{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"以合成的水性有机硅改性硅溶胶为基料,在铝合金表面制备了一种具有良好理化性能的不燃有机-无机复合涂层.通过对底涂层附着力、耐冲击性以及涂层表面形貌的对比,确定底层涂料的颜基比(P/B)为1 :1~1.5:1时,底涂层具有良好的理化性能,制备过程中不易产生细裂纹.SEM观察形成的底涂层致密性差,喷涂纳米面漆后涂层平整,致密.EDS分析表明底涂层的厚度在30μm左右,其中存在5-10μm的过渡层.火焰燃烧测试表明涂层(底涂层+面层)遇明火高温不燃、不脱落、无炭化,而是形成一种釉状层与铝合金基体牢固地结合在一起;XRD分析证明燃烧前后涂层材料主要物相没有发生明显改变.除耐沸水性、耐高温性外,涂层的理化性能按照国家标准GB 12441-2005检测,结果表明涂层具有良好的理化性能,能够满足铝合金表面高装饰、高防护的性能要求.","authors":[{"authorName":"崔学军","id":"3ace22ca-5bab-41d0-a9c7-0511e7f01fcf","originalAuthorName":"崔学军"},{"authorName":"李国军","id":"beafa774-37a3-49f8-bbec-90a88eb33c2e","originalAuthorName":"李国军"},{"authorName":"董洪亮","id":"71b6576a-0d10-4ce5-83a1-6e31e3314156","originalAuthorName":"董洪亮"},{"authorName":"任瑞铭","id":"344d5a50-61e8-4870-89fb-ab5665f2629f","originalAuthorName":"任瑞铭"}],"doi":"","fpage":"704","id":"031c04c6-9826-4917-a02c-6f4332f31390","issue":"5","journal":{"abbrevTitle":"CLKXYGCXB","coverImgSrc":"journal/img/cover/CLKXYGCXB.jpg","id":"13","issnPpub":"1673-2812","publisherId":"CLKXYGCXB","title":"材料科学与工程学报"},"keywords":[{"id":"fb6d2172-9f63-4cb0-b554-2d8021a5ac27","keyword":"有机-无机","originalKeyword":"有机-无机"},{"id":"d82673d8-71a0-45e8-ae21-45008b698439","keyword":"改性硅溶胶","originalKeyword":"改性硅溶胶"},{"id":"ebf03d75-011d-421b-9f3b-8e4c97f55a71","keyword":"不燃涂层","originalKeyword":"不燃涂层"},{"id":"ecf93df8-9d0b-4465-99d1-da860d527120","keyword":"铝合金","originalKeyword":"铝合金"},{"id":"19047c68-9a7d-4178-8974-508933271169","keyword":"理化性能","originalKeyword":"理化性能"}],"language":"zh","publisherId":"clkxygc200905014","title":"铝合金表面不燃有机-无机复合涂层的制备与表征","volume":"27","year":"2009"},{"abstractinfo":"采用爆炸喷涂工艺制备了CoCrAlYTa涂层,借助SEM,EDS,显微硬度分析和结合强度测试等手段研究了氧燃充枪比对所制备涂层组织结构和性能的影响.结果表明,随着氧燃充枪比的增加,爆轰温度和爆轰速率不断提高,使涂层由均匀结构向层状结构转变,涂层的孔隙率不断降低;涂层的显微硬度、结合强度以及弯曲结合力则随氧燃充枪比的增加不断提高.","authors":[{"authorName":"高俊国","id":"576bda8d-de78-4fb3-9b96-dc5c8db06915","originalAuthorName":"高俊国"},{"authorName":"陆峰","id":"03be080e-abfc-49ec-9c1e-88ccf66da9bc","originalAuthorName":"陆峰"},{"authorName":"汤智慧","id":"db56919a-80cc-45c9-98b2-bb751aaa2793","originalAuthorName":"汤智慧"},{"authorName":"王长亮","id":"5915f861-ce86-4113-9607-4487222c9f9d","originalAuthorName":"王长亮"},{"authorName":"郭孟秋","id":"f6d1aaf3-9f5c-41ed-bd75-99032723980d","originalAuthorName":"郭孟秋"},{"authorName":"崔永静","id":"42819688-bdc6-4d1b-9cd8-5eebe595e0c6","originalAuthorName":"崔永静"}],"doi":"10.3969/j.issn.1005-5053.2013.2.006","fpage":"29","id":"0100879b-2325-45e1-bfa9-fb13020e8fbf","issue":"2","journal":{"abbrevTitle":"HKCLXB","coverImgSrc":"journal/img/cover/HKCLXB.jpg","id":"41","issnPpub":"1005-5053","publisherId":"HKCLXB","title":"航空材料学报"},"keywords":[{"id":"9c2f80b7-7259-4d44-9a4b-32724d8af2d9","keyword":"CoCrAlYTa涂层","originalKeyword":"CoCrAlYTa涂层"},{"id":"fb707204-41ea-476b-a8e2-1b9ab1859657","keyword":"爆炸喷涂","originalKeyword":"爆炸喷涂"},{"id":"c5db9b48-7120-4276-a534-eb1ee3fe4f8f","keyword":"氧燃充枪比","originalKeyword":"氧燃充枪比"},{"id":"60830f3e-52a4-4c8b-a98d-41414b5318d8","keyword":"组织","originalKeyword":"组织"},{"id":"30040f1d-7904-47c9-9bb7-6f8846ecad28","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"hkclxb201302006","title":"氧燃充枪比对爆炸喷涂CoCrAlYTa涂层组织和性能的影响","volume":"33","year":"2013"},{"abstractinfo":"采用爆炸喷涂工艺制备了CoCrAlYTa涂层,借助SEM,EDS,XRD和高温氧化实验研究了氧燃充枪比对涂层组织结构及抗氧化性能的影响.结果表明:随着氧燃充枪比的增加,爆轰温度和爆轰速率不断提高,使涂层由均匀结构向层状结构转变,涂层的孔隙率不断降低;而涂层越致密,氧化过程中涂层表面越能尽早形成连续的氧化膜,使得涂层的抛物线速率常数kp下降,从而降低形成铝氧化物的临界浓度,促进Al元素的选择性氧化,进一步阻碍氧向涂层内部的扩散,使涂层的抗氧化性能随氧燃充枪比的增加而不断增强.","authors":[{"authorName":"高俊国","id":"7c382b04-165c-4616-87fc-d7a28f36174d","originalAuthorName":"高俊国"},{"authorName":"陆峰","id":"9ef78f0c-49f3-4a49-be0f-9ffab0d4f441","originalAuthorName":"陆峰"},{"authorName":"王长亮","id":"15b2d601-2f9a-4e99-bbf5-95a46bc0d7c8","originalAuthorName":"王长亮"},{"authorName":"郭孟秋","id":"31fc42bc-ef70-4db5-b197-ba729318c2d6","originalAuthorName":"郭孟秋"},{"authorName":"崔永静","id":"3af597dc-85ac-403b-9423-349b8f18bc56","originalAuthorName":"崔永静"}],"doi":"10.3969/j.issn.1001-4381.2013.04.006","fpage":"28","id":"b06b4756-a999-4058-89bf-0fb09bb1c112","issue":"4","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"3ac484c6-6323-4627-85f9-ab5f268caa9f","keyword":"氧燃充枪比","originalKeyword":"氧燃充枪比"},{"id":"33a42e23-f7bb-4fae-8ad0-86fd1a77e913","keyword":"爆炸喷涂","originalKeyword":"爆炸喷涂"},{"id":"153f06c1-8fe7-4089-9efe-18f373a09483","keyword":"CoCrAlYTa涂层","originalKeyword":"CoCrAlYTa涂层"},{"id":"07c23d67-a07a-46a4-bde6-2eeba4f19432","keyword":"抗氧化性能","originalKeyword":"抗氧化性能"}],"language":"zh","publisherId":"clgc201304006","title":"氧燃充枪比对爆炸喷涂CoCrAlYTa涂层抗氧化性能的影响","volume":"","year":"2013"},{"abstractinfo":"通过优化爆炸喷涂工艺制备硬度高、结构均匀致密的碳化钨涂层,用扫描电子显微镜(SEM)观察喷涂粉末的形貌、用显微硬度计测试涂层的维氏显微硬度、用光学显微镜、X射线衍射(XRD)和能谱仪(EDS)观察分析涂层的结构组成。结果表明:提高氧燃比,涂层的硬度和结合强度先增后降;孔隙率则先降后增。氧燃比较低,粒子飞行速率低和熔融不足是涂层致密性和力学性能下降的主要原因;氧燃比过高,粒子脱碳和黏结相在冷却过程中收缩不均匀是影响涂层结构和性能的决定因素。氧燃比为1.15时可有效减少涂层的氧化和脱碳,涂层的综合性能最优;截面维氏显微硬度HV0.3达到1178kg·mm-2、孔隙率为0.86%,涂层与基材间的结合强度达到152MPa。","authors":[{"authorName":"赵立英","id":"4a10d8a0-95dc-4308-a2f5-bd7961f2787b","originalAuthorName":"赵立英"},{"authorName":"刘平安","id":"93e71f33-0a83-4720-9d06-765568e9a4cb","originalAuthorName":"刘平安"}],"categoryName":"材料与工艺","doi":"10.11868/j.issn.1001-4381.2016.06.008","fpage":"50","id":"45a3139c-4058-41c2-85a2-28b94b72530a","issue":"6","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"e9e92c82-6d3f-4a48-bb1a-02f7e334b2ca","keyword":"氧燃比","originalKeyword":"氧燃比"},{"id":"a4c6a51f-4343-4c80-8b4c-d9fc2ccdc42d","keyword":"爆炸喷涂","originalKeyword":"爆炸喷涂"},{"id":"42e44834-f4de-46a5-8daa-7ec81db7cfd2","keyword":"碳化钨涂层","originalKeyword":"碳化钨涂层"},{"id":"361ba019-6b7f-47f0-98dc-4ca73dc6d0cd","keyword":"维氏显微硬度","originalKeyword":"维氏显微硬度"},{"id":"400c9d01-0cfa-4ac4-8ae6-0bfa5e2e18cf","keyword":"孔隙率","originalKeyword":"孔隙率"}],"language":"zh","publisherId":"clgc-44-06-50","title":"氧燃比对爆炸喷涂碳化钨涂层结构和性能的影响","volume":"44","year":"2016"},{"abstractinfo":"通过优化爆炸喷涂工艺制备硬度高、结构均匀致密的碳化钨涂层,用扫描电子显微镜(SEM)观察喷涂粉末的形貌、用显微硬度计测试涂层的维氏显微硬度、用光学显微镜、X射线衍射(XRD)和能谱仪(EDS)观察分析涂层的结构组成.结果表明:提高氧燃比,涂层的硬度和结合强度先增后降;孔隙率则先降后增.氧燃比较低,粒子飞行速率低和熔融不足是涂层致密性和力学性能下降的主要原因;氧燃比过高,粒子脱碳和黏结相在冷却过程中收缩不均匀是影响涂层结构和性能的决定因素.氧燃比为1.15时可有效减少涂层的氧化和脱碳,涂层的综合性能最优;截面维氏显微硬度HV0.3达到1178kg·mm-2、孔隙率为0.86%,涂层与基材间的结合强度达到152MPa.","authors":[{"authorName":"赵立英","id":"2b3246e0-8950-43f3-9af2-4dab5a60fcf1","originalAuthorName":"赵立英"},{"authorName":"刘平安","id":"5c010842-93d3-4da5-913b-e7f66cd057bf","originalAuthorName":"刘平安"}],"doi":"10.11868/j.issn.1001-4381.2016.06.008","fpage":"50","id":"3c1a46ff-88eb-434c-87d2-286533f38cfa","issue":"6","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"20910188-54cd-40c1-a853-9c8dd5cd9d33","keyword":"氧燃比","originalKeyword":"氧燃比"},{"id":"f72e1f52-520a-42bc-a37a-246d4004365a","keyword":"爆炸喷涂","originalKeyword":"爆炸喷涂"},{"id":"cfd39b2d-5448-4bfb-8a94-d04b332f3e21","keyword":"碳化钨涂层","originalKeyword":"碳化钨涂层"},{"id":"3c70fe35-b1ad-4ed7-8c9f-3bef72b4f3fe","keyword":"维氏显微硬度","originalKeyword":"维氏显微硬度"},{"id":"ef8f55b4-bf97-47b8-90c9-cd36fc80fb82","keyword":"孔隙率","originalKeyword":"孔隙率"}],"language":"zh","publisherId":"clgc201606008","title":"氧燃比对爆炸喷涂碳化钨涂层结构和性能的影响","volume":"44","year":"2016"},{"abstractinfo":"在工具钢表面采用电弧蒸发物理气相沉积TiN涂层中,将不锈钢编织网置于基底和蒸发源之间,以得到不连续的TiN涂层.检验了无涂层、连续涂层和不连续涂层3种表面状态的性能,其中在室温和200℃下做了无润滑和润滑条件下的盘-块和球-盘滑动摩擦试验.结果表明,在滑动条件下,不连续的TiN涂层可同时减小工具钢的磨损量和磨损速度.3种表面状态下的高速切削中,与无涂层和连续涂层比较,不连续TiN涂层由于寿命增加具有优势.","authors":[{"authorName":"","id":"fa1dbe89-d3d4-4af6-b0b1-2b7a2293bbdb","originalAuthorName":""},{"authorName":"","id":"fdab022e-dfab-4583-9438-40c656d4cb1f","originalAuthorName":""},{"authorName":"乔生儒","id":"45d9a4f4-899b-49ab-a5ba-0a0b4f0c6616","originalAuthorName":"乔生儒"},{"authorName":"张程煜","id":"6283d307-cdbf-4c5a-b7f4-e53bcfed79ae","originalAuthorName":"张程煜"}],"doi":"","fpage":"580","id":"02931c56-21ed-4dde-9209-7f702dd63ab6","issue":"4","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":"a5549f34-a08c-4e11-8bf5-6bce4a62d664","keyword":"PVD","originalKeyword":"PVD"},{"id":"ec54a54f-5533-4d0b-af24-f48553e56703","keyword":"连续涂层","originalKeyword":"连续涂层"},{"id":"f76d241e-7b22-400e-858a-f7aa29bf3326","keyword":"不连续涂层","originalKeyword":"不连续涂层"},{"id":"f63f160c-dd44-43e0-b07d-0bfc62bb0c0c","keyword":"摩擦行为","originalKeyword":"摩擦行为"},{"id":"950e1929-fd29-43ae-9fcc-89edc8ec0145","keyword":"粗糙度","originalKeyword":"粗糙度"},{"id":"fe18ab64-8840-4186-ac23-9094de5c0734","keyword":"切削性能","originalKeyword":"切削性能"}],"language":"zh","publisherId":"xyjsclygc201104004","title":"PVD-TiN不连续结构涂层的摩擦行为和切削性能","volume":"40","year":"2011"},{"abstractinfo":"钛基涂层不溶性阳极(DSA)已在电解和电镀工业中得到了广泛的应用.为此,介绍了近年来国内外在新型不溶性阳极的研究和开发方面的重要工作和进展,包括涂层钛阳极新的制备方法及活性涂层组成等.同时,简要介绍了关于钛基涂层不溶性阳极的作用机理及失效机理方面的研究进展.","authors":[{"authorName":"胡新发","id":"2e2b0279-763f-4f90-8a26-7925657373b3","originalAuthorName":"胡新发"},{"authorName":"刘全兵","id":"642253f1-d9a1-4d1e-9303-636c6470b213","originalAuthorName":"刘全兵"},{"authorName":"廖世军","id":"eeb92d11-303c-47d5-97a8-8b84cfdfe0d8","originalAuthorName":"廖世军"}],"doi":"","fpage":"41","id":"26c0cb35-a5dc-4143-afe8-3dd43e648076","issue":"8","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"8dc6e0a9-f71f-4ec1-9256-8b6c260fe204","keyword":"钛基涂层阳极","originalKeyword":"钛基涂层阳极"},{"id":"c9c838de-79c9-4e0b-b765-d9b2143a4f80","keyword":"制备方法","originalKeyword":"制备方法"},{"id":"b3e2554e-e013-4533-a995-289deb2215f4","keyword":"活性层","originalKeyword":"活性层"},{"id":"fb2e55d0-79bf-4c82-b234-f6a0a67c216c","keyword":"失效","originalKeyword":"失效"}],"language":"zh","publisherId":"clbh200808014","title":"钛基涂层不溶性阳极的开发与研究进展","volume":"41","year":"2008"},{"abstractinfo":"DSA电极和铅电极是普遍使用的不溶性阳极,但这类电极均存在一定的缺点.聚苯胺被认为是最有前景的导电聚合物,通过复合反应来改善聚苯胺涂层的性能.综述了聚苯胺不溶性阳极涂层的应用,总结了聚苯胺涂层电极的几种制备方法与研究进展.","authors":[{"authorName":"吴凯","id":"f1728e08-164b-4096-8c38-627a41d488ba","originalAuthorName":"吴凯"},{"authorName":"郝建军","id":"d2429302-55ae-4961-a027-23325ad2b4bc","originalAuthorName":"郝建军"},{"authorName":"里新","id":"9e40e7fa-3c33-4ff9-ba50-7a0ee216a941","originalAuthorName":"里新"}],"doi":"10.3969/j.issn.1001-3849.2014.03.010","fpage":"39","id":"7d0738a2-e046-4b86-b6bb-51b92a425c5f","issue":"3","journal":{"abbrevTitle":"DDYJS","coverImgSrc":"journal/img/cover/DDYJS.jpg","id":"20","issnPpub":"1001-3849","publisherId":"DDYJS","title":"电镀与精饰 "},"keywords":[{"id":"2a25af99-5e94-48d4-88a8-2dd8435a806e","keyword":"不溶性阳极","originalKeyword":"不溶性阳极"},{"id":"5f01a37a-dddc-4039-ba9d-883f26040a8e","keyword":"聚苯胺","originalKeyword":"聚苯胺"},{"id":"c0770524-b94d-4cf0-835f-ecd367936929","keyword":"涂层","originalKeyword":"涂层"}],"language":"zh","publisherId":"ddjs201403010","title":"聚苯胺做不溶性阳极涂层的研究进展","volume":"36","year":"2014"},{"abstractinfo":"目的 提高直升机旋翼系统连接件的耐微动磨损疲劳寿命,解决传统镀铬工艺引起的环境污染问题. 方法 采用爆炸喷涂工艺,通过调节氧气和乙炔混合气体氧燃比,在35 Ni4 Cr2 MoA高强合金钢基体上制备不同的WC-12 Co涂层,研究氧燃比对涂层组成、结构和力学性能的影响规律. 结果 随着氧燃比的提高,涂层C含量逐渐降低,硬度、致密性、弹性模量和结合强度则先升后降. 氧燃比低于1. 1时,粒子飞行速度低和熔融不充分是涂层硬度和致密性下降的主要原因;氧燃比高于1. 3 时,爆炸焰流为氧化气氛,WC粒子的氧化和分解加剧了C元素的流失,使得涂层性能下降;氧燃比为1. 2 时,涂层无明显氧化和脱碳,截面维氏显微硬度(HV0. 3)达到12. 9 GPa,孔隙率为0. 86%,与基材间的结合强度达到148 MPa. 结论 爆炸喷涂中高速飞行的粒子对35 Ni4 Cr2 MoA高强合金钢基体具有一定的表面强化作用,喷丸试棒经爆炸喷涂工艺沉积WC-12 Co涂层后,疲劳寿命提高107 . 4%. 氧燃比对爆炸喷涂沉积WC-12 Co涂层的组成、结构和力学性能影响较大,氧燃比为1 . 2 时,涂层的综合力学性能最佳.","authors":[{"authorName":"赵立英","id":"5bfa2236-07df-4295-b45b-676c25f4155a","originalAuthorName":"赵立英"},{"authorName":"李国太","id":"4063a236-fb77-4205-9dea-7839e966a111","originalAuthorName":"李国太"},{"authorName":"吴清军","id":"dd0cdc13-1615-4d6e-93a7-7a2d061c201b","originalAuthorName":"吴清军"},{"authorName":"代洪川","id":"afee49c0-9b1a-4dd5-9516-fe192a919cf2","originalAuthorName":"代洪川"}],"doi":"10.16490/j.cnki.issn.1001-3660.2016.01.021","fpage":"131","id":"1b8b0c46-c0d8-4203-9f9c-0fe9d78fe8d7","issue":"1","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术 "},"keywords":[{"id":"930271a6-a490-4b69-8771-53e10147746c","keyword":"爆炸喷涂","originalKeyword":"爆炸喷涂"},{"id":"bcbe1d21-0280-420e-8468-14d0ef368107","keyword":"氧燃比","originalKeyword":"氧燃比"},{"id":"a0334c7d-cf19-4cdc-ab91-6071cb6fbbc8","keyword":"碳化钨","originalKeyword":"碳化钨"},{"id":"1f3bb1e5-d4a6-44af-8f82-f64568d2f66e","keyword":"涂层","originalKeyword":"涂层"},{"id":"a54c01f4-5cac-4de4-87fb-23fcf36e9b39","keyword":"组织","originalKeyword":"组织"},{"id":"bc97335c-b7a2-48ac-b616-fbbd50c11c80","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"2b0e16c3-12aa-45c1-a2fd-9d45dd1769dd","keyword":"疲劳寿命","originalKeyword":"疲劳寿命"}],"language":"zh","publisherId":"bmjs201601021","title":"氧燃比对爆炸喷涂WC-12 Co涂层组织和力学性能的影响","volume":"45","year":"2016"},{"abstractinfo":"为了研制机械设备或构件零部件表面的不粘耐磨涂层,选取五因素四水平的正交试验方案[L16(45)]研究了Fe、Al2O3、石墨填充的环氧/聚四氟乙烯(EP/PTFE)复合涂层的不粘性能、粘接性能和耐浆体冲蚀磨损性能,得到了复合涂层的最佳配方,并对其性能进行了分析.结果表明:当填加量(体积分数)为15.0%PTFE、3.O%Fe、2.0%Al2O3、1.0%石墨、0.5%KH-550时,最佳配方的复合涂层具备了防粘和耐浆体冲蚀磨损等优良的综合性能.","authors":[{"authorName":"党胜","id":"f6ab6054-05fc-4a79-aecd-11a374c20395","originalAuthorName":"党胜"},{"authorName":"崔静娜","id":"619a638e-886c-4983-8b5e-84c55e287c42","originalAuthorName":"崔静娜"},{"authorName":"耿刚强","id":"82e0517d-5662-4ac2-a509-d77868a25cdb","originalAuthorName":"耿刚强"},{"authorName":"王阳军","id":"6243ee97-c610-40f6-a20c-b21e6c97da5d","originalAuthorName":"王阳军"},{"authorName":"张海宝","id":"c581b026-a968-4287-846f-2d57f6557b30","originalAuthorName":"张海宝"},{"authorName":"林杰","id":"db5ce167-b951-4504-b034-4740aff9353f","originalAuthorName":"林杰"}],"doi":"10.3969/j.issn.1001-1560.2007.06.013","fpage":"35","id":"2bcd3003-f21d-44ad-ac4c-3680c669c9c4","issue":"6","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"082f9a87-5372-4c3e-84fc-302edeb60461","keyword":"复合涂层","originalKeyword":"复合涂层"},{"id":"e95e7709-9bb7-41ff-b742-82ee3101e08f","keyword":"不粘性能","originalKeyword":"不粘性能"},{"id":"41a9f2d7-afef-41e9-92b5-65b0a4bc9720","keyword":"粘接性能","originalKeyword":"粘接性能"},{"id":"dd215f0f-d7dd-4660-81da-e9317660ea85","keyword":"磨损性能","originalKeyword":"磨损性能"},{"id":"1f7ceae7-a6d6-40fa-a139-877347a90452","keyword":"聚四氟乙烯","originalKeyword":"聚四氟乙烯"},{"id":"6c50d542-b4bf-4c60-9e52-3c1a54ecba58","keyword":"正交试验","originalKeyword":"正交试验"}],"language":"zh","publisherId":"clbh200706013","title":"环氧/聚四氟乙烯复合涂层的不粘与耐浆体磨损性能研究","volume":"40","year":"2007"}],"totalpage":1283,"totalrecord":12829}