材料导报, 2006, 20(4): 102-105.
模板法制备纳米片状银粉的粒径与形貌控制
耐磨损性能试验,研究了V颗粒大小及分布形态和不同V含量对AgCuV合金的耐磨性能的影响.研究结果表明:合金中V颗粒细小且弥散均匀以及提高V的含量,有利于提高合金材料的耐磨损性能;AgCuV合金的磨损机理为磨粒磨损和氧化磨损.","authors":[{"authorName":"陈永泰","id":"6e88dd35-2d20-4639-9388-6b87fca6cf8b","originalAuthorName":"陈永泰"},{"authorName":"谢明","id":"ee94fba7-62f1-4530-85b3-55a4f6722347","originalAuthorName":"谢明"},{"authorName":"杨有才","id":"e0fb2438-354a-43e9-9da3-fd00437f7349","originalAuthorName":"杨有才"},{"authorName":"黎玉盛","id":"462a5c5f-b1b6-4780-9646-300ed39573ad","originalAuthorName":"黎玉盛"},{"authorName":"李靖华","id":"1aad3a8b-4363-4920-af57-6c33ae246d53","originalAuthorName":"李靖华"},{"authorName":"张利斌","id":"1bef1606-93e9-4a5d-8ec1-5b538179649b","originalAuthorName":"张利斌"},{"authorName":"崔浩","id":"35e514a4-d435-432d-b2bd-e1d2c42723b6","originalAuthorName":"崔浩"},{"authorName":"刘满门","id":"ef38ad11-3b6a-47aa-82f0-507f3c4520bb","originalAuthorName":"刘满门"}],"doi":"10.3969/j.issn.1004-0676.2010.01.005","fpage":"17","id":"6a6a821e-140a-4f7f-a780-fb4386622c7b","issue":"1","journal":{"abbrevTitle":"GJS","coverImgSrc":"journal/img/cover/GJS.jpg","id":"38","issnPpub":"1004-0676","publisherId":"GJS","title":"贵金属"},"keywords":[{"id":"0537f4e3-2b88-413f-8dfa-b0108da56009","keyword":"金属材料","originalKeyword":"金属材料"},{"id":"b6f1f8ae-3c96-4101-a089-4de64a3b317b","keyword":"银铜钒合金","originalKeyword":"银铜钒合金"},{"id":"a31ced2c-96d3-40b4-9793-a9d979d1b15a","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"},{"id":"cd7415a9-17fe-44f2-a2b5-3243558d521c","keyword":"磨粒磨损","originalKeyword":"磨粒磨损"},{"id":"4986ed59-d533-42d5-a5e1-5561981797bb","keyword":"氧化磨损","originalKeyword":"氧化磨损"}],"language":"zh","publisherId":"gjs201001005","title":"银铜钒合金耐磨损性能研究","volume":"31","year":"2010"},{"abstractinfo":"
采用多弧离子镀技术, 使用Ti-Al-Zr合金靶及Cr单质靶的组合方式, 在W18Cr4V高速钢基体上制备TiAlZrCr/(Ti, Al, Zr, Cr)N四元梯度氮化物膜. 利用SEM和XRD分析梯度膜的微观组织和结构, 使用摩擦磨损试验机研究梯度膜在室温(15 ℃)和高温(500 ℃)下的耐磨损特性, 并采用SEM观察磨痕形貌. 结果表明, 在不同沉积偏压下制备的四元梯度膜均具有fcc-NaCl型的TiN结构, 其组织致密均匀, 呈典型的柱状晶形态. 梯度膜的摩擦磨损机理是以塑性变形为主要特征的黏着磨损, 并伴有轻微的磨粒磨损. 在室温和高温下磨损时的平均摩擦系数分别在0.25~0.30和0.30~0.35之间, 且当沉积偏压增加至-200 V时, 梯度膜的耐磨损性能实现最优化.
","authors":[{"authorName":"赵时璐","id":"d5ef036a-7929-4e1a-955e-0e1731f9b4ed","originalAuthorName":"赵时璐"},{"authorName":"张震","id":"8b09dcbd-d8b4-486b-9240-28b573542896","originalAuthorName":"张震"},{"authorName":"张钧","id":"4b319112-1714-4c06-a3ed-3f89b29f6e71","originalAuthorName":"张钧"},{"authorName":"王建明","id":"a8186104-cdda-4849-9c66-96093b2db01a","originalAuthorName":"王建明"},{"authorName":"张正贵","id":"5b1ad070-7c9d-45a7-9663-9719f0bd67e0","originalAuthorName":"张正贵"}],"categoryName":"Orginal Article","doi":"10.11900/0412.1961.2015.00522","fpage":"747","id":"7994aeed-da80-45b1-b26e-f6d02000e8a0","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":"6a6615ac-ad10-4fb8-b318-4994c19a3f82","keyword":"TiAlZrCr/(Ti","originalKeyword":"TiAlZrCr/(Ti"},{"id":"d7f7e9c0-c2ca-452e-8049-c46ca3812354","keyword":"Al","originalKeyword":"Al"},{"id":"b0835feb-c05a-4044-ac08-9160adf166f6","keyword":"Zr","originalKeyword":"Zr"},{"id":"80a9d3e5-dea1-406d-8eaa-59d459ac13d6","keyword":"Cr)N梯度膜","originalKeyword":"Cr)N梯度膜"},{"id":"0cfe340f-695f-4a33-b0b7-51e19648e327","keyword":"多弧离子镀","originalKeyword":"多弧离子镀"},{"id":"a68e73ed-1a74-4b89-abe2-da84df3e1874","keyword":"偏压","originalKeyword":"偏压"},{"id":"017b5a00-15fd-4b80-afe5-e402e3a6976d","keyword":"显微结构","originalKeyword":"显微结构"},{"id":"499b53cc-4044-4bb4-97de-635aa036866a","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"C20150522","title":"多弧离子镀TiAlZrCr/(Ti, Al, Zr, Cr)N梯度膜的微观结构与耐磨损性能*","volume":"52","year":"2016"},{"abstractinfo":"研究了HT250铸铁齿轮表面涂镀Ni-W和Ni-Go合金涂层的耐磨损性能.磨损试验结果表明:合金涂层能显著提高铸铁齿轮的耐磨损性能.采用电子显微镜、光学显微镜等对铸铁齿轮表面上的合金涂层的表面形貌、横截面组织、纵截面组织、显微硬度、磨损形貌特征等进行了分析.","authors":[{"authorName":"温芳","id":"e240541e-12e2-4b58-8e21-1108318cda10","originalAuthorName":"温芳"},{"authorName":"黄华梁","id":"c1148be6-5d7d-41c6-95b9-0deb8ef0d921","originalAuthorName":"黄华梁"},{"authorName":"朱江新","id":"e46937d5-7b19-4383-8fad-12a5657d4b35","originalAuthorName":"朱江新"}],"doi":"10.3969/j.issn.1001-3660.2004.03.013","fpage":"32","id":"565d0b00-7293-4c64-a706-27413c53c1c3","issue":"3","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术 "},"keywords":[{"id":"f50a395e-8012-4385-b24d-30d83847deb5","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"},{"id":"5782e7e8-6f5c-45f9-a702-df4f892ae214","keyword":"合金涂层","originalKeyword":"合金涂层"},{"id":"99362ced-191f-4516-abdc-766f853e4399","keyword":"齿轮传动","originalKeyword":"齿轮传动"},{"id":"d6602b02-9b80-4415-a418-3e557dbafabe","keyword":"铸铁","originalKeyword":"铸铁"}],"language":"zh","publisherId":"bmjs200403013","title":"涂镀合金层的铸铁齿轮耐磨损性能的研究","volume":"33","year":"2004"},{"abstractinfo":"通过控制无压埋烧条件制备了85Al2O3/SiC纳米复合陶瓷,重点研究了纳米碳化硅对复合陶瓷耐磨损性能的影响.结果表明,纳米复合陶瓷表现出显著优于基体材料的表面耐磨损特性.SEM分析表明,纳米碳化硅的加入使材料的磨损去除机制发生了改变,由大范围的深层晶粒拔出变为小尺寸的浅层去除和塑性变形.","authors":[{"authorName":"彭珍珍","id":"5ac8827f-c69e-4cbf-9ab2-29a9dd3b3ca1","originalAuthorName":"彭珍珍"},{"authorName":"蔡舒","id":"c997b852-8bcc-402f-9bb3-bee3cd5f71a0","originalAuthorName":"蔡舒"},{"authorName":"吴厚政","id":"0e67e698-e270-4d0a-920f-dd9af82445b1","originalAuthorName":"吴厚政"}],"doi":"","fpage":"61","id":"abadc3b3-0bc7-4e6d-a37c-e0ebe84c0717","issue":"z1","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"3b14deee-dda2-4613-8771-91975976e1c5","keyword":"85Al2O3/SiC纳米复合陶瓷","originalKeyword":"85Al2O3/SiC纳米复合陶瓷"},{"id":"c2063075-827f-4a7e-b38c-6f2fa3d797d6","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"xyjsclygc2006z1015","title":"85Al2O3/SiC纳米复合陶瓷的耐磨损性能研究","volume":"35","year":"2006"},{"abstractinfo":"通过控制无压埋烧条件制备了85Al2O3/SiC纳米复合陶瓷,重点研究了纳米碳化硅对复合陶瓷耐磨损性能的影响.结果表明,纳米复合陶瓷表现出显著优于基体材料的表面耐磨损特性.SEM分析表明,纳米碳化硅的加入使材料的磨损去除机制发生了改变,由大范围的深层晶粒拔出变为小尺寸的浅层去除和塑性变形.","authors":[{"authorName":"彭珍珍","id":"1d31e33e-23be-402d-a481-68c9b316aac6","originalAuthorName":"彭珍珍"},{"authorName":"蔡舒","id":"ed9a9411-d41b-488a-a2a6-b10c1caf1239","originalAuthorName":"蔡舒"},{"authorName":"吴厚政","id":"e53cf332-dfd5-4d33-b32f-76745f6ba8fc","originalAuthorName":"吴厚政"}],"doi":"","fpage":"61","id":"b0f9a7e2-8e4f-4275-822d-94f97db45c31","issue":"z2","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"3989b494-9aa8-41a5-9466-88962b687d20","keyword":"85Al2O3/SiC纳米复合陶瓷","originalKeyword":"85Al2O3/SiC纳米复合陶瓷"},{"id":"2794966f-31db-4587-8132-ff7251bc801b","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"xyjsclygc2006z2015","title":"85Al2O3/SiC纳米复合陶瓷的耐磨损性能研究","volume":"35","year":"2006"},{"abstractinfo":"采用直流电沉积、脉冲电沉积和超声-脉冲电沉积三种方式在45钢表面制备了纳米TiN/Ni复合镀层,分析了复合镀层的组织、显微硬度以及镀层中 TiN 的含量,并对复合镀层的耐磨损性能进行了研究.结果表明:直流电沉积复合镀层的晶粒最粗大,超声-脉冲电沉积复合镀层的晶粒尺寸最细小;直流电沉积复合镀层、脉冲电沉积复合镀层和超声-脉冲电沉积复合镀层的显微硬度以及镀层中TiN的含量依次增大;超声-脉冲电沉积复合镀层具有最佳的耐磨损性能,其磨损量为直流电沉积复合镀层的46%,显微硬度为604.72 HV,镀层中TiN的质量分数为2.27%.","authors":[{"authorName":"吴蒙华","id":"f922e921-dfcb-440f-bd41-6e7faa7f9062","originalAuthorName":"吴蒙华"},{"authorName":"李霖泰","id":"8fd46cac-6a25-4e57-8903-b7bab586cd4e","originalAuthorName":"李霖泰"},{"authorName":"王元刚","id":"da44658d-66fc-4e81-ad85-b8b624fb9986","originalAuthorName":"王元刚"},{"authorName":"王邦国","id":"20592238-9032-4d80-bcd9-a1fff5234462","originalAuthorName":"王邦国"},{"authorName":"段伟","id":"f8309d6f-6d24-4ecd-8281-04a2cf16dff5","originalAuthorName":"段伟"}],"doi":"10.11973/jxgccl201612018","fpage":"78","id":"67667fbc-12cd-4c7f-8a8d-7df236949bf5","issue":"12","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":"e574c549-960b-46d1-acc5-a323b3082c33","keyword":"电沉积","originalKeyword":"电沉积"},{"id":"cad241aa-077b-417c-a3bd-20b82ac14596","keyword":"纳米TiN/Ni复合镀层","originalKeyword":"纳米TiN/Ni复合镀层"},{"id":"01d26a1d-bab6-4e69-a0d4-1fb4336c191b","keyword":"显微硬度","originalKeyword":"显微硬度"},{"id":"f833a730-4b5e-455e-a8fa-9222789104e3","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"jxgccl201612018","title":"不同方式电沉积纳米TiN/Ni复合镀层的组织和耐磨损性能","volume":"40","year":"2016"},{"abstractinfo":"利用射频反应磁控溅射法在45钢基体上制备了氧化铬薄膜.采用XRD测试了薄膜的晶体结构,用Tribo-Indentor纳米力学测试系统得到了薄膜的硬度及微观形貌,在UMT显微力学测试仪上测试了薄膜的耐磨损性能,在此基础上讨论了铬靶溅射功率对薄膜的力学性能和耐磨损性能的影响.结果表明:在射频功率较低的情况下薄膜为Cr2O3结构.随着射频功率的提高,薄膜表面的大颗粒物质增多,硬度下降.射频功率增大时,磨损体积增加,薄膜的耐磨损性能下降.","authors":[{"authorName":"罗飞","id":"19df7eb5-e35a-4565-bda8-b0e9f178e723","originalAuthorName":"罗飞"},{"authorName":"庞晓露","id":"f13fdea6-ee9e-4f2c-8ce1-f5da666bf96c","originalAuthorName":"庞晓露"},{"authorName":"高克玮","id":"a13af375-1804-4793-a30c-8c71dd57274f","originalAuthorName":"高克玮"},{"authorName":"杨会生","id":"17801d99-7564-4d90-9a9c-42c37f12bc20","originalAuthorName":"杨会生"},{"authorName":"王燕斌","id":"961478a8-45f1-487c-97ed-857d06a3b826","originalAuthorName":"王燕斌"}],"doi":"10.3969/j.issn.1001-4381.2007.01.006","fpage":"25","id":"be10b802-3fac-4c9e-b9da-b64c2d549ab2","issue":"1","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"fdd0c7b2-50d8-4473-aaa5-71e7a187dade","keyword":"磁控溅射","originalKeyword":"磁控溅射"},{"id":"4734cf5c-40f9-4335-8562-69a7ef7795b5","keyword":"氧化铬薄膜","originalKeyword":"氧化铬薄膜"},{"id":"9d2d6a97-f854-4b7b-9d03-2d284aea1a24","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"clgc200701006","title":"射频功率对氧化铬薄膜的力学性能和耐磨损性能的影响","volume":"","year":"2007"},{"abstractinfo":"采用多弧离子镀技术,使用Ti-Al-Zr合金靶及Cr单质靶的组合方式,在W18Cr4V高速钢基体上制备TiAlZrCr/(Ti,Al,Zr,Cr)N四元梯度氮化物膜.利用SEM和XRD分析梯度膜的微观组织和结构,使用摩擦磨损试验机研究梯度膜在室温(15℃)和高温(500℃)下的耐磨损特性,并采用SEM观察磨痕形貌.结果表明,在不同沉积偏压下制备的四元梯度膜均具有fcc-NaCl型的TiN结构,其组织致密均匀,呈典型的柱状晶形态.梯度膜的摩擦磨损机理是以塑性变形为主要特征的黏着磨损,并伴有轻微的磨粒磨损.在室温和高温下磨损时的平均摩擦系数分别在0.25~0.30和0.30~0.35之间,且当沉积偏压增加至-200 V时,梯度膜的耐磨损性能实现最优化.","authors":[{"authorName":"赵时璐","id":"ea164e61-3b07-479f-adb2-6bf079ac3066","originalAuthorName":"赵时璐"},{"authorName":"张震","id":"9627b3a3-5a74-42aa-b50b-0a3171e265ea","originalAuthorName":"张震"},{"authorName":"张钧","id":"eb2b2a19-b210-48f9-9b41-eb64556c3ce4","originalAuthorName":"张钧"},{"authorName":"王建明","id":"30d3d09d-30f6-4acf-9704-d6e5425ebd7e","originalAuthorName":"王建明"},{"authorName":"张正贵","id":"6d29b514-3367-46da-87fc-5a09f7ec562f","originalAuthorName":"张正贵"}],"doi":"10.11900/0412.1961.2015.00522","fpage":"747","id":"b2a00ea9-e6e2-43dd-b295-16599e3def16","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":"6a844881-7e69-4e9d-a2fc-654377e86f1b","keyword":"TiAlZrCr/(Ti,Al,Zr,Cr)N梯度膜","originalKeyword":"TiAlZrCr/(Ti,Al,Zr,Cr)N梯度膜"},{"id":"a646b8f3-09f2-45fa-8733-97b9772ddb08","keyword":"多弧离子镀","originalKeyword":"多弧离子镀"},{"id":"b7b560c3-2c6d-4640-9823-d699a2b8bb5d","keyword":"偏压","originalKeyword":"偏压"},{"id":"bd467a33-2430-428b-b414-3cf96cfb731f","keyword":"显微结构","originalKeyword":"显微结构"},{"id":"72a8d321-92dd-42e6-adc0-c8c05ed2e6c5","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"jsxb201606013","title":"多弧离子镀TiAlZrCr/(Ti,Al,Zr,Cr)N梯度膜的微观结构与耐磨损性能","volume":"52","year":"2016"},{"abstractinfo":"以高度抛光的玻璃陶瓷、聚合瓷、氧化锆、纯钛为摩擦副,模拟口腔环境,使用微摩擦磨损实验机进行天然牙釉质和牙本质的摩擦磨损实验.用扫描电镜观察表面形貌、用粗糙度仪测粗糙度、用维氏硬度仪测表面硬度、用电子天平测磨损量,研究了天然牙釉质和牙本质与不同修复材料之间的摩擦磨损性能.结果表明,釉质和牙本质分别与四种材料对磨后的磨损量与对照组均有统计学差异(P<0.05),对磨物的磨损量与四种材料及釉质、牙本质的硬度值呈显著正相关关系.其中牙本质与聚合瓷对磨后的磨损量与牙本质对照组最接近,釉质与玻璃陶瓷对磨后的磨损量与釉质对照组最接近.","authors":[{"authorName":"李晨曦","id":"12b6de09-7c1d-4d76-b64e-0209fa2e0f54","originalAuthorName":"李晨曦"},{"authorName":"梁锐英","id":"ba8bd263-41b1-434f-b02d-4071e4db39a9","originalAuthorName":"梁锐英"},{"authorName":"任婧","id":"ccd2d2d6-7510-4f85-817b-bd73425e330e","originalAuthorName":"任婧"},{"authorName":"王景坤","id":"76588a76-6949-44e6-82bc-85cc0dd6404d","originalAuthorName":"王景坤"},{"authorName":"徐艳丽","id":"7d4836a5-52b3-4678-aa6e-8b3ae369353a","originalAuthorName":"徐艳丽"},{"authorName":"孟贺","id":"4b5ab106-633e-4c70-b6ce-210049f32e99","originalAuthorName":"孟贺"},{"authorName":"孙硕","id":"07cd73aa-3569-44d3-86cf-eef1ea7f7104","originalAuthorName":"孙硕"}],"doi":"10.11901/1005.3093.2015.490","fpage":"489","id":"3f854b63-1c5f-42ed-8686-fdcca35d64d1","issue":"7","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"0660e599-97d1-4de5-a7e9-e06961395f8a","keyword":"口腔修复材料","originalKeyword":"口腔修复材料"},{"id":"950e952b-dfdf-40c2-ba5f-09cb5252a6e7","keyword":"摩擦磨损实验","originalKeyword":"摩擦磨损实验"},{"id":"82aa696d-fecc-42dc-bcb6-fb0de78c5a0d","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"},{"id":"27f2b7ae-d7d7-4d9f-bcc2-8a7156c0cc62","keyword":"釉质","originalKeyword":"釉质"},{"id":"5a1794d0-166c-4e28-91dc-193c4f3962ce","keyword":"牙本质","originalKeyword":"牙本质"}],"language":"zh","publisherId":"clyjxb201607002","title":"不同修复材料与天然牙釉质和牙本质之间的摩擦磨损性能","volume":"30","year":"2016"},{"abstractinfo":"对比研究了新型冷作模具钢SDC55和进口模具钢DC53、SLD及ASSAB88的抗弯曲性能和耐磨损性能.在电子万能试验机上对实验钢的抗弯曲性能进行了测试,并在M-200磨损仪上研究了其耐磨性能.利用超景深三维显微系统研究了实验钢磨损后的磨痕,并对其进行了金相观察.利用JMat-Pro软件对4种实验钢的组织进行了计算.通过对比研究发现,与进口对比钢相比,新型冷作模具钢SDC55的抗弯曲性能最好,并且其耐磨损性能好于SLD钢.","authors":[{"authorName":"邓黎辉","id":"ba442c3f-26df-4961-821d-f8882e565ae3","originalAuthorName":"邓黎辉"},{"authorName":"汪宏斌","id":"f6badd1e-b0a4-4bb2-9047-2a4fe0bd818c","originalAuthorName":"汪宏斌"},{"authorName":"李绍宏","id":"beaf7c39-09c9-4ad6-9863-f9a1e4e84c34","originalAuthorName":"李绍宏"},{"authorName":"梁洋杰","id":"e469f732-00bf-4d32-9155-ee073d8c056e","originalAuthorName":"梁洋杰"},{"authorName":"吴晓春","id":"628a60c8-ee0a-4488-886d-58962e15c282","originalAuthorName":"吴晓春"}],"doi":"10.3969/j.issn.1001-7208.2011.01.002","fpage":"8","id":"8b91779a-99a2-41d8-a14c-b0a2e7699191","issue":"1","journal":{"abbrevTitle":"SHJS","coverImgSrc":"journal/img/cover/SHJS.jpg","id":"59","issnPpub":"1001-7208","publisherId":"SHJS","title":"上海金属"},"keywords":[{"id":"9266ddb9-0209-4b30-b32f-38b74fec19c4","keyword":"SDC55钢","originalKeyword":"SDC55钢"},{"id":"853b778f-11fb-4daf-b463-93c75b866266","keyword":"冷作模具钢","originalKeyword":"冷作模具钢"},{"id":"a6873585-4a37-4ed6-a027-590be84e1d96","keyword":"抗弯曲性能","originalKeyword":"抗弯曲性能"},{"id":"a9047090-f228-4cb0-b2b7-63dd88c29a88","keyword":"耐磨损性能","originalKeyword":"耐磨损性能"}],"language":"zh","publisherId":"shjs201101002","title":"新型冷作模具钢SDC55的性能研究","volume":"33","year":"2011"}],"totalpage":8838,"totalrecord":88380}