{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"研究了元素Ti对贮氢电极合金ZrMn0.7V0.2Co0.1Ni1.2的相结构、相组成以及电化学性能的影响.结果表明,对于合金Zr1-xTix(Mn0.7V0.2Co0.1Ni1.2),其母体合金的主相为C15型Laves相,并含有少量的非Laves相Zr7M10;但随着掺Ti量的增加,合金中出现C14型Laves相,而且其含量逐渐增加;在x=0.1～0.2时,合金中还出现少量的TiNi相,而在x=0.4～0.5时,非Laves相Zr7M10和TiNi相全部消失,说明元素Ti大量的掺杂抑制了第二相的产生;而且随着Ti含量的增加,合金中的C15型和C14型Laves相的晶格常数逐渐减小.电化学测试结果发现,当含Ti量x=0.2时,合金有最大放电容量Cmax为354 mAh/g,在放电电流为300 mAh/g条件下,高倍率放电性能比母体合金提高了15%.","authors":[{"authorName":"李嵩","id":"d584e535-2339-49d0-b737-a040ebe36fad","originalAuthorName":"李嵩"},{"authorName":"季世军","id":"b263ec9d-7b87-4245-915c-8aca1e207739","originalAuthorName":"季世军"},{"authorName":"孙俊才","id":"8fee56f6-daf4-425e-937d-56e1cff20255","originalAuthorName":"孙俊才"}],"doi":"","fpage":"283","id":"8856d6bc-cd53-422c-936b-e84da6d8ab0b","issue":"2","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":"983039a4-5f9a-47bb-8119-36a23c345417","keyword":"Zr基Laves相","originalKeyword":"Zr基Laves相"},{"id":"7ac4642b-f29a-47b1-978a-51b673603e0d","keyword":"TiNi相","originalKeyword":"TiNi相"},{"id":"d1373141-e6e4-4411-88f3-643912ff9f93","keyword":"合金化","originalKeyword":"合金化"},{"id":"565c1177-02be-4113-b179-ab2305793a77","keyword":"电化学性质","originalKeyword":"电化学性质"}],"language":"zh","publisherId":"xyjsclygc200502027","title":"元素Ti对贮氢合金ZrMn0.7V0.2Co0.1Ni1.2相结构和电化学性能的影响","volume":"34","year":"2005"},{"abstractinfo":"研究了贮氢电极合金Zr1-xTixM0.7V0.2Co0.1Ni1.2的相结构和电化学性能.结果表明,随着掺Ti量的增加,该合金主相中C15型Laves相含量逐渐减少而C14型Laves相含量逐渐增加,同时非Laves相Zr7M10和TiNi相全部消失,说明元素Ti掺杂量的增加抑制了第二相的产生.当含Ti量x=0.2时,该合金具有最大放电容量Cmax为354mAh/g,在放电电流为300mAg/g条件下,高倍率放电性能比母体合金提高了15%.而对于合金Zr0.75Ti0.2La0.05Mn0.7V0.2Co0.1Ni1.2,其活化性能被大大提高,只需4次就能达到最大放电容量372mAh/g,而且经过30次循环仍能保持最大放电容量的93%.","authors":[{"authorName":"李嵩","id":"09485c93-3355-413b-a5c5-f02b6254549b","originalAuthorName":"李嵩"},{"authorName":"季世军","id":"32a3e59d-7cab-4d5a-9b53-9f35a14fc971","originalAuthorName":"季世军"},{"authorName":"孙俊才","id":"adbd0607-5904-481b-8bfa-750513d1a136","originalAuthorName":"孙俊才"}],"doi":"","fpage":"308","id":"8f478bc6-99a8-4ccd-aa58-98161a98537b","issue":"3","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"74bebbee-61b3-400f-9a9f-e4cb4fcb311b","keyword":"Zr基Laves相","originalKeyword":"Zr基Laves相"},{"id":"388e63f2-5af2-46db-b45f-7b7a6669dffa","keyword":"TiNi相","originalKeyword":"TiNi相"},{"id":"0d827666-e450-4007-857f-0c9acd7bfaf3","keyword":"合金化","originalKeyword":"合金化"},{"id":"45c4bb04-129c-410a-8789-9f05b9d31981","keyword":"高倍率性能","originalKeyword":"高倍率性能"},{"id":"65ab53b1-9847-4441-8ea5-7a3e1f49330b","keyword":"活化性能","originalKeyword":"活化性能"}],"language":"zh","publisherId":"gncl200403015","title":"Ti、La对贮氢合金ZrMn0.7 V0.2 Co0.1 Ni1.2相结构和电化学性能的影响","volume":"35","year":"2004"},{"abstractinfo":"研究了新型钛钒系贮氢电极合金Ti0.8Zr0.2V2.665Mn0.535Cr0.8Ni的相结构、微观组织及电化学性能.XRD及EDS分析表明: 铸态合金主要由C14 Laves相母体和树枝晶的钒基固溶体相组成, 同时由于成分偏析的缘故, 合金中还存在少量的TiNi基的第三相.热处理使得合金中C14 Laves相及钒基固溶体相的晶胞参数和晶胞体积增大, 促进合金成分的均匀化, 同时极大地改善了合金电极的综合电化学性能.","authors":[{"authorName":"朱云峰","id":"3079eb9f-3e4e-4b62-8262-ec9ea604f013","originalAuthorName":"朱云峰"},{"authorName":"潘洪革","id":"00a0d2ea-4491-4325-8a4f-0b732b43c17d","originalAuthorName":"潘洪革"},{"authorName":"刘永锋","id":"be1343f6-02da-4a34-b632-5a129143d1d7","originalAuthorName":"刘永锋"},{"authorName":"李锐","id":"ffdfe9dc-61ad-4b1c-9ef2-9b13865760be","originalAuthorName":"李锐"},{"authorName":"金勤伟","id":"44a7c9a8-6783-401b-8093-42f986f59cb1","originalAuthorName":"金勤伟"},{"authorName":"王启东","id":"fce006ed-3d7b-4edd-961e-d417bbd88b61","originalAuthorName":"王启东"}],"doi":"","fpage":"680","id":"9e264c9b-6b13-4043-a20a-e37f3eed4d96","issue":"3","journal":{"abbrevTitle":"ZGYSJSXB","coverImgSrc":"journal/img/cover/ZGYSJSXB.jpg","id":"88","issnPpub":"1004-0609","publisherId":"ZGYSJSXB","title":"中国有色金属学报"},"keywords":[{"id":"167d1690-d349-4574-9734-3b09b5b2c360","keyword":"钛","originalKeyword":"钛"},{"id":"57443196-3cf0-4878-8181-79739a477bed","keyword":"钒","originalKeyword":"钒"},{"id":"d6e62283-822b-4f39-b1cd-291b4c817ea9","keyword":"贮氢电极合金","originalKeyword":"贮氢电极合金"},{"id":"9e30213d-038e-4881-bfef-a9f274230e05","keyword":"C14 Laves相","originalKeyword":"C14 Laves相"},{"id":"4bab274f-93f4-4ffe-a7c8-ec5bcb66678f","keyword":"TiNi相","originalKeyword":"TiNi相"},{"id":"52e83604-cc66-4869-a00f-9a798bd9fa9b","keyword":"电化学性能","originalKeyword":"电化学性能"}],"language":"zh","publisherId":"zgysjsxb200303028","title":"新型钛钒系贮氢电极合金","volume":"13","year":"2003"},{"abstractinfo":"采用AgCu金属箔作中间过渡层,对TiNi形状记忆合金与不锈钢进行了瞬时液相扩散焊,分析了接头的显微组织、元素分布和物相组成等,研究了接头的抗剪强度和断裂方式.结果表明:接头界面区由TiNi侧过渡区,中间区,不锈钢侧过渡区组成,主要相分别为Ti (Cu,Ni,Fe),AgCu,TiFe等.连接温度为860℃,保温时间为60 min,连接压力为0.05 MPa时,接头最人抗剪强度为239 MPa.断裂发生在TiNi母材和AgCu中间层扩散界面上,断口为混合断裂形貌.通过中间层等温凝同过程动力学模型,结合界面形貌和元素扩散分析,认为TiNi SMA与不锈钢异种材料瞬时液相扩散焊过程存在明显的非对称性.","authors":[{"authorName":"李红","id":"3959565f-55a2-4a59-be62-e449edf171e4","originalAuthorName":"李红"},{"authorName":"栗卓新","id":"c5244a09-438d-4578-a255-62b679ccfbec","originalAuthorName":"栗卓新"},{"authorName":"汪应玲","id":"859aa344-d860-4580-99ad-566b6716972f","originalAuthorName":"汪应玲"},{"authorName":"冯吉才","id":"44214709-541d-4836-9ff6-755994c11be9","originalAuthorName":"冯吉才"}],"doi":"","fpage":"1382","id":"5006ffa5-ffc1-44b6-b03e-df3c5709a8e7","issue":"8","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":"78d2782a-5977-4e9c-9f1c-125a0ccdc2f2","keyword":"TiNi形状记忆合金","originalKeyword":"TiNi形状记忆合金"},{"id":"1a1e339a-edee-4358-bc94-64ba37c6925d","keyword":"不锈钢","originalKeyword":"不锈钢"},{"id":"d07ae95b-49f9-402a-baf3-9d4821bbb92e","keyword":"瞬时液相扩散焊","originalKeyword":"瞬时液相扩散焊"},{"id":"fab8462d-dad0-4043-b92a-5015e9b47ffc","keyword":"界面组织","originalKeyword":"界面组织"},{"id":"ba9c4853-e0d9-4e2e-b7a4-a34ed8361909","keyword":"等温凝固","originalKeyword":"等温凝固"},{"id":"eb4a69a0-150e-4599-a53e-1f73081cc84b","keyword":"非对称性","originalKeyword":"非对称性"}],"language":"zh","publisherId":"xyjsclygc201108013","title":"TiNi形状记忆合金不锈钢的瞬时液相扩散焊","volume":"40","year":"2011"},{"abstractinfo":"采用AgCu中间.过渡层,研究了连接温度、保温时间和连接压力对TiNi形状记忆合金与不锈钢瞬间液相扩散焊接头剪切强度的影响规律.本实验条件下连接温度为860℃,保温时间为60min,连接压力为0.05MPa时接头剪切强度最大为239.4MPa.通过扫描电镜(SEM)和X射线衍射仪(XRD)研究了最佳工艺参数下接头的元素分布和相组成,结果表明:接头生成了TiNi2,TiFe和Ti3Ni4等金属间化合物,从而影响接头性能.","authors":[{"authorName":"汪应玲","id":"6cf520ee-9772-458a-9ccd-fe671abdadc4","originalAuthorName":"汪应玲"},{"authorName":"李红","id":"ba1fcb25-0ed1-4fa9-af64-61935c9f8293","originalAuthorName":"李红"},{"authorName":"栗卓新","id":"fc9077fd-90e0-4ae4-a41f-0a65f9485ddd","originalAuthorName":"栗卓新"},{"authorName":"冯吉才","id":"c44eeffb-5919-4970-9106-61b7d99d4ccf","originalAuthorName":"冯吉才"}],"doi":"10.3969/j.issn.1001-4381.2008.09.013","fpage":"48","id":"2ca1b705-d3ff-4745-a0bd-9d8f72e368d9","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":"322dccf2-8a0a-4b00-861f-22be60f972b2","keyword":"TiNi形状记忆合金","originalKeyword":"TiNi形状记忆合金"},{"id":"d22ee6e8-eaa6-4289-87cb-8726739e1995","keyword":"不锈钢","originalKeyword":"不锈钢"},{"id":"c8d448a2-9326-417f-a9f2-090b710a30f8","keyword":"瞬间液相扩散焊","originalKeyword":"瞬间液相扩散焊"},{"id":"0b29117a-6540-4c80-8752-613a46208d5e","keyword":"剪切强度","originalKeyword":"剪切强度"}],"language":"zh","publisherId":"clgc200809013","title":"TiNi形状记忆合金与不锈钢瞬间液相扩散焊工艺研究","volume":"","year":"2008"},{"abstractinfo":"由于相变滞后，ＴｉＮｉ合金可以在同组成同温度下呈现不同的相结构（马氏体和奥氏体〕本文研究了不同相结构对其电化学性能的影响，发现奥氏体和马氏体相结构的吸放氢电化学热力学性能差别不大，但前者的动力学性能更优越．同时还用电阻法测试了ＴｉＮｉ中固溶氢量对相变点Ｍｓ的影响．","authors":[{"authorName":"王春生","id":"f63fa338-dc83-4dd9-9833-a317f4e55bbb","originalAuthorName":"王春生"},{"authorName":"雷永泉","id":"560c8744-d7a2-4a91-b215-5ad788081389","originalAuthorName":"雷永泉"},{"authorName":"杨晓光","id":"2d9c8b90-d455-458b-9f34-3513f2fa8e4a","originalAuthorName":"杨晓光"},{"authorName":"江建军","id":"0685e5e6-fc85-488c-ac35-89479d0db375","originalAuthorName":"江建军"},{"authorName":"吴京","id":"8833d199-ba20-4dd5-b492-5292b4634761","originalAuthorName":"吴京"},{"authorName":"王启东","id":"bdc8084a-cc04-4eac-b56f-7865fb50b0f4","originalAuthorName":"王启东"}],"categoryName":"|","doi":"","fpage":"440","id":"b0df555f-e4d3-4c06-8e3e-b3be944f6117","issue":"22","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"1bd881cc-ec5e-421d-873c-f35f011c6b17","keyword":"ＴｉＮｉ合金","originalKeyword":"ＴｉＮｉ合金"},{"id":"e5819a59-279c-4573-972d-dec9d7e385f3","keyword":" phase structure","originalKeyword":" phase structure"},{"id":"603213ee-9ae5-4c29-8637-e719a2a5148f","keyword":" electrochemical property","originalKeyword":" electrochemical property"}],"language":"zh","publisherId":"0412-1961_1995_22_3","title":"TiNi合金的相结构对电化学性能的影响","volume":"31","year":"1995"},{"abstractinfo":"The wear behavior of a TiNi alloy after various heat treatments has been studied in three conditions: sliding wear, impact abrasion and sand-blasting erosion. The results show that for all three conditions, the TiNi in a pseudoplastic state shows much better wear resistance as compared with that in a pseudoelastic state. The wear resistance of a TiNi alloy is mainly dependent on the recoverable strain limit, i.e. the sum of the pseudoelastic and pseudoplastic strain limits.","authors":[],"categoryName":"|","doi":"","fpage":"236","id":"1b3f1a3a-20f6-4baf-a777-23a7d43845f2","issue":"42737","journal":{"abbrevTitle":"W","id":"7b1ed076-e577-461f-af85-e75fe613a2b5","issnPpub":"0043-1648","publisherId":"W","title":"Wear"},"keywords":[{"id":"213fbf86-1324-462d-9a44-cbb413f3b7e3","keyword":"TiNi alloy;pseudoelasticity;pseudoplasticity;strain limit;wear;erosion","originalKeyword":"TiNi alloy;pseudoelasticity;pseudoplasticity;strain limit;wear;erosion"}],"language":"en","publisherId":"0043-1648_1996_42737_1","title":"Wear behavior of a TiNi alloy","volume":"198","year":"1996"},{"abstractinfo":"等原子比的TiNi合金除具有独特的形状记忆效应、超弹性效应和良好的耐磨耐蚀性外,还有着优异的阻尼性能,为当前几种最著名的高性能减振合金之一.用自蔓延高温合成(燃烧合成)法制备了孔洞发达、形状不规则、相对孔隙度50%左右的多孔TiNi合金.多孔体密度为3.15g/cm3,压缩强度270MPa,压缩变形率20%,压缩弹性模量2.5GPa.其阻尼性能比相同成分的致密TiNi合金提高了50%以上,对振动的衰减比致密TiNi合金高一个数量级.","authors":[{"authorName":"张小明","id":"ce5acd5f-255d-4425-abef-3e40b13087a7","originalAuthorName":"张小明"},{"authorName":"谭拴斌","id":"b8d40a68-6299-4de3-ab96-4555d1513117","originalAuthorName":"谭拴斌"},{"authorName":"王立新","id":"bef34a84-2b32-4054-bf04-d6ec24a13e8e","originalAuthorName":"王立新"},{"authorName":"王小鹏","id":"cace7349-584d-4301-88d4-6721ea91df27","originalAuthorName":"王小鹏"},{"authorName":"王学成","id":"2807d263-b4a9-44fe-9d69-58afb8a7769d","originalAuthorName":"王学成"}],"doi":"","fpage":"2153","id":"d63aa2f3-a0d6-45af-9103-40f2229b7c64","issue":"z1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"43e98fce-f7ec-4470-b929-a6e8923a973e","keyword":"高阻尼金属","originalKeyword":"高阻尼金属"},{"id":"d9519bd7-b58e-43fb-adb0-dcf656364498","keyword":"多孔材料","originalKeyword":"多孔材料"},{"id":"fb98d54f-0876-414b-ba78-1c5850630f59","keyword":"TiNi合金","originalKeyword":"TiNi合金"}],"language":"zh","publisherId":"gncl2004z1595","title":"高阻尼TiNi合金","volume":"35","year":"2004"},{"abstractinfo":"通过示差扫描量热分析(DSC)研究了预应变及约束条件下TiNi形状记忆合金的温度记忆效应. 结果表明, 通过变形约束手段, 可以大大拓宽TiNi合金的相变温度区间,使得TiNi合金的温度记忆效应能够在一个非常大的温度范围内发挥作用; 同时, 变形并约束后TiNi合金的温度记忆效应比自由态TiNi合金的温度记忆效应更加准确. 分析表明, 马氏体与母相界面处的位错以及界面处的弹性自适应过程是可能的温度记忆效应机.","authors":[{"authorName":"郑雁军","id":"6b9163cf-f0b3-41cd-814f-497807ac1ca3","originalAuthorName":"郑雁军"},{"authorName":"崔立山","id":"6311240d-d33b-4c8a-9b91-fa5a24ba00e7","originalAuthorName":"崔立山"}],"categoryName":"|","doi":"","fpage":"915","id":"ee0c4d93-222a-4340-87bb-c0222239436b","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"bb1704f7-5357-4e08-aa36-fe8b1a686a03","keyword":"TiNi合金","originalKeyword":"TiNi合金"},{"id":"28d3d3f6-0658-46a6-abce-17ee3d8df3ac","keyword":"shape memory alloy","originalKeyword":"shape memory alloy"},{"id":"907c0edd-ccaa-474a-88b0-504543e571c3","keyword":"incomplete transformation","originalKeyword":"incomplete transformation"}],"language":"zh","publisherId":"0412-1961_2004_9_9","title":"TiNi合金不完全相变的温度记忆效应","volume":"40","year":"2004"},{"abstractinfo":"通过示差扫描量热分析(DSC)研究了预应变及约束条件下TiNi形状记忆合金的温度记忆效应.结果表明,通过变形约束手段,可以大大拓宽TiNi合金的相变温度区间,使得TiNi合金的温度记忆效应能够在一个非常大的温度范围内发挥作用;同时,变形并约束后TiNi合金的温度记忆效应比自由态TiNi合金的温度记忆效应更加准确.分析表明,马氏体与母相界面处的位错以及界面处的弹性自适应过程是可能的温度记忆效应机制.","authors":[{"authorName":"郑雁军","id":"445b77a8-3622-48f0-9041-4069fcfe898a","originalAuthorName":"郑雁军"},{"authorName":"崔立山","id":"10ed262b-109f-4f30-a1ab-5bc4062aeef9","originalAuthorName":"崔立山"}],"doi":"10.3321/j.issn:0412-1961.2004.09.004","fpage":"915","id":"1030af1d-6a61-4020-9328-d3cfae1f846e","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"ecdd9ab1-2070-406e-b7e3-69a637d0f951","keyword":"TiNi合金","originalKeyword":"TiNi合金"},{"id":"53e4e995-bbab-48ec-9cac-0560cae20894","keyword":"形状记忆合金","originalKeyword":"形状记忆合金"},{"id":"62f16505-3e3f-42d6-9d4c-a6d95cfa5969","keyword":"不完全相变","originalKeyword":"不完全相变"},{"id":"42c6381c-d922-4314-8476-71c9ad714ae8","keyword":"温度记忆效应","originalKeyword":"温度记忆效应"}],"language":"zh","publisherId":"jsxb200409004","title":"TiNi合金不完全相变的温度记忆效应","volume":"40","year":"2004"}],"totalpage":3988,"totalrecord":39880}