{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"针对偶联改性玄武岩纤维增强沥青胶浆现有研究现状和不足,采用硅烷偶联剂对玄武岩纤维进行表面改性,制备了不同粉胶比和不同纤维掺量的偶联改性玄武岩纤维增强沥青胶浆,通过低温延度、弹性恢复、锥入度及软化点试验,研究了沥青胶浆低、中、高温<span style=\"color:red\">性能</span>,并对偶联改性玄武岩纤维增强沥青胶浆机理进行分析.研究表明,偶联改性玄武岩纤维与沥青胶浆润湿性好、黏附性强,表面沥青胶浆膜厚度大,纤维力学特性发挥显著,粉胶比在0.8～1.0、纤维掺量在0.4％ ～0.6％之间时,沥青胶浆抗拉强度、抗剪强度、弹性恢复率及软化点明显提高,沥青胶浆低温抗裂、高温抗剪切、疲劳<span style=\"color:red\">性能</span>及自愈能力得到较大改善,研究成果对矿物纤维复合材料在道路工程中的推广与应用具有一定的实际意义.","authors":[{"authorName":"向宇","id":"dcfb061b-f337-4b9c-a13f-e5beed54b827","originalAuthorName":"向宇"},{"authorName":"刘朝晖","id":"56e32253-dff1-440d-b768-4f79307d2ae9","originalAuthorName":"刘朝晖"},{"authorName":"柳力","id":"873fb803-b79a-4c96-b880-79a1884cfa05","originalAuthorName":"柳力"},{"authorName":"李盛","id":"94ef61c5-3780-4708-9405-12b336596c86","originalAuthorName":"李盛"}],"doi":"","fpage":"5","id":"6ee268f7-243e-4c2a-bf70-c0ca753df15b","issue":"5","journal":{"abbrevTitle":"BLGFHCL","coverImgSrc":"journal/img/cover/BLGFHCL.jpg","id":"6","issnPpub":"1003-0999","publisherId":"BLGFHCL","title":"玻璃钢/复合材料"},"keywords":[{"id":"14e1fdde-b6e5-4ec8-ae3d-0608d6579279","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"01b671e6-686a-4e4f-9ffa-368cf2a5184b","keyword":"硅烷偶联剂","originalKeyword":"硅烷偶联剂"},{"id":"661f6ba1-cacd-4fe3-9681-1573efb88a7e","keyword":"玄武岩纤维","originalKeyword":"玄武岩纤维"},{"id":"5f610245-3b32-4503-a4fa-078dd5fdebcb","keyword":"沥青胶浆","originalKeyword":"沥青胶浆"},{"id":"30b71946-0ca5-4207-9738-1d33546ce399","keyword":"<span style=\"color:red\">常规</span><span style=\"color:red\">性能</span>","originalKeyword":"常规性能"},{"id":"ae16ccf6-7a73-4ba8-8285-14d6278c8a3f","keyword":"增强机理","originalKeyword":"增强机理"}],"language":"zh","publisherId":"blgfhcl201605001","title":"偶联改性玄武岩纤维增强沥青胶浆<span style=\"color:red\">性能</span>及机理研究","volume":"","year":"2016"},{"abstractinfo":"本文对某高<span style=\"color:red\">性能</span><span style=\"color:red\">常规</span>涡轮开展了对转改型研究.首先对该<span style=\"color:red\">常规</span>涡轮进行基本分析,详细探讨了将其改进为1+1 及1+1/2对转涡轮(无低压涡轮导叶)时遇到的关键问题,并给出了一些解决问题的方案.研究表明,1+1对转方案现实可行,1+1/2对转方案将很难实现.在方案研究的基础之上,本文进行了保留过渡段的1+1对转涡轮详细设计并采用三维黏性程序对其<span style=\"color:red\">性能</span>进行了初步的分析.","authors":[{"authorName":"张磊","id":"0344dfc8-62a1-426a-9d8c-b413ebb2616b","originalAuthorName":"张磊"},{"authorName":"王会社","id":"d129f7f9-8f73-492d-a2e9-910e4f4cbf3f","originalAuthorName":"王会社"},{"authorName":"王正明","id":"42fa4dd7-912f-4bac-9171-1707f3f0bf0b","originalAuthorName":"王正明"},{"authorName":"黄家骅","id":"c8b314e3-960d-4321-81a6-947fcb527987","originalAuthorName":"黄家骅"},{"authorName":"徐建中","id":"ff1ac493-ae09-4b02-a70b-0180e5e654b1","originalAuthorName":"徐建中"}],"doi":"","fpage":"218","id":"9c4f1c73-a394-4db6-b1ea-6c7817cbf0fa","issue":"2","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":"b773c8bd-a244-41d8-979c-645bae4fca4d","keyword":"对转涡轮","originalKeyword":"对转涡轮"},{"id":"ba65c976-e4ab-4f7f-b332-ce8e2755cc53","keyword":"改型","originalKeyword":"改型"},{"id":"6b531a76-1064-43fc-b036-7c0ee4f0bea6","keyword":"设计","originalKeyword":"设计"},{"id":"f4942ce7-005c-4731-b554-3b58debb52d3","keyword":"分析","originalKeyword":"分析"}],"language":"zh","publisherId":"gcrwlxb201002010","title":"某型高<span style=\"color:red\">性能</span><span style=\"color:red\">常规</span>涡轮对转改型研究","volume":"31","year":"2010"},{"abstractinfo":"拉力试验机、电阻率测量装置和扫描电子显微镜是表征合金材料<span style=\"color:red\">性能</span>的<span style=\"color:red\">常规</span>测试设备。简要介绍了这些设备的测试原理以及在Pd-18Ir合金丝材中的应用。","authors":[{"authorName":"吴庆伟","id":"522a5d61-ae9c-4849-bf63-e5bc98a85e40","originalAuthorName":"吴庆伟"},{"authorName":"柳青","id":"5cc6e86d-0693-4e54-9c57-64cade93c6bc","originalAuthorName":"柳青"},{"authorName":"刘莉","id":"ca9097d1-98d5-497a-a5dc-e687b941b89b","originalAuthorName":"刘莉"},{"authorName":"高勤琴","id":"728f1d58-537d-4b4f-bec4-17a6776e0ac7","originalAuthorName":"高勤琴"},{"authorName":"毛端","id":"4be73211-cc5b-447e-a8a8-00d4e780eacd","originalAuthorName":"毛端"},{"authorName":"陈雯","id":"174d65d1-eb00-474b-a2f3-edfbaaec118e","originalAuthorName":"陈雯"},{"authorName":"马丽华","id":"8da64905-517d-4cd0-b3f9-613fd57dce88","originalAuthorName":"马丽华"},{"authorName":"陈国华","id":"2edc6051-8041-422c-b6fd-64dfa0cb2bad","originalAuthorName":"陈国华"},{"authorName":"赖丽君","id":"8b0e1414-8e4d-491e-8b18-6ce38a0382b4","originalAuthorName":"赖丽君"}],"doi":"","fpage":"171","id":"6b4224bc-a7ad-4527-9c34-969ddd8e9a3b","issue":"z1","journal":{"abbrevTitle":"GJS","coverImgSrc":"journal/img/cover/GJS.jpg","id":"38","issnPpub":"1004-0676","publisherId":"GJS","title":"贵金属"},"keywords":[{"id":"b0d6650e-8550-42e8-b325-7e0dae64d09c","keyword":"测试设备","originalKeyword":"测试设备"},{"id":"9e8b01ea-84b6-4438-9b12-bbd9e3581572","keyword":"Pd-18Ir合金丝材","originalKeyword":"Pd-18Ir合金丝材"},{"id":"7c647201-c788-4014-a30a-fa7fb1e218eb","keyword":"<span style=\"color:red\">性能</span>","originalKeyword":"性能"}],"language":"zh","publisherId":"gjs2014z1034","title":"<span style=\"color:red\">常规</span>物理<span style=\"color:red\">性能</span>测试设备在PdIr合金丝材中的应用","volume":"","year":"2014"},{"abstractinfo":"对相同成分的550 MPa级高强韧船板钢进行了<span style=\"color:red\">常规</span>轧制和控制轧制，对比了轧后试验钢的显微组织和力学<span style=\"color:red\">性能</span>.结果表明：两种工艺轧制试验钢的组织均为铁素体＋M/A 岛；控制轧制试验钢的晶粒更细小，铁素体含量更高；两种工艺轧制试验钢的强度和伸长率相差不大，但控制轧制试验钢在－40℃的低温冲击功更高，为<span style=\"color:red\">常规</span>轧制试验钢的2．4倍.","authors":[{"authorName":"何亚元","id":"5c0d2000-b833-4f28-b0be-2b2f3994f72e","originalAuthorName":"何亚元"},{"authorName":"严翔","id":"034c1fcd-f201-441d-b0e4-2e7b78f27782","originalAuthorName":"严翔"},{"authorName":"朱丛茂","id":"904d56f3-8547-493c-b792-ef1b0bbd0293","originalAuthorName":"朱丛茂"},{"authorName":"周千学","id":"036744c8-462b-465b-a746-b2fcc062c36b","originalAuthorName":"周千学"}],"doi":"10.11973/jxgccl201607005","fpage":"24","id":"4f0c4e36-2d68-464b-a7f4-506a19d07da2","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":"2da1fdc5-0711-4ec3-9c2d-be3d4d6f62c6","keyword":"<span style=\"color:red\">常规</span>轧制","originalKeyword":"常规轧制"},{"id":"b21238ad-3e73-4a94-968b-676c04e3d00b","keyword":"控制轧制","originalKeyword":"控制轧制"},{"id":"f333a9f1-993c-44e8-bdd2-69305d848944","keyword":"显微组织","originalKeyword":"显微组织"},{"id":"d4cfbbaa-fce2-4dab-b3b0-1883a3a1decf","keyword":"低温冲击韧性","originalKeyword":"低温冲击韧性"}],"language":"zh","publisherId":"jxgccl201607005","title":"<span style=\"color:red\">常规</span>轧制和控制轧制高强韧船板钢组织与力学<span style=\"color:red\">性能</span>的对比","volume":"40","year":"2016"},{"abstractinfo":"纳米陶瓷具有高韧性和超塑性等独特的<span style=\"color:red\">性能</span>,用于制备涂层可极大地提高其耐冲蚀<span style=\"color:red\">性能</span>.以<span style=\"color:red\">常规</span>和纳米团聚体Al2O3-13%TiO2(质量分数)陶瓷粉末为原料,采用等离子喷涂工艺在TiAl合金表面制备了2种陶瓷涂层.比较了2种涂层的微观结构、结合强度和抗冲蚀<span style=\"color:red\">性能</span>,探讨了涂层的冲蚀破坏机理.结果表明:<span style=\"color:red\">常规</span>涂层呈典型的层状堆积特征,有一定的孔隙且分布有微裂纹;纳米结构涂层由部分熔化区以及完全熔化区组成,呈双相组织结构;<span style=\"color:red\">常规</span>陶瓷涂层表现为典型的脆性冲蚀特性,纳米结构陶瓷涂层呈明显的脆性冲蚀特性,同时有一定程度的塑性冲蚀特征,具有较好的结合强度及抗冲蚀<span style=\"color:red\">性能</span>.2种等离子喷涂层的冲蚀磨损都以片层状脱落为主,同时有一定程度的脆性陶瓷颗粒破碎.","authors":[{"authorName":"王东生","id":"eedaca4d-57b4-4ad8-a8e5-65ba4b0c126c","originalAuthorName":"王东生"},{"authorName":"田宗军","id":"b9a61f59-011b-4632-9950-ae7178fdb0a7","originalAuthorName":"田宗军"},{"authorName":"张少伍","id":"da0c0b17-614e-4535-81a1-b6c4da21c787","originalAuthorName":"张少伍"},{"authorName":"曲光","id":"0ef05cc9-613b-4d14-bdf8-d7b1d0ce0606","originalAuthorName":"曲光"},{"authorName":"沈理达","id":"ab3c6a4d-a12c-4451-a60a-7235369cffa8","originalAuthorName":"沈理达"},{"authorName":"黄因慧","id":"0b60c9b8-195d-4a8e-b9b1-97f1a9879568","originalAuthorName":"黄因慧"}],"doi":"","fpage":"67","id":"2d98a15e-a0ea-4088-8c51-b955c9585c5a","issue":"1","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"deeda2df-7451-416e-acb2-fcc28019f420","keyword":"等离子喷涂","originalKeyword":"等离子喷涂"},{"id":"1b605fa4-86a4-4831-837f-e44948ad6ad9","keyword":"陶瓷涂层","originalKeyword":"陶瓷涂层"},{"id":"bfee1ef0-aa03-418f-a94a-62d908c66e54","keyword":"纳米结构","originalKeyword":"纳米结构"},{"id":"da9fb47a-389c-4962-9493-d429d02ae8e7","keyword":"TiAl合金","originalKeyword":"TiAl合金"},{"id":"04560a91-1332-493f-9c26-eb4495d030be","keyword":"抗冲蚀<span style=\"color:red\">性能</span>","originalKeyword":"抗冲蚀性能"}],"language":"zh","publisherId":"clbh201101021","title":"<span style=\"color:red\">常规</span>和纳米陶瓷等离子喷涂层抗冲蚀<span style=\"color:red\">性能</span>的对比","volume":"44","year":"2011"},{"abstractinfo":"采用不同于桐油酸酐胶黏剂且具有较高热变形温度的黏合剂制备了JF5440-1G高机械强度多胶粉云母带，对该云母带的<span style=\"color:red\">常规</span><span style=\"color:red\">性能</span>进行了研究。结果表明，该云母带固化后在155℃下的弯曲强度不低于100 MPa，在50~120℃其导热系数为0.31~0.32 W/(m·K)，各项<span style=\"color:red\">性能</span>均达到IEC 60371-3-6技术指标要求。","authors":[{"authorName":"黄超","id":"a6a0c8f9-71e5-4f1d-b0b5-27f45da2c8a7","originalAuthorName":"黄超"},{"authorName":"饶保林","id":"de1fd131-5a01-4287-9dd7-2c96e3fb9476","originalAuthorName":"饶保林"},{"authorName":"夏宇","id":"27164c3d-b80a-458c-bd27-1a67d51232fd","originalAuthorName":"夏宇"},{"authorName":"陆春","id":"4761b939-377d-4cf2-972f-8745d8fcd3ef","originalAuthorName":"陆春"},{"authorName":"虞锦洪","id":"4275fd9e-f912-4890-aae4-b6c900272882","originalAuthorName":"虞锦洪"},{"authorName":"凌敏","id":"7a41b7b3-6f19-4fbf-a20f-ce5e62256821","originalAuthorName":"凌敏"}],"doi":"","fpage":"29","id":"39d67531-8845-43c0-aebb-c6da30bf1dad","issue":"3","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"6deb5e8d-ebad-417a-b2ae-059d5d793b9b","keyword":"多胶云母带","originalKeyword":"多胶云母带"},{"id":"863d0690-7da9-4ca8-9842-8454e1f9f1ba","keyword":"环氧黏合剂","originalKeyword":"环氧黏合剂"},{"id":"dcfa6baf-373c-4080-a844-57f4c2f50c07","keyword":"高压电机","originalKeyword":"高压电机"},{"id":"a9e03ebc-1f03-4865-8e89-0af4cb0d9884","keyword":"主绝缘","originalKeyword":"主绝缘"}],"language":"zh","publisherId":"jycltx201503007","title":"高机械强度多胶粉云母带（Ⅰ）--<span style=\"color:red\">常规</span><span style=\"color:red\">性能</span>研究","volume":"","year":"2015"},{"abstractinfo":"采用<span style=\"color:red\">常规</span>凝固技术制备了Mg-45Zn-xY(x=1.0,4.0,5.5,8.0,质量分数,％)合金.利用SEM、EDS、OM、TEM、XRD、DSC和硬度测试技术研究了Y对Mg-45Zn-xY系合金组织及<span style=\"color:red\">性能</span>的影响,同时对准晶相(Ⅰ-phase)的形成机制进行了分析.结果表明:合金组织主要由a-Mg颗粒或枝晶、花瓣状的Mg3Zn6Y准晶相、层片状的(Ⅰ-phase+α-Mg)共晶组织以及Mg7Zn3相组成;准晶相形貌、含量及分布与Y含量密切相关,随着Y含量的增加,花瓣状准晶相含量逐渐增加,当Y含量为5.5％时,花瓣状准晶相含量最多,合金的硬度达到最大值,HB为1557 MPa,当Y含量为8.0％时,合金中的花瓣状准晶相消失;准晶以层片状共晶组织和花瓣状形式存在,花瓣状的特殊形貌是正二十面体沿五次轴方向生长的结果.","authors":[{"authorName":"杨玲","id":"4bd62709-de75-4f59-a651-f61183c31c8a","originalAuthorName":"杨玲"},{"authorName":"赵宇宏","id":"c089583e-23b0-4135-ab0f-8b1834371466","originalAuthorName":"赵宇宏"},{"authorName":"侯华","id":"c70be90e-ec09-47d0-8dd5-a717222492a4","originalAuthorName":"侯华"},{"authorName":"杨晓敏","id":"0ce0f582-9231-47c3-b618-b1860166cab2","originalAuthorName":"杨晓敏"}],"doi":"","fpage":"1754","id":"64b8485a-6b1b-4e17-a857-6c77799f52c6","issue":"7","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":"211db860-e8e9-4ce1-815d-c86faac2c23e","keyword":"Mg-Zn-Y合金","originalKeyword":"Mg-Zn-Y合金"},{"id":"840a32c8-63f2-4a08-b0cd-6d25fc6d5c89","keyword":"<span style=\"color:red\">常规</span>凝固","originalKeyword":"常规凝固"},{"id":"8f827f9d-d139-47fb-9320-8a71f6f41982","keyword":"准晶","originalKeyword":"准晶"},{"id":"7bf498af-ef3f-47d6-9c68-96a5591dc69f","keyword":"微观组织","originalKeyword":"微观组织"},{"id":"a71105eb-8a3e-4abf-b328-621b6b6286da","keyword":"<span style=\"color:red\">性能</span>","originalKeyword":"性能"}],"language":"zh","publisherId":"xyjsclygc201407043","title":"Y对<span style=\"color:red\">常规</span>凝固Mg-Zn-Y合金组织和<span style=\"color:red\">性能</span>的影响","volume":"43","year":"2014"},{"abstractinfo":"在室温下对处于<span style=\"color:red\">常规</span>固溶处理态的2024高强铝合金成功实现了等效应变为0.5的等通道转角挤压(ECAP),将形变强化、时效强化和结构细化强化三者有机组合,制备出超高强铝合金,其硬度、屈服强度、伸长率分别高达1770MPa,550 MPa和14%.研究结果首次证明,固溶处理+室温ECAP+时效是提升<span style=\"color:red\">常规</span>高强铝合金的强度、制取超高强铝合金的一条有效途径.","authors":[{"authorName":"许晓静","id":"41dd66af-f404-4add-80ed-8a2e9916e0bc","originalAuthorName":"许晓静"},{"authorName":"张雪峰","id":"aba13244-b406-4511-8eb8-1d4cbc9b2210","originalAuthorName":"张雪峰"},{"authorName":"曹进琪","id":"5d8cb740-e855-46c3-8a47-ffeae87e51fb","originalAuthorName":"曹进琪"},{"authorName":"汪建敏","id":"c6f44b38-063b-4cee-9c6d-8546e6193bfb","originalAuthorName":"汪建敏"},{"authorName":"蒋维平","id":"139f49ce-1c8a-44fb-91aa-64f12705e968","originalAuthorName":"蒋维平"}],"doi":"","fpage":"395","id":"333f806f-b782-4675-8dfb-6e095b409408","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":"069759e4-0d4e-45cc-9169-746554b83cfe","keyword":"超高强铝合金","originalKeyword":"超高强铝合金"},{"id":"adf37e0e-76da-47ba-88dd-c29a21b7dcfd","keyword":"ECAP","originalKeyword":"ECAP"},{"id":"ad332d9a-c82a-4954-b8b3-8161489f6f57","keyword":"力学<span style=\"color:red\">性能</span>","originalKeyword":"力学性能"},{"id":"b16ac61a-89cb-4cae-8160-bcad9f41286f","keyword":"组织结构","originalKeyword":"组织结构"}],"language":"zh","publisherId":"xyjsclygc2006z2096","title":"<span style=\"color:red\">常规</span>固溶态2024铝合金ECAP加工后的拉伸<span style=\"color:red\">性能</span>","volume":"35","year":"2006"},{"abstractinfo":"在室温下对处于<span style=\"color:red\">常规</span>固溶处理态的2024高强铝合金成功实现了等效应变为0.5的等通道转角挤压(ECAP),将形变强化、时效强化和结构细化强化三者有机组合,制备出超高强铝合金,其硬度、屈服强度、伸长率分别高达1770MPa,550 MPa和14%.研究结果首次证明,固溶处理+室温ECAP+时效是提升<span style=\"color:red\">常规</span>高强铝合金的强度、制取超高强铝合金的一条有效途径.","authors":[{"authorName":"许晓静","id":"37c46d1f-faa9-42d5-ae2d-fde9d1272f31","originalAuthorName":"许晓静"},{"authorName":"张雪峰","id":"0ca4e7a7-e88c-4d0b-922a-d4a3588134d7","originalAuthorName":"张雪峰"},{"authorName":"曹进琪","id":"0b45ee2e-07c2-4dad-8394-cd978b0caa40","originalAuthorName":"曹进琪"},{"authorName":"汪建敏","id":"fca68d96-31ec-418d-a9b3-995837f9950b","originalAuthorName":"汪建敏"},{"authorName":"蒋维平","id":"747e0f93-2cfc-4d1e-ae9c-6e23b363b52a","originalAuthorName":"蒋维平"}],"doi":"","fpage":"395","id":"43f73686-887e-4c92-8d2f-a5f3e4765273","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":"85cd46a8-e77a-479a-84a6-14b0f8f2c7af","keyword":"超高强铝合金","originalKeyword":"超高强铝合金"},{"id":"1d8b0ed0-d06f-4a28-b085-89ae953ab56d","keyword":"ECAP","originalKeyword":"ECAP"},{"id":"f4d9fb8d-d9c7-4fdf-a6eb-1fcc46eae45b","keyword":"力学<span style=\"color:red\">性能</span>","originalKeyword":"力学性能"},{"id":"da3ff3e1-fa03-46c1-8c33-c42ec01499e5","keyword":"组织结构","originalKeyword":"组织结构"}],"language":"zh","publisherId":"xyjsclygc2006z1096","title":"<span style=\"color:red\">常规</span>固溶态2024铝合金ECAP加工后的拉伸<span style=\"color:red\">性能</span>","volume":"35","year":"2006"},{"abstractinfo":"通过试验研究,提出了一种新型的不锈钢着色工艺--<span style=\"color:red\">常规</span>脉冲伏安法着黑色,即在无铬的硼酸缓冲液中,通过加入添加剂(自配)降低着色温度,进行电化学着色.测试了着色样品在3.5%NaCl溶液中的耐蚀性.采用扫描探针显微镜(SPM)观测了着色膜封膜前后的形貌.结果表明,<span style=\"color:red\">常规</span>脉冲伏安法着色工艺是一种低温、无铬的不锈钢着色的新型环保工艺,所得到的不锈钢着色膜光亮美观、呈黑色,同时具有优良的耐磨性和耐热性.","authors":[{"authorName":"张述林","id":"2111a222-3918-44a3-aea7-8db15e28f6ab","originalAuthorName":"张述林"},{"authorName":"王晓波","id":"582376e7-817e-4109-a393-3dffd47e7ee6","originalAuthorName":"王晓波"},{"authorName":"陈世波","id":"e236e724-c3a1-466b-addd-2537114d55bf","originalAuthorName":"陈世波"}],"doi":"10.3969/j.issn.1005-748X.2007.03.005","fpage":"123","id":"bad181d2-26bf-41b0-98ff-8c91560eefe0","issue":"3","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"da76b511-c2d5-48ed-a6dd-372f8b29f12d","keyword":"不锈钢","originalKeyword":"不锈钢"},{"id":"9eeca966-c29e-40bf-85b4-6771e4c73bad","keyword":"<span style=\"color:red\">常规</span>脉冲伏安法","originalKeyword":"常规脉冲伏安法"},{"id":"904e8aef-5123-4550-a320-8f7a3eb7ef04","keyword":"黑色","originalKeyword":"黑色"},{"id":"3bcad21c-37a9-4c0c-995b-65f92c72ac29","keyword":"环保","originalKeyword":"环保"}],"language":"zh","publisherId":"fsyfh200703005","title":"<span style=\"color:red\">常规</span>脉冲伏安法制备黑色不锈钢及<span style=\"color:red\">性能</span>测试","volume":"28","year":"2007"}],"totalpage":8820,"totalrecord":88199}