高分子材料科学与工程, 2012, 28(1): 93-100.
大直径PA6/PA66共聚物单丝的后拉伸性能
马海燕 1, , 刘兆峰 2, , 张军 3, , 马海军 {"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"
为提高钛合金在海水中的摩擦性能, 采用激光加工技术分别制备具有网格和点阵微结构的超疏水Ti6Al4V合金表面. 采用HSR-2M高速往复摩擦试验机研究其在人工海水介质中的摩擦学行为, 并与水介质比较. 结果表明, 超疏水Ti6Al4V合金表面的摩擦系数和磨损量(体积)均显著小于Ti6Al4V基体. 海水介质中, 与空白样相比, 点阵和网格表面的摩擦系数分别减小了17.8%和11.7%, 磨损量分别减小了36.8%和57.5%. 超疏水Ti6Al4V合金表面在海水介质中的摩擦系数小于水介质中, 磨损量大于水介质中. 超疏水钛合金表面的制备显著提高了钛合金在海水中的摩擦性能.
","authors":[{"authorName":"连峰","id":"bdc5ada5-b1ba-461e-8019-32f04a662702","originalAuthorName":"连峰"},{"authorName":"臧路苹","id":"ca6e9a1b-8512-4970-ab9b-f17c959b091d","originalAuthorName":"臧路苹"},{"authorName":"项秋宽","id":"4ad3349e-1a5f-4cef-acfd-a582d4ea49ef","originalAuthorName":"项秋宽"},{"authorName":"张会臣","id":"b546f2c5-a8d5-46eb-9e21-06ce0bbac1b1","originalAuthorName":"张会臣"}],"categoryName":"Orginal Article","doi":"10.11900/0412.1961.2015.00342","fpage":"592","id":"8962845b-7f69-44d3-9cac-017af14b21d1","issue":"5","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"50ae398b-db64-4a1b-8ad6-540e9f948131","keyword":"超疏水","originalKeyword":"超疏水"},{"id":"01f0c278-020e-435d-a39c-0c362ab52be0","keyword":"钛合金","originalKeyword":"钛合金"},{"id":"2fdb0e5f-1713-4c14-9aca-3d5982e97a15","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"89456aa4-0965-4272-88e5-c0fbe2266294","keyword":"摩擦系数","originalKeyword":"摩擦系数"},{"id":"c590ed2d-632c-49b3-8536-76683776588c","keyword":"磨损量","originalKeyword":"磨损量"}],"language":"zh","publisherId":"C20150342","title":"超疏水钛合金表面在人工海水中的摩擦性能*","volume":"52","year":"2016"},{"abstractinfo":"为提高钛合金在海水中的摩擦性能,采用激光加工技术分别制备具有网格和点阵微结构的超疏水Ti6Al4V合金表面采用HSR-2M高速往复摩擦试验机研究其在人工海水介质中的摩擦学行为,并与水介质比较.结果表明,超疏水Ti6Al4V合金表面的摩擦系数和磨损量(体积)均显著小于Ti6Al4V基体.海水介质中,与空白样相比,点阵和网格表面的摩擦系数分别减小了17.8%和11.7%,磨损量分别减小了36.8%和57.5%.超疏水Ti6Al4V合金表面在海水介质中的摩擦系数小于水介质中,磨损量大于水介质中.超疏水钛合金表面的制备显著提高了钛合金在海水中的摩擦性能.","authors":[{"authorName":"连峰","id":"44a57eca-bc21-4f07-b3aa-789babf4ff19","originalAuthorName":"连峰"},{"authorName":"臧路苹","id":"6936cf27-7d56-4a73-b0ce-d61bdacaa702","originalAuthorName":"臧路苹"},{"authorName":"项秋宽","id":"dd6f3117-1539-4227-80eb-aebfe66abe57","originalAuthorName":"项秋宽"},{"authorName":"张会臣","id":"2c85c14e-7151-485f-a161-d9f23ab51f43","originalAuthorName":"张会臣"}],"doi":"10.11900/0412.1961.2015.00342","fpage":"592","id":"9d1da67a-5069-4c39-b762-55f51d52866c","issue":"5","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"134348de-2f04-487a-8a46-e6f8a46b6260","keyword":"超疏水","originalKeyword":"超疏水"},{"id":"4199f990-9856-461b-852a-756279cf4fc8","keyword":"钛合金","originalKeyword":"钛合金"},{"id":"f434dc3f-9ae6-4c14-91d6-482d7efa29cb","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"6874f041-c8b8-4269-b4bf-828fb2f03627","keyword":"摩擦系数","originalKeyword":"摩擦系数"},{"id":"e337c5f9-5698-4402-b06b-3dfd74e15f23","keyword":"磨损量","originalKeyword":"磨损量"}],"language":"zh","publisherId":"jsxb201605010","title":"超疏水钛合金表面在人工海水中的摩擦性能","volume":"52","year":"2016"},{"abstractinfo":"采用失重法、腐蚀电化学试验方法、电偶腐蚀试验方法,研究了铝合金(Al6061)在人工海水中的耐腐蚀性能和电化学特性及其与环氧碳纤维复合材料T700偶接后的电偶腐蚀敏感性.结果表明,Al6061在人工海水中有一定的电化学腐蚀钝化性;Al6061与T700偶接后,电偶腐蚀使Al6061的腐蚀速度明显加快,人工海水中通入空气使电偶腐蚀程度增大;在T700表面涂敷环氧树脂涂层,能有效控制T700与Al6061之间的电偶腐蚀.","authors":[{"authorName":"马宗耀","id":"50ca0590-8f40-43cc-be5b-e578b975b14d","originalAuthorName":"马宗耀"},{"authorName":"谢发勤","id":"f5a0ef4a-9b15-4f6b-9d15-a5fa21265751","originalAuthorName":"谢发勤"}],"doi":"","fpage":"27","id":"70b2dc32-8c0d-4b1f-a2e3-7b5cf1d08f00","issue":"3","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"17d9d494-f83d-46b8-bb08-fc9b88e6ae04","keyword":"铝合金","originalKeyword":"铝合金"},{"id":"5fadd321-89f3-4012-9644-2cb653624c83","keyword":"碳纤维复合材料","originalKeyword":"碳纤维复合材料"},{"id":"768149ec-399a-416c-ae65-82cdd8cf6c06","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"f739e5a0-b142-4e67-b3a3-8354c6e5fb5a","keyword":"电偶腐蚀","originalKeyword":"电偶腐蚀"}],"language":"zh","publisherId":"clbh200903008","title":"人工海水中铝合金与复合材料T700电偶的腐蚀性能","volume":"42","year":"2009"},{"abstractinfo":"为进一步改善TC4台金性能,尤其耐海水腐蚀性,采用自耗电极真空电弧熔炼(VAR)法在TC4合金基体中加入Cu和Ag,制备分别含1%、2%Cu(质量分数,下同)的TC4-Cu和含1%Ag的TC4-Ag合金.利用电化学方法研究了不同合金在人工海水中的腐蚀行为与特征.结果表明,添加Cu和Ag后,TC4合金在人工海水中的腐蚀电位升高,腐蚀电流减小,可以有效提高TC4合金的耐腐蚀性能.","authors":[{"authorName":"章桥新","id":"44393de3-b7bf-427e-8534-f94b5758d65d","originalAuthorName":"章桥新"},{"authorName":"揭松","id":"a126ddf3-dc65-4ebe-b378-0aed7b3120cf","originalAuthorName":"揭松"},{"authorName":"黄祺","id":"7e26a887-8933-4914-a051-73639de3e285","originalAuthorName":"黄祺"},{"authorName":"李涛","id":"15a0d825-4967-4e24-8e91-a18136203bb8","originalAuthorName":"李涛"}],"doi":"","fpage":"1231","id":"c6de405e-e736-48f8-891a-faa42ecf145e","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":"b2dc8323-4842-487e-b240-ca4c199256fd","keyword":"TC4合金","originalKeyword":"TC4合金"},{"id":"823385e3-b059-479a-b5e1-659851ccd358","keyword":"电化学","originalKeyword":"电化学"},{"id":"520a6731-2e7e-4f38-895b-17d8187dbf0f","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"fde2e831-6d60-443e-9d48-dfea9dad2c61","keyword":"耐腐蚀性能","originalKeyword":"耐腐蚀性能"}],"language":"zh","publisherId":"xyjsclygc201207022","title":"Cu和Ag添加对TC4合金耐人工海水腐蚀性的影响","volume":"41","year":"2012"},{"abstractinfo":"本文对10%纳米钛粉改性的环氧煤焦沥青涂层在流动人工海水中进行了模拟实验,并应用电化学阻抗研究了涂层的电阻随冲刷时间的变化.研究结果表明含有质量分数为10%的纳米钛粉涂层在4种不同流速的实验中,涂层电阻在所测试期间都保持具有较好的防护性能.流速相同时,涂层电阻随冲刷时间的增加而减小.提高流速对涂层界面的传质与力学作用增强,从而使得涂层电阻随时间增加而减小的幅度增大.","authors":[{"authorName":"张秀芝","id":"f3eb7ed0-f903-4170-8e8c-3ee0d824fcd5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"},"keywords":[{"id":"9a91afc1-4371-4642-b46b-6aea5b8fdba1","keyword":"纳米钛粉","originalKeyword":"纳米钛粉"},{"id":"b989db14-fa2b-4af0-8175-282c3698c676","keyword":"涂层","originalKeyword":"涂层"},{"id":"aa1cc4f7-a888-48ee-a2ec-3d527aba9cb5","keyword":"人工海水","originalKeyword":"人工海水"}],"language":"zh","publisherId":"tlgy200804019","title":"纳米钛粉改性环氧煤焦沥青涂层在流动人工海水中防护性能的研究","volume":"38","year":"2008"},{"abstractinfo":"通过测量阳极极化曲线研究了固溶处理温度对超级双相不锈铸钢在人工海水中腐蚀的影响.结果表明:经不同温度固溶处理的超级双相不锈铸钢材料在人工海水中自腐蚀电位相差不大,均具有钝化性能,维钝电流密度为0.1 mA/cm2 左右;室温海水中,不同温度的固溶处理对腐蚀电流密度影响也不大;海水温度由室温升至80℃,钝化区宽度急剧变窄,击破电位显著下降.经1150℃固溶处理后,Cr、Mo在铁素体与奥氏体两相中的均匀分配,有利于提高超级双相不锈铸钢在海水中耐蚀性.","authors":[{"authorName":"向红亮","id":"81f7ba68-2867-4a33-ad34-2e5df42f256c","originalAuthorName":"向红亮"},{"authorName":"刘东","id":"1f88f168-42a1-467f-a33c-aa2b86e08a63","originalAuthorName":"刘东"},{"authorName":"何福善","id":"d96eb982-7611-4e3a-929e-50ec9e29fd3b","originalAuthorName":"何福善"},{"authorName":"黄利光","id":"5d9ae7aa-6b33-4ea1-a147-89abb5b419bf","originalAuthorName":"黄利光"}],"doi":"","fpage":"25","id":"dafb46c4-39c3-4f3e-9534-ecbe4a6b5486","issue":"1","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报(英文)"},"keywords":[{"id":"c00d8e94-e1a5-44a7-a417-857f9c7306d6","keyword":"超级双相不锈铸钢","originalKeyword":"超级双相不锈铸钢"},{"id":"90f9271e-2336-4cc1-b2c5-4b3767a2db0b","keyword":"固溶处理温度","originalKeyword":"固溶处理温度"},{"id":"623106eb-7b8b-4a00-bf1a-8ad513ed9bab","keyword":"腐蚀","originalKeyword":"腐蚀"},{"id":"37c8d35f-415c-40a4-b74d-12f8842ad6cd","keyword":"人工海水","originalKeyword":"人工海水"}],"language":"zh","publisherId":"fskxyfhjs201101006","title":"固溶温度对超级双相不锈铸钢在海水中耐蚀性的影响","volume":"23","year":"2011"},{"abstractinfo":"通过高速旋转腐蚀试验、X射线衍射、扫描电镜(SEM)及能谱分析(EDAX)、电化学特征测定等对Cu-2.9Sn-0.9Al铜合金在人工海水中的腐蚀行为进行了研究.结果表明,添加2.9%Sn、0.9%Al的铜合金在室温、pH值为8.2的人工海水中具有较好的耐腐蚀性.其高耐蚀性主要是由于在合金表面形成一层氧化膜,它对阳极过程和阴过程都有影响.这层膜是Cu的氧化物和Sn的氧化物及Cu-Al-Mg共析化合物的复合保护膜.它们的协同作用降低了氧化层的孔隙度,从而避免了局部酸性区域的形成而导致的局部腐蚀.","authors":[{"authorName":"赵楠","id":"5424feaf-9ae7-404e-aa6a-52e525625e7f","originalAuthorName":"赵楠"},{"authorName":"罗兵辉","id":"b399631d-71cb-47bd-957b-ab13fc9439e8","originalAuthorName":"罗兵辉"},{"authorName":"柏振海","id":"c0e6e123-00aa-4388-a174-ae2de0458e02","originalAuthorName":"柏振海"}],"doi":"10.3969/j.issn.1001-1560.2003.03.007","fpage":"21","id":"17edbca2-a771-4e6e-946e-5f6a4a724633","issue":"3","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"e23fb834-a36f-49e6-b363-c2c924c36fcf","keyword":"铜合金","originalKeyword":"铜合金"},{"id":"a667c42b-dc51-4542-9669-23972632371a","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"da226ffb-5ee5-43e8-b5c7-c4c9087c8868","keyword":"耐蚀性","originalKeyword":"耐蚀性"},{"id":"8d7038cb-5705-42d4-b84a-6b4fcb0907de","keyword":"电化学特征","originalKeyword":"电化学特征"}],"language":"zh","publisherId":"clbh200303007","title":"铜合金在海水中的腐蚀行为研究","volume":"36","year":"2003"},{"abstractinfo":"设计并建立了实验室模拟流动海水腐蚀试验装置。对A3、20#、X70钢挂片和20#钢管路在流动人工海水中全浸暴露2、4、8、16、32天的腐蚀行为进行了试验研究。试验结果表明,流动海水中碳钢的腐蚀速率先降后升,然后趋于稳定;在动水试验中,锈层分为两层,底层以Fe3O4为主,表层以Fe2O3为主;在静水试验中,锈层以Fe2O3为主。","authors":[{"authorName":"程浩力","id":"a7529c25-0606-43a7-ab00-ea24d31918ee","originalAuthorName":"程浩力"},{"authorName":"刘德俊","id":"b80413ac-ef2e-478f-93ef-7430c7b580b1","originalAuthorName":"刘德俊"}],"doi":"","fpage":"212","id":"b40fbf5e-c007-4f7f-a7e4-f5c3a5832246","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":"ddcde203-7f83-487e-83f5-e13c5e4b66b6","keyword":"流动海水","originalKeyword":"流动海水"},{"id":"bd743b3e-9615-4211-a682-3dca72897400","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"1f4e50d8-edbb-4453-839e-706e09d38ebe","keyword":"腐蚀试验","originalKeyword":"腐蚀试验"},{"id":"ce0e9df2-2f87-421e-9bd9-0d77ebf5e09e","keyword":"腐蚀特征","originalKeyword":"腐蚀特征"},{"id":"8f182cf0-f588-48c3-b89e-fe318419e8bb","keyword":"腐蚀速率","originalKeyword":"腐蚀速率"}],"language":"zh","publisherId":"fsyfh201203011","title":"A3、20#和X70钢室内模拟流动海水腐蚀试验","volume":"33","year":"2012"},{"abstractinfo":"利用腐蚀电化学法及化学浸泡法研究了1ONiCrMo钢在人工海水及3.5%NaCl溶液中的腐蚀行为.结果表明:1ONiCrMo钢在人工海水中的自然腐蚀电位为一0.690V,在3.5% NaCl溶液中为-0.661V,在人工海水中腐蚀电位较在3.5%NaCl溶液中低;3个月室内全、间浸腐蚀中,腐蚀速率大小主要受氧扩散控制影响,随着腐蚀时间增长,表面锈层的增厚,1ONiCrMo钢在人工海水及3.5%NaCl溶液中的全、间浸腐蚀速率随时间的延长而降低,1500h后趋向稳定;IONiCrMo钢在人工海水中全、间浸腐蚀速率分别为0.338~0.459mm/a和0.279~0.435mm/a,在3.5%NaCl溶液中全、间浸平均腐蚀速率分别为1.200~1.141mm/a和0.840~0.404 mm/a,虽在人工海水中腐蚀电位较在3.5%NaCl溶液中低,但在人工海水中全、间浸腐蚀速率均比对应时间段内在3.5%NaCl溶液中小,在人工海水中及3.5%NaCl溶液中的间浸腐蚀速率比全浸低.","authors":[{"authorName":"查小琴","id":"8ee70752-bfef-44f5-8d38-9989e338942c","originalAuthorName":"查小琴"}],"doi":"","fpage":"75","id":"a05a5f6a-0183-40fb-a74a-c991272b5c5a","issue":"10","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"7f0ebf8d-a057-4fea-a165-d0e10fc076c7","keyword":"IONiCrMo钢","originalKeyword":"IONiCrMo钢"},{"id":"4b7d0357-5f89-4264-93a8-1d5ed83f7fe6","keyword":"腐蚀","originalKeyword":"腐蚀"},{"id":"7c0ab240-53a9-4a93-aaf6-4a697ca38328","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"b7077e50-cf3c-4ef8-86e1-fee4c93af1ad","keyword":"3.5%NaCl溶液","originalKeyword":"3.5%NaCl溶液"}],"language":"zh","publisherId":"gt201010016","title":"1ONiCrMo钢在室内模拟海洋环境试验中的腐蚀行为","volume":"45","year":"2010"},{"abstractinfo":"本文对几种复合材料在去离子水和人工海水中长期浸泡后的去湿性进行了研究,并对实验结果进行了讨论.","authors":[{"authorName":"张立晨","id":"b4933215-9d36-4fc9-87a9-63bda4696866","originalAuthorName":"张立晨"},{"authorName":"何峰","id":"67f61566-1865-4fe0-b97c-bc66fac3f807","originalAuthorName":"何峰"},{"authorName":"石勇","id":"cbd2e992-1bba-4386-8f1c-686790cde631","originalAuthorName":"石勇"}],"doi":"10.3969/j.issn.1003-0999.1999.04.004","fpage":"11","id":"5470c098-451d-4755-bc55-c11c8944ce1a","issue":"4","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":"8cd0daa2-29d0-495f-957b-dd7d633c4b1b","keyword":"去湿","originalKeyword":"去湿"},{"id":"ab345ba6-b4e3-4554-8b75-0798c9eaaab9","keyword":"吸湿","originalKeyword":"吸湿"},{"id":"bcbd181e-92b6-46f0-b41e-91a58d96db03","keyword":"人工海水","originalKeyword":"人工海水"},{"id":"cda0f013-1dbd-4ccc-ba78-6943558d0cb6","keyword":"复合材料","originalKeyword":"复合材料"}],"language":"zh","publisherId":"blgfhcl199904004","title":"复合材料去湿性能研究","volume":"","year":"1999"}],"totalpage":258,"totalrecord":2579}