{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"海洋是人类生存的基本空间,也是保证人类社会持续发展的宝库。关于海洋环境下材料的摩擦学研究,不仅促进了海洋工程装备的开发,而且也为海洋工程装备的关键摩擦副材料提供了有力支撑。但海洋环境下的摩擦磨损严重制约了海洋专用材料的应用与发展,主要原因是海水介质复杂,以及腐蚀与摩擦的交互作用等。因此,研究和探讨海洋环境下关键摩擦副材料的摩擦学是提高我国海洋工程装备整体水平的重要途径。对海洋环境下关键摩擦副材料的摩擦学研究进行汇总与分析,着重介绍了金属与金属配副、陶瓷与金属配副、聚合物与金属配副、聚合物与陶瓷配副等在海水环境下的摩擦学研究现状,并结合摩擦副材料的摩擦学研究现状及发展趋势,对海洋环境下关键摩擦副材料的摩擦学研究进行了展望。","authors":[{"authorName":"文怀兴","id":"518f73bd-7bcc-4842-a986-fe66fd14b7d3","originalAuthorName":"文怀兴"},{"authorName":"孙建建","id":"b60a5804-7cb8-4372-bf0e-a5c5ca4b27c4","originalAuthorName":"孙建建"},{"authorName":"陈威","id":"29d2e875-eb37-4b7c-ad3e-20e4b3c3470f","originalAuthorName":"陈威"}],"doi":"10.11896/j.issn.1005-023X.2016.015.014","fpage":"85","id":"d2dd89b3-e84c-4d3b-814f-450693432a12","issue":"15","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"08dbd6ef-f2c8-485e-995b-84705b872e6e","keyword":"海洋环境","originalKeyword":"海洋环境"},{"id":"d5e7d137-6472-4d8f-bbfa-66a3abd03a0d","keyword":"关键摩擦副","originalKeyword":"关键摩擦副"},{"id":"1bc743de-3ddd-4e4d-901b-38130dd41307","keyword":"摩擦学","originalKeyword":"摩擦学"},{"id":"a9a903f5-2b4f-4429-8b50-e92335f066a7","keyword":"腐蚀磨损","originalKeyword":"腐蚀磨损"}],"language":"zh","publisherId":"cldb201615015","title":"海洋环境下关键摩擦副材料的摩擦学研究现状与展望","volume":"30","year":"2016"},{"abstractinfo":"四十多年来,研究成功10种航空摩擦副材料,并坚持科研成果工程化,转换为现实生产力,已在十几种军用飞机和民航进口的波音、麦道、伊留申、图波列夫和安东诺夫系列等20个民用机型上应用,取得重大的技术、经济效果.","authors":[{"authorName":"李东生","id":"430029c6-733f-40b3-9c37-17c90d5e7c19","originalAuthorName":"李东生"}],"doi":"10.3969/j.issn.1001-1560.2004.z1.004","fpage":"9","id":"19a91c2d-66fc-4d3a-9b2f-9a88c0abb30b","issue":"z1","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"2633207b-be3b-44b5-be0d-2f175cb103a2","keyword":"金属陶瓷摩擦材料","originalKeyword":"金属陶瓷摩擦材料"},{"id":"87523219-dc9d-4e61-b77c-e88c72f1997f","keyword":"炭/炭复合材料刹车盘","originalKeyword":"炭/炭复合材料刹车盘"},{"id":"b26dee07-97a3-40a5-b1e5-1af231999f11","keyword":"摩擦学","originalKeyword":"摩擦学"}],"language":"zh","publisherId":"clbh2004z1004","title":"航空摩擦副材料研究及应用","volume":"37","year":"2004"},{"abstractinfo":"在1:1惯性力矩制动试验台上研究了两种不同石墨形态的铸铁制动盘与两种混杂纤维增强的酚醛基制动闸片配副时的摩擦磨损性能.结果表明,对于某一配方的制动闸片,使用灰口铸铁盘的摩擦副具有较高的摩擦系数,但制动盘表面温度较高,闸片磨损量较大;对于某一种制动盘,使用B配方制动闸片时,制动盘表面的温度较高,但闸片的磨损量较小;在所有四种组合中,B配方制动闸片与灰口铸铁盘配副的瞬时摩擦系数能够完全满足有关技术要求.","authors":[{"authorName":"庄光山","id":"7d17b7f7-da09-4446-a0d8-de4cfe711919","originalAuthorName":"庄光山"},{"authorName":"王成国","id":"c9c4dcfc-ab58-4b49-be6f-b31eaa5edcf4","originalAuthorName":"王成国"},{"authorName":"王海庆","id":"ca1a9ca5-12c5-428f-be94-1bcf2e3d23cd","originalAuthorName":"王海庆"},{"authorName":"孙毅","id":"e332179c-be12-42a4-ad7d-4023f3b21b9d","originalAuthorName":"孙毅"},{"authorName":"姚永强","id":"1e43529d-38b5-4046-a1b5-2c423d3e4b87","originalAuthorName":"姚永强"}],"doi":"10.3969/j.issn.1000-3738.2003.11.017","fpage":"52","id":"3cb2d747-2e19-4967-ba1b-86e554b9f4bb","issue":"11","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":"725ffeff-9e86-4c63-8469-72a3bb30fb67","keyword":"制动装置","originalKeyword":"制动装置"},{"id":"072c6761-9ac3-458b-9346-828490dae032","keyword":"盘形制动","originalKeyword":"盘形制动"},{"id":"4761fbdb-b62e-4220-8386-17c2e326b09a","keyword":"摩擦副","originalKeyword":"摩擦副"}],"language":"zh","publisherId":"jxgccl200311017","title":"摩擦副组合对摩擦磨损性能的影响","volume":"27","year":"2003"},{"abstractinfo":"对舰用艉轴密封副材料进行了筛选和研究,结果表明在不锈钢基体上热喷熔镍基合金不仅经济性好,而且其与YG8组成的摩擦副具有极其优异的摩擦学性能,优于硬质合金摩擦副.解决了因海水中泥沙含量大而导致机械密封环寿命过短的问题.","authors":[{"authorName":"谢沛霖","id":"5b3c676d-51b2-425e-a4df-4b2dec912226","originalAuthorName":"谢沛霖"},{"authorName":"付安林","id":"719b6960-a4a3-474c-8cc6-b08c90892365","originalAuthorName":"付安林"}],"doi":"10.3969/j.issn.1001-1560.2002.04.005","fpage":"12","id":"f5f9791e-4632-4d77-8aff-3197c4f8fd59","issue":"4","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"6f6d50f9-1ba6-4a00-8ce1-6120df5c47fa","keyword":"机械端面密封","originalKeyword":"机械端面密封"},{"id":"7ec0851a-9c2e-4034-bf66-9fa657050daa","keyword":"摩擦副材料","originalKeyword":"摩擦副材料"},{"id":"02fc12eb-d313-4edf-9892-3afedb1438fb","keyword":"艉轴","originalKeyword":"艉轴"}],"language":"zh","publisherId":"clbh200204005","title":"艉轴端面密封副摩擦学性能研究","volume":"35","year":"2002"},{"abstractinfo":"两种具有较高热稳定性的胍盐离子液体用于Si3N4/钢摩擦副摩擦学性能的研究,在扫描电子显微镜下观察了磨斑表面形貌,并与烷基咪唑离子液体进行对比.用X射线光电子能谱仪(XPS)分析了润滑机理.结果表明,胍盐离子液体对Si3N4/钢摩擦副具有非常好的润滑作用,其承载能力强,摩擦系数小,磨痕浅.摩擦过程中,Si3N4/钢摩擦副界面发生了复杂的摩擦化学反应并形成了边界润滑膜,起到减摩抗磨的作用.","authors":[{"authorName":"于桂琴","id":"61305555-0eb7-43db-820c-47edd83870a6","originalAuthorName":"于桂琴"},{"authorName":"刘建军","id":"5c4c79e1-e4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7mm3/(N·m)数量级.其中,Si3 N4巴氏合金的摩擦因数最低,SiC巴氏合金的磨损率最小.Si3 N4具有自润滑特性,摩擦表面能够形成氧化膜,使其与金属组合具有较佳的摩擦学性能.锡基巴氏合金作为对磨件,易与陶瓷形成金属化合物润滑膜,其摩擦性能优于其他三种金属,Si3N4锡基巴氏合金组合摩擦学性能最为优异.","authors":[{"authorName":"田欣利","id":"5b150b00-4cb3-4826-a216-a3f8e8994497","originalAuthorName":"田欣利"},{"authorName":"王龙","id":"fd7424cf-1c94-495e-9ba2-d5de663be955","originalAuthorName":"王龙"},{"authorName":"王朋晓","id":"a593f5fa-aa4e-4917-b06e-c8899b63d832","originalAuthorName":"王朋晓"},{"authorName":"吴志远","id":"791a1792-a2c2-4585-8e5e-818c41bda06e","originalAuthorName":"吴志远"},{"authorName":"张保国","id":"ac2e5e2d-e55b-4197-8fb6-4c0c66d5362a","originalAuthorName":"张保国"},{"authorName":"王健全","id":"07f7ba00-14eb-4090-a76a-ab5eab712cc6","originalAuthorName":"王健全"}],"doi":"10.11868/j.issn.1001-4381.2014.09.008","fpage":"45","id":"b913abfe-980f-4c1c-930f-71e8ec5412fe","issue":"9","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"bcecd7a8-fb4f-467e-91a3-a38aec2d2ad5","keyword":"工程陶瓷-金属","originalKeyword":"工程陶瓷-金属"},{"id":"36eaace8-90a2-4c76-8376-843917d12754","keyword":"最优摩擦副组合","originalKeyword":"最优摩擦副组合"},{"id":"a1d20bd2-60fb-48c3-b670-901d6376e25a","keyword":"微量润滑","originalKeyword":"微量润滑"},{"id":"68d6f0f3-4738-4561-9788-1bdc9300bd1e","keyword":"摩擦学性能","originalKeyword":"摩擦学性能"}],"language":"zh","publisherId":"clgc201409008","title":"工程陶瓷-典型金属摩擦副的摩擦学性能及组合优化","volume":"","year":"2014"},{"abstractinfo":"用多功能SRV实验机评价了钢/钢摩擦副在干摩擦条件下的的高温减摩抗磨性能,并对高温磨损机理进行了探讨.结果表明,钢/钢摩擦副的高温摩擦系数随着实验负荷的增加呈下降趋势,而随着实验时间的延长呈增长趋势.钢/钢摩擦副的线接触高温摩擦系数明显比点接触时的高温摩擦系数大,SPHC/GCr15摩擦副的高温摩擦系数明显高于GCr15/GCr15摩擦副的高温摩擦系数.钢球在点接触条件下的磨损随实验负荷的增加呈线性增长趋势,而钢柱在线接触条件下的磨损随实验负荷的增加呈线性降低趋势.在相同负荷下,SPHC/GCr15摩擦副的磨损要较GCr15/GCr15摩擦副的磨损略微大.钢/钢摩擦副在高速度下的磨损机理主要是磨粒磨损,而在较低速度下主要是磨粒磨损和粘着磨损.","authors":[{"authorName":"乔玉林","id":"ea28c078-1685-41ad-9f7d-f06df859629b","originalAuthorName":"乔玉林"},{"authorName":"梁志杰","id":"7348b7b6-2624-4415-991f-8b0ad0f88075","originalAuthorName":"梁志杰"},{"authorName":"孙晓峰","id":"b0dc9707-9667-48b5-a1cd-69e7db962657","originalAuthorName":"孙晓峰"},{"authorName":"徐滨士","id":"981b118e-b86c-47f4-8afa-3bf78ef7277d","originalAuthorName":"徐滨士"},{"authorName":"小豆岛明","id":"212cbc15-75cc-4b7e-bbee-4165a3f5b0fd","originalAuthorName":"小豆岛明"}],"doi":"10.3969/j.issn.1001-4381.2005.11.003","fpage":"9","id":"6a37951e-8b7a-4e06-8176-e57f0e3e2372","issue":"11","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"1805b827-2f43-4065-a2d7-0d3c35377e9c","keyword":"高温","originalKeyword":"高温"},{"id":"321b0534-bfea-4f06-aa12-b14776ade8bf","keyword":"摩擦系数","originalKeyword":"摩擦系数"},{"id":"b4a06556-cdfe-405d-b98f-ff043aa494df","keyword":"磨损机理","originalKeyword":"磨损机理"}],"language":"zh","publisherId":"clgc200511003","title":"在点线接触条件下钢/钢摩擦副的干摩擦高温减摩抗磨性能的研究","volume":"","year":"2005"},{"abstractinfo":"摩擦副表面的微细形貌深刻影响着摩擦副的摩擦学性能,因而人们利用各种加工方法对摩擦副进行表面处理以达到所需的摩擦学性能,激光表面造型技术以其诸多的优点而被认为是摩擦副表面处理的理想手段.首先阐述了激光表面造型技术的原理及其减磨机理.介绍了激光表面造型专用设备的基本组成及其控制原理,接着详细论述了激光表面造型技术在重要摩擦副处理中的应用及取得的效果,最后提出了激光表面造型技术的发展和应用前景.","authors":[{"authorName":"钱振华","id":"c93721d4-55f4-4b6a-9cc1-c73ec4ddab44","originalAuthorName":"钱振华"},{"authorName":"左希庆","id":"4a2c7e70-6e83-4929-9081-1be10a3557ae","originalAuthorName":"左希庆"}],"doi":"10.3969/j.issn.1001-3660.2008.01.030","fpage":"86","id":"d16dd4f6-2328-4274-ad2b-4d6c5a1f4c7b","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":"b4030983-0703-4c45-9275-8054e2252354","keyword":"激光造型","originalKeyword":"激光造型"},{"id":"c76fa7fa-f59a-4a85-a8e0-67a12589542e","keyword":"摩擦副","originalKeyword":"摩擦副"},{"id":"5b230602-4d08-4fd1-85c2-63ef77b8cf75","keyword":"表面处理","originalKeyword":"表面处理"}],"language":"zh","publisherId":"bmjs200801030","title":"激光造型技术在摩擦副表面处理中的应用","volume":"37","year":"2008"},{"abstractinfo":"利用球-盘摩擦试验机,在大气和真空环境中分别考察了9Cr18和GCr15钢在干摩擦和固体润滑条件下与钢球的摩擦磨损性能.试验结果表明:两种材料在真空环境中或MoS2基薄膜润滑条件下,摩擦系数都明显低于大气环境或无润滑条件,而且摩擦振动和噪音较低,磨痕表面较光滑;通常的摩擦副在真空环境中的摩擦系数、磨损量比大气中大.研究表明这是由于9Cr18盘表面干摩擦跃迁导致了加工硬化和MoS2基薄膜润滑作用.通过对动态滑动摩擦系数及其特征值的系统分析,对这两种材料的摩擦过程特性进行了研究.","authors":[{"authorName":"于翔","id":"d5f24e79-585d-4c89-b6e1-1abba97d9c3c","originalAuthorName":"于翔"},{"authorName":"王成彪","id":"c26a5fb9-89dd-4193-b703-4229be16ed75","originalAuthorName":"王成彪"},{"authorName":"孙晓军","id":"37d7efb6-2b58-489e-ac42-86d3066f79d8","originalAuthorName":"孙晓军"}],"doi":"10.3969/j.issn.1009-6264.2002.04.012","fpage":"47","id":"7a1c412d-cdf7-4cf0-8a16-2cde7a3c516f","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":"3348f592-44b8-4d4d-b54f-cda3da1506c4","keyword":"球-盘摩擦磨损试验","originalKeyword":"球-盘摩擦磨损试验"},{"id":"895c1985-65f9-4b32-9277-8eaea97c10fa","keyword":"滑动摩擦副","originalKeyword":"滑动摩擦副"},{"id":"ed0c964f-af5f-4d27-b8ee-79845353cd37","keyword":"滑动摩擦系数","originalKeyword":"滑动摩擦系数"},{"id":"20412238-cb88-41eb-b55b-4b3f9e2b9414","keyword":"磨损性能","originalKeyword":"磨损性能"}],"language":"zh","publisherId":"jsrclxb200204012","title":"9Cr18和GCr15球-盘摩擦副摩擦学性能分析","volume":"23","year":"2002"},{"abstractinfo":"室温下采用改进的MPV-1500型摩擦试验机,研究锌黄铜自配副的磁场干摩擦学特性和磁场干涉机理.结果表明:磁场的施加和增大加剧了抗磁性锌黄铜的摩擦和磨损,增大了摩擦面的粗糙度,降低了摩擦面的氧元素含量,主要氧化物为Cu64O;随着磁场的增大,锌黄铜的磨损率和摩擦副的摩擦因数均有增大趋势,欲克服磁场对抗磁性锌黄铜干摩擦学特性的不利影响,可在其背面添置铁磁性材料;配副材料选配、对摩面的相对尺寸以及装卡装置的磁性均可影响实验研究结果.","authors":[{"authorName":"魏永辉","id":"0c43d90f-8ea1-4fdf-98f5-6d713fffddbd","originalAuthorName":"魏永辉"},{"authorName":"张永振","id":"3ce81447-13d8-4e59-ad7f-1020cbe48726","originalAuthorName":"张永振"},{"authorName":"陈跃","id":"f5d395d3-1143-4460-a3b6-3611a636ca0c","originalAuthorName":"陈跃"}],"doi":"10.3969/j.issn.1001-4381.2013.08.004","fpage":"23","id":"e7d3aaae-400c-40fc-84fa-ee590d5cc3c2","issue":"8","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"ed438793-e117-4c82-8dad-3da99e1d0036","keyword":"磁场","originalKeyword":"磁场"},{"id":"30aba17c-aa92-486a-a886-67c5b64717f8","keyword":"干滑动摩擦","originalKeyword":"干滑动摩擦"},{"id":"cdf4bf4f-69c8-41f0-85a7-ba663c147dc4","keyword":"铜合金","originalKeyword":"铜合金"},{"id":"5e9af1a4-fad3-4091-b2d3-0097baa5c59d","keyword":"电力机车","originalKeyword":"电力机车"}],"language":"zh","publisherId":"clgc201308004","title":"磁场干涉下锌黄铜自配副干摩擦学特性的研究","volume":"","year":"2013"}],"totalpage":906,"totalrecord":9057}