgccl200209002","title":"半固态下1Cr18Ni9Ti钢轧制过程中的组织演变","volume":"26","year":"2002"},{"abstractinfo":"研究了AlSi7Mg合金半固态等温电磁搅拌过程和连续降温电磁搅拌合金熔体的温度分布. 结果表明;在电磁搅拌条件腑氏温度梯度下, 可增加初生α-Al一次臂的长大失去方向优先性, 并使一次臂生长速度减慢, 二次的长大速度与一次臂的长大速度相迫使lSi7Mg合金出现薇状初生α-Al.","authors":[{"authorName":"毛卫民","id":"184ce0c4-96ce-49c3-b35b-e427f0699d14","originalAuthorName":"毛卫民"},{"authorName":"赵爱民","id":"2712e806-31bc-43c7-a859-3a137cfce6fb","originalAuthorName":"赵爱民"},{"authorName":"崔成林","id":"44598f38-5229-4658-85a5-861d3c232d87","originalAuthorName":"崔成林"},{"authorName":"钟雪友","id":"9d16fddb-0f3b-4038-a7ff-6257c5f190d7","originalAuthorName":"钟雪友"}],"categoryName":"|","doi":"","fpage":"971","id":"025d83dd-cdda-4437-9245-5db078ceba8c","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"b82c67e3-6f98-4b99-a04e-8e69abb45acd","keyword":"AlSi7Mg合金","originalKeyword":"AlSi7Mg合金"},{"id":"9f022439-621a-41c8-9c09-ada4d29a0abd","keyword":"null","originalKeyword":"null"},{"id":"3deb655b-0943-48c5-810f-e838df801d55","keyword":"null","originalKeyword":"null"},{"id":"9111e817-25c8-4be1-99b9-1b74706b5d7d","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"0412-1961_1999_9_5","title":"电磁搅拌对半固态AlSi7Mg合金初生α—Al的影响规律","volume":"35","year":"1999"},{"abstractinfo":"运用拉伸、金相、析出物定量分析、SEM、TEM和EDS等测试方法,对不同卷取温度低碳钢组织性能及硫化物析出进行研究.结果表明:随着卷取温度的升高,钢的强度和晶粒度等级下降.MnS析出主要分2个阶段:第1阶段主要为奥氏体区MnS和Al2O3的复合析出,析出尺寸普遍介于1~5μm之间,形状为条片状;第2阶段为MnS在卷取过程中析出,尺寸普遍介于200~600nm之间,形状为近球形.卷取温度的变化对化合硫含量以及MnS析出尺寸分布范围影响较小.","authors":[{"authorName":"王岩","id":"c274a304-b3a6-417d-9843-0b179ff6547d","originalAuthorName":"王岩"},{"authorName":"赵爱民","id":"faeb0480-d486-4ef5-ba01-786749c3454a","originalAuthorName":"赵爱民"},{"authorName":"陈银莉","id":"30bd09d5-df7a-40cf-96ab-8efc04e240a0","originalAuthorName":"陈银莉"},{"authorName":"左碧强","id":"888aef30-42d9-4308-aab6-470304d7fcb8","originalAuthorName":"左碧强"},{"authorName":"薛俊平","id":"cd405763-e42a-49c5-9532-c786c78db2e0","originalAuthorName":"薛俊平"}],"doi":"","fpage":"60","id":"0437cdbd-ea1c-4f3c-b4e1-ffd875d1eb31","issue":"1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"c8df747f-6c6a-4581-8f21-9a26636704bf","keyword":"卷取温度","originalKeyword":"卷取温度"},{"id":"2158b7e4-0d08-4d8e-af58-8a543dccab24","keyword":"MnS","originalKeyword":"MnS"},{"id":"8cdf67a3-3cd3-41e2-93cb-aac65954634c","keyword":"析出","originalKeyword":"析出"},{"id":"52127db1-d6d7-44f4-9cb4-c2d2996c4667","keyword":"SPHC","originalKeyword":"SPHC"}],"language":"zh","publisherId":"gt201101012","title":"不同卷取温度低碳钢性能及硫化物析出的研究","volume":"46","year":"2011"},{"abstractinfo":"用中频感应电炉熔炼获得不同Cr含量高Si铁基合金试样.借助光学显微镜、扫描电镜和力学性能检测设备及腐蚀性能检测仪器等手段,分析和研究了含Cr高Si铁基合金的组织、力学性能和耐腐蚀性能.结果表明:含Cr高Si铁基合金的共晶石墨数量少,分散度高,组织细小;当Cr含量>5.2%时,大量的富Cr相在晶界处析出;当Cr加入量为4.5%~6.5%时,其力学性能和耐硝酸腐蚀性能最好,冲击韧性达1.66 J/cm2,腐蚀速率仅为6.3119 g/h·m2;含Cr高Si铁基合金在H2SO4中的腐蚀速率随着Cr含量增加而增加.","authors":[{"authorName":"汪淑英","id":"c9a014bb-7924-441e-a6a7-d46aae509aab","originalAuthorName":"汪淑英"},{"authorName":"李具仓","id":"3e9e7ea4-2211-40f4-af0a-42ead414aa60","originalAuthorName":"李具仓"},{"authorName":"赵爱民","id":"ca5ac170-3d40-4a92-bd1a-6c54e7fb5024","originalAuthorName":"赵爱民"},{"authorName":"毛双亮","id":"848cb91c-4683-4f05-b856-591ea63db1a9","originalAuthorName":"毛双亮"},{"authorName":"王贵清","id":"d18feb3a-8ed4-430d-97c9-6f344f30b835","originalAuthorName":"王贵清"},{"authorName":"王秀生","id":"eacf3f8b-e3e0-4810-bb64-068574bf45ed","originalAuthorName":"王秀生"}],"doi":"10.3969/j.issn.1005-4537.2007.05.008","fpage":"292","id":"0504e81f-3525-45b3-b07b-184a151e4bab","issue":"5","journal":{"abbrevTitle":"ZGFSYFHXB","coverImgSrc":"journal/img/cover/中国腐蚀封面19-3期-01.jpg","id":"81","issnPpub":"1005-4537","publisherId":"ZGFSYFHXB","title":"中国腐蚀与防护学报"},"keywords":[{"id":"8bbaa0b3-4b44-450d-b5be-d7c6f63b32af","keyword":"高Si铁基合金","originalKeyword":"高Si铁基合金"},{"id":"a78b3cb7-b75a-4996-a8ee-f4efd50da9af","keyword":"显微组织","originalKeyword":"显微组织"},{"id":"8837b869-5218-4580-ae1d-47c21572a200","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"ecb99326-6613-453c-99f0-4cf5176b2ac5","keyword":"耐蚀性","originalKeyword":"耐蚀性"}],"language":"zh","publisherId":"zgfsyfhxb200705008","title":"含铬高硅铁基合金组织和性能的研究","volume":"27","year":"2007"}],"totalpage":15,"totalrecord":144}