{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"研究了不同热处理温度(510、550、590、630和670℃)×30min,对TA2/NiCr爆炸复合棒形变组织、硬度、成分扩散的影响.结果表明,随退火温度的提高,形变组织逐渐发生回复、再结晶和晶粒长大,硬度逐渐下降.在630℃退火时,覆层形变组织转变为细小的等轴组织,硬度较低,溶化层中晶内偏析基本消除,成分稳定,组织均匀,微裂纹得到愈合,且晶粒尺寸增大较为明显,细晶强化效果减弱,塑韧性将下降；低于630℃退火,覆层组织中仍有大量的形变组织,硬度较高.因而确定630℃为该爆炸复合棒的合适的热处理温度.","authors":[{"authorName":"朱协彬","id":"9307d50b-4c86-4057-9abf-57ab2fa15471","originalAuthorName":"朱协彬"},{"authorName":"陈伟","id":"29928042-847f-407b-bb94-59a90c749486","originalAuthorName":"陈伟"},{"authorName":"<span style=\"color:red\">汪</span><span style=\"color:red\">冰</span><span style=\"color:red\">锋</span>","id":"f9421915-b1ac-4dc3-8745-5415963d1fcd","originalAuthorName":"汪冰锋"},{"authorName":"姜涛","id":"54aac809-9c98-4bd2-b9fb-cc47df19ddd6","originalAuthorName":"姜涛"},{"authorName":"张孟","id":"26538c9c-fb3a-4874-9789-22aa194c19b8","originalAuthorName":"张孟"},{"authorName":"孙坤","id":"ed7ba8c4-8c8e-4803-b3e8-d24b998cc245","originalAuthorName":"孙坤"}],"doi":"10.3969/j.issn.1001-9731.2013.15.028","fpage":"2258","id":"73f1f944-66a3-4a65-aa22-90c1a07238f1","issue":"15","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"34cb6af1-3cbb-40d7-b165-0751bdde135a","keyword":"爆炸复合棒","originalKeyword":"爆炸复合棒"},{"id":"f4823db3-05da-4b07-ad51-61ba1dcf0960","keyword":"热处理温度","originalKeyword":"热处理温度"},{"id":"9a8be53c-c108-4dca-97d8-966706d5ef9c","keyword":"组织","originalKeyword":"组织"},{"id":"4892aaa8-f1bc-4c30-b919-0c3d9c7f88f6","keyword":"硬度","originalKeyword":"硬度"},{"id":"87bf8b26-0e7a-44c6-8c74-50a78ca42270","keyword":"成分","originalKeyword":"成分"},{"id":"e76ec6d4-5417-4966-b2dc-1781cb0abac0","keyword":"机理","originalKeyword":"机理"}],"language":"zh","publisherId":"gncl201315028","title":"退火温度对TA2/NiCr爆炸复合棒的影响机理研究","volume":"44","year":"2013"},{"abstractinfo":"现有的直接蒸发式<span style=\"color:red\">冰</span>蓄冷空调蓄<span style=\"color:red\">冰</span>槽内在融<span style=\"color:red\">冰</span>运行时都存在不利于传热的较大垂直温差.本文通过在蓄<span style=\"color:red\">冰</span>槽中下部位置处设置水平交叉盘管,使蓄<span style=\"color:red\">冰</span>槽内的坚直冰柱易于断裂,从而改善槽内自然对流条件,达到强化换热的目的.实验表明,水半盘管的布置明显减小了蓄<span style=\"color:red\">冰</span>槽内在融冰过程中的上下层温差,传热过程得到强化,融<span style=\"color:red\">冰</span>速度加快,制冷系统的COP也相应得到提高.","authors":[{"authorName":"肖睿","id":"031559bd-a300-4529-943c-8cc5abaadeb3","originalAuthorName":"肖睿"},{"authorName":"何世辉","id":"ecadd56c-8835-477e-8cec-6471d57668cd","originalAuthorName":"何世辉"},{"authorName":"杜艳利","id":"b0c5ebfa-ffda-45a7-84d1-aa4774108a39","originalAuthorName":"杜艳利"},{"authorName":"黄冲","id":"4f0c218a-379d-4f37-944c-3c5be148df28","originalAuthorName":"黄冲"},{"authorName":"冯自平","id":"ce1a7bd0-ea20-4424-a92e-3fa9714286cf","originalAuthorName":"冯自平"},{"authorName":"国德防","id":"2224e69b-fe5f-4bfa-bb47-10c86afcef1b","originalAuthorName":"国德防"},{"authorName":"崔昌学","id":"44fadee5-9628-476e-b53d-d558e7dea84f","originalAuthorName":"崔昌学"},{"authorName":"杜光林","id":"1cbee060-94ba-4991-a4ec-0f80cb6f54ef","originalAuthorName":"杜光林"}],"doi":"","fpage":"1524","id":"19e2f336-5a1c-400f-9866-4df90d921f05","issue":"9","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":"870ed182-186f-4b84-94c4-77b19daa9354","keyword":"直接蒸发","originalKeyword":"直接蒸发"},{"id":"afcecf35-c011-48e3-8e31-a7abb2967569","keyword":"<span style=\"color:red\">冰</span>蓄冷","originalKeyword":"冰蓄冷"},{"id":"1582b725-3d65-4c1b-a68f-e1b0cc58d03f","keyword":"蓄<span style=\"color:red\">冰</span>槽","originalKeyword":"蓄冰槽"},{"id":"f2421d4d-98d2-4155-ab8b-6674c4e36ae2","keyword":"水甲盘管","originalKeyword":"水甲盘管"},{"id":"92b69245-9cc4-4a93-9416-3774f904740c","keyword":"强化传热","originalKeyword":"强化传热"}],"language":"zh","publisherId":"gcrwlxb200809022","title":"直接蒸发式<span style=\"color:red\">冰</span>蓄冷空调的蓄<span style=\"color:red\">冰</span>槽融<span style=\"color:red\">冰</span>强化换热","volume":"29","year":"2008"},{"abstractinfo":"采用双<span style=\"color:red\">锋</span>角钻头和普通麻花钻对T700碳纤维复合材料(CFRP)进行钻削试验,从钻削轴向力、制孔出口质量和表面粗糙度等方面分析双<span style=\"color:red\">锋</span>角钻头在不同加工参数下制孔特点,并与普通麻花钻进行对比.试验结果表明:与普通麻花钻对比,双<span style=\"color:red\">锋</span>角钻头钻削CFRP时钻削轴向力减小约20％,制孔出口质量更好,孔壁的表面粗糙度值减小,体现优异的切削性能更适合CFRP的制孔加工.","authors":[{"authorName":"刘洋","id":"84b05ae5-a230-41ff-b807-1153de61c705","originalAuthorName":"刘洋"},{"authorName":"李鹏南","id":"ce579e61-f76f-484c-b690-a2f0dc957fae","originalAuthorName":"李鹏南"},{"authorName":"陈明","id":"55f42f01-21ff-4344-a87c-e23d5f0523bf","originalAuthorName":"陈明"},{"authorName":"邱新义","id":"46e7be67-8ed8-4643-866d-0b60fe3a811c","originalAuthorName":"邱新义"},{"authorName":"胡立湘","id":"daaff4cd-74ae-4036-9af8-a60665d7228a","originalAuthorName":"胡立湘"}],"doi":"10.3969/j.issn.1007-2330.2015.06.012","fpage":"53","id":"202f4754-37c9-42f9-afdf-6d82c39bd52e","issue":"6","journal":{"abbrevTitle":"YHCLGY","coverImgSrc":"journal/img/cover/YHCLGY.jpg","id":"77","issnPpub":"1007-2330","publisherId":"YHCLGY","title":"宇航材料工艺   "},"keywords":[{"id":"1af4de59-2086-474a-bec7-84f7ee6ae50b","keyword":"双<span style=\"color:red\">锋</span>角钻头","originalKeyword":"双锋角钻头"},{"id":"947a52d4-b948-47ab-8901-421d8ee8afe3","keyword":"CFRP","originalKeyword":"CFRP"},{"id":"24c898bd-96b6-4e32-8553-b90975356206","keyword":"钻削轴向力","originalKeyword":"钻削轴向力"},{"id":"ff98df70-d644-4a98-b0ed-ed4b53688240","keyword":"出口质量","originalKeyword":"出口质量"},{"id":"398d4903-6c1c-4810-b1cb-6542f6d54a30","keyword":"孔壁表面粗糙度","originalKeyword":"孔壁表面粗糙度"}],"language":"zh","publisherId":"yhclgy201506012","title":"双<span style=\"color:red\">锋</span>角钻头钻削碳纤维增强树脂基复合材料研究","volume":"45","year":"2015"},{"abstractinfo":"介绍了描述液滴润湿性的Young、Wenzel和Cassie模型,概述了静、动态疏水性与疏<span style=\"color:red\">冰</span>之间的关系,综述了疏水疏<span style=\"color:red\">冰</span>涂层的制备方法,以及<span style=\"color:red\">冰</span>粘接强度的主要影响因素和测量方法,指出了疏水疏<span style=\"color:red\">冰</span>涂层将来的研究方向.","authors":[{"authorName":"陈名华","id":"272b9be8-679f-45d8-b127-9d823b50a5fa","originalAuthorName":"陈名华"},{"authorName":"郭必新","id":"f860ef01-b4ad-4c8c-9828-0d641248e0ec","originalAuthorName":"郭必新"},{"authorName":"<span style=\"color:red\">汪</span>定江","id":"1ab54e6c-1622-4ab6-96a6-680cc979403d","originalAuthorName":"汪定江"},{"authorName":"葛文军","id":"75848262-59fc-4d28-a124-27c52fc0a5ff","originalAuthorName":"葛文军"}],"doi":"","fpage":"55","id":"211330f3-ca3c-45b9-8328-b7fa51723e03","issue":"7","journal":{"abbrevTitle":"DDYTS","coverImgSrc":"journal/img/cover/DDYTS.jpg","id":"21","issnPpub":"1004-227X","publisherId":"DDYTS","title":"电镀与涂饰   "},"keywords":[{"id":"97964a6a-adbd-4024-81ba-d2f0dbdb6549","keyword":"涂层","originalKeyword":"涂层"},{"id":"09e5add9-254e-43c8-b73a-79dfe9eff25f","keyword":"疏水","originalKeyword":"疏水"},{"id":"f1246b9f-913a-412b-b896-79d9e793cd95","keyword":"疏<span style=\"color:red\">冰</span>","originalKeyword":"疏冰"},{"id":"32aaa7b7-5169-4522-a88d-40ccf801dd40","keyword":"接触角","originalKeyword":"接触角"},{"id":"1925a009-9848-4f39-bf2b-466747da9e9f","keyword":"表面粗糙度","originalKeyword":"表面粗糙度"},{"id":"120d14a2-5643-40de-8223-b5317623028e","keyword":"<span style=\"color:red\">冰</span>粘接强度","originalKeyword":"冰粘接强度"}],"language":"zh","publisherId":"ddyts201107015","title":"疏水疏<span style=\"color:red\">冰</span>涂层的研究进展","volume":"30","year":"2011"},{"abstractinfo":"为制备一种具备高憎水性、可降低水冰点的融<span style=\"color:red\">冰</span>型防覆<span style=\"color:red\">冰</span>涂料,筛选出能降低水的固-液相转变温度的金属有机化合物,并对含金属有机化合物的低冰点型融<span style=\"color:red\">冰</span>涂料进行了研究.结果表明:制备的低冰点型融<span style=\"color:red\">冰</span>涂料可将水的冰点温度由0℃降至约-4℃,并能使垂直白铁片试样上的覆<span style=\"color:red\">冰</span>在9 h后完全脱落,融<span style=\"color:red\">冰</span>和脱<span style=\"color:red\">冰</span>效果显著.在绝缘子上试验时,可观察到涂层与覆<span style=\"color:red\">冰</span>界面间有液态水出现,随着时间的延长,融冰点逐渐增多、扩大,融<span style=\"color:red\">冰</span>效果显著.由于绝缘子伞倾角较小,其冰层难以自然脱落.为实现工程应用,可考虑使用伞倾角较大的绝缘子,以增强脱<span style=\"color:red\">冰</span>效果.","authors":[{"authorName":"张锐","id":"d8d514e1-01b1-44d4-8844-c808882e2ed4","originalAuthorName":"张锐"},{"authorName":"易辉","id":"ee530f3b-1191-432f-ba06-a95601a18511","originalAuthorName":"易辉"},{"authorName":"万小东","id":"46b2ae77-9001-4be3-9e1c-06f28cf9024e","originalAuthorName":"万小东"},{"authorName":"吴仲岿","id":"a0e42c9f-dfb1-4093-9e27-3ba96c6e9cf9","originalAuthorName":"吴仲岿"}],"doi":"","fpage":"22","id":"2f4957bc-69bd-4c45-a378-b73e7a05bccf","issue":"4","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"0f6c93bd-0dae-42b0-9faa-e73bdfebd387","keyword":"输电线路","originalKeyword":"输电线路"},{"id":"6d7276d4-48b3-4b8a-8286-0636db825fda","keyword":"绝缘子","originalKeyword":"绝缘子"},{"id":"c2ea7190-0d52-4b6a-a933-df5fe3cb2dd5","keyword":"防覆<span style=\"color:red\">冰</span>涂料","originalKeyword":"防覆冰涂料"}],"language":"zh","publisherId":"jycltx201204006","title":"输电线路绝缘子用融<span style=\"color:red\">冰</span>型防覆<span style=\"color:red\">冰</span>涂料的研究","volume":"","year":"2012"},{"abstractinfo":"为研究覆<span style=\"color:red\">冰</span>复合绝缘子的电气特性,基于ANSYS有限元法建立了330 kV覆<span style=\"color:red\">冰</span>复合绝缘子模型,分别模拟仿真了干、湿覆<span style=\"color:red\">冰</span>情况下,不同空气间隙位置及<span style=\"color:red\">冰</span>棱长度对覆<span style=\"color:red\">冰</span>复合绝缘子的沿面电场、电位分布的影响,并与清洁复合绝缘子进行比较分析.结果表明:与清洁复合绝缘子相比,覆<span style=\"color:red\">冰</span>明显畸变了复合绝缘子的沿面电场和电位分布;当覆<span style=\"color:red\">冰</span>未完全桥接大伞裙间时,随着<span style=\"color:red\">冰</span>棱长度的增长,对沿面电位和电场分布的畸变程度越严重.当融冰过程中形成水膜时,覆<span style=\"color:red\">冰</span>复合绝缘子的沿面电场和电位分布进一步畸变,此时更容易发生局部放电.","authors":[{"authorName":"张瑞峰","id":"5be4161e-766b-430a-8008-6610ce30a5a3","originalAuthorName":"张瑞峰"},{"authorName":"贾冬明","id":"4c54963a-ddef-4e95-8820-49fc4279b243","originalAuthorName":"贾冬明"},{"authorName":"杨晓辉","id":"0b70e9bb-be2e-436f-bce3-1122ebf36c60","originalAuthorName":"杨晓辉"},{"authorName":"柴永忠","id":"479bba3b-5ed6-43f2-a80a-9ddd20b4ae32","originalAuthorName":"柴永忠"}],"doi":"","fpage":"42","id":"81f8db50-d78e-4dd9-9ebd-ddd0edf86f5a","issue":"9","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"a842c468-db42-45f8-9388-c0ae8065ee70","keyword":"覆<span style=\"color:red\">冰</span>复合绝缘子","originalKeyword":"覆冰复合绝缘子"},{"id":"a49c8a9a-4cfb-46b1-b79f-1405c4fed922","keyword":"有限元法","originalKeyword":"有限元法"},{"id":"99457fe0-bd82-4d15-a1e7-b1e3c7c24b42","keyword":"电场和电位分布","originalKeyword":"电场和电位分布"},{"id":"e7450090-4810-4519-8c72-114c8fd75783","keyword":"覆<span style=\"color:red\">冰</span>","originalKeyword":"覆冰"}],"language":"zh","publisherId":"jycltx201509010","title":"覆<span style=\"color:red\">冰</span>复合绝缘子电场分布的研究","volume":"","year":"2015"},{"abstractinfo":"风力机叶片覆<span style=\"color:red\">冰</span>会使风力发电效率下降并且威胁风力机组的安全运行.本文采用Fluent中的欧拉多相流模型,通过添加质量传递以及对流换热系数计算模型等,实现了对风力机叶片表面覆<span style=\"color:red\">冰</span>的二维数值模拟,结果表明:覆<span style=\"color:red\">冰</span>主要出现在叶片的前缘迎风面,且驻点附近覆<span style=\"color:red\">冰</span>最多;当增大翼型攻角时,驻点向翼型的下部尾部移动,最大覆<span style=\"color:red\">冰</span>位置也相应地移动;随着时间的推移,叶片表面覆<span style=\"color:red\">冰</span>增多.","authors":[{"authorName":"马强","id":"fb5bfd0d-9f1f-4bf2-8eec-e123222888be","originalAuthorName":"马强"},{"authorName":"吴晓敏","id":"56a30636-f037-4276-afb1-721c30f49225","originalAuthorName":"吴晓敏"},{"authorName":"陈彦","id":"55b070a8-f9a3-4c8b-ab90-649a47711872","originalAuthorName":"陈彦"}],"doi":"","fpage":"770","id":"1ca90c2b-541f-411a-92e4-7513e2f7ccee","issue":"4","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":"11bf71ee-28b3-4549-bea6-3e2d3446037a","keyword":"风力机叶片","originalKeyword":"风力机叶片"},{"id":"4a187946-bdc1-46ad-91a6-f2522b3174a8","keyword":"覆<span style=\"color:red\">冰</span>","originalKeyword":"覆冰"},{"id":"3ac28a88-6105-4efe-b021-e10a9fe2a249","keyword":"数值模拟","originalKeyword":"数值模拟"},{"id":"f2a8914c-ffe1-474b-8a6f-b5a25be3fce0","keyword":"多相流","originalKeyword":"多相流"}],"language":"zh","publisherId":"gcrwlxb201404034","title":"风力机叶片覆<span style=\"color:red\">冰</span>的数值模拟","volume":"35","year":"2014"},{"abstractinfo":"针对碳纤维复合材料钻孔时易产生撕裂、毛刺等缺陷的特点,采用双<span style=\"color:red\">锋</span>角钻头为研究对象,从横刃、第一主切削刃和第二主切削刃对孔入、出口缺陷的影响和加工参数对撕裂因子的影响规律等方面分析双<span style=\"color:red\">锋</span>角钻头钻孔特点,并与普通麻花钻进行对比.结果表明:在相同的加工参数下,双<span style=\"color:red\">锋</span>角钻头双主切削刃加工特点降低了入、出口钻削轴向力,有效抑制了入、出口撕裂、毛刺等缺陷产生,更适合于钻削碳纤维复合材料.主轴转速增大有利于减小撕裂因子,随着进给速度的增加撕裂因子呈增大的趋势.采用多元线性回归方法建立了试验两种钻头钻孔入、出口的撕裂因子与加工参数之间的回归预测模型.","authors":[{"authorName":"刘洋","id":"966991ac-40c3-4875-8fd2-5b254e51bab2","originalAuthorName":"刘洋"},{"authorName":"李鹏南","id":"f70e8d0c-8f66-4fe0-a0b8-89fc90f23a9d","originalAuthorName":"李鹏南"},{"authorName":"陈明","id":"5a679404-8ab9-4f72-8a43-2fde8d54c118","originalAuthorName":"陈明"},{"authorName":"邱新义","id":"c567763e-9ce3-4518-bee6-18ca1d9984fb","originalAuthorName":"邱新义"},{"authorName":"唐玲艳","id":"45da4e46-afc1-46ee-9b1c-01a993fdbba2","originalAuthorName":"唐玲艳"}],"doi":"10.3969/j.issn.1007-2330.2016.05.010","fpage":"54","id":"3aaf2b66-afa4-41ec-b17b-2954ec79382d","issue":"5","journal":{"abbrevTitle":"YHCLGY","coverImgSrc":"journal/img/cover/YHCLGY.jpg","id":"77","issnPpub":"1007-2330","publisherId":"YHCLGY","title":"宇航材料工艺   "},"keywords":[{"id":"31166d84-6bb5-4c0e-991f-0f201e34d1de","keyword":"双<span style=\"color:red\">锋</span>角钻头","originalKeyword":"双锋角钻头"},{"id":"377dc73b-e7a1-4001-a38e-77321d24af6f","keyword":"碳纤维复合材料","originalKeyword":"碳纤维复合材料"},{"id":"93eaf4f3-544c-4102-9b93-eb0e951ecdcb","keyword":"撕裂","originalKeyword":"撕裂"},{"id":"7fac6586-e313-4ed4-801f-df1e527ded55","keyword":"加工参数","originalKeyword":"加工参数"}],"language":"zh","publisherId":"yhclgy201605010","title":"双<span style=\"color:red\">锋</span>角钻头钻削碳纤维增强树脂基复合材料钻孔缺陷的研究","volume":"46","year":"2016"},{"abstractinfo":"本文利用自行设计的新型表面覆<span style=\"color:red\">冰</span>垂直粘结强度测试装置，测试了不同材料表面的覆<span style=\"color:red\">冰</span>垂直粘结强度，并探讨了基体表面粗糙度、冻冰时间、冰层厚度、冻冰温度等因素对同一材料表面覆<span style=\"color:red\">冰</span>垂直粘结强度的影响。结果发现，覆<span style=\"color:red\">冰</span>垂直粘结强度随着材料表面粗糙度增加而增大，随着冰冻温度的升高而降低。而冻冰时间与冰层厚度对覆<span style=\"color:red\">冰</span>垂直粘结强度的影响较为复杂。","authors":[{"authorName":"王国刚","id":"0c193b42-0156-41af-9eba-6319232b4088","originalAuthorName":"王国刚"},{"authorName":"穆静静","id":"a7961a20-5334-403d-af45-6fbbc0ed7ae8","originalAuthorName":"穆静静"},{"authorName":"周红伟","id":"cf3a700a-0a6d-4f67-ac36-1f85133dbb20","originalAuthorName":"周红伟"},{"authorName":"苗文华","id":"e4d5993b-d33c-487a-ad09-e7bd992a5e8a","originalAuthorName":"苗文华"},{"authorName":"刘中良","id":"dbb3e3e8-e50a-476d-b98c-5e446b3d78d8","originalAuthorName":"刘中良"},{"authorName":"刘耀民","id":"6cb9f298-99bd-4fb7-bc8d-d4af291492ab","originalAuthorName":"刘耀民"}],"doi":"","fpage":"282","id":"e4d4f814-fcf9-4a3c-805e-9980de6262b4","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":"e3bc6184-6feb-493d-ae96-befd8a673b73","keyword":"覆<span style=\"color:red\">冰</span>","originalKeyword":"覆冰"},{"id":"80946a03-0060-4e08-8cbc-e8a677c13936","keyword":"垂直粘结强度","originalKeyword":"垂直粘结强度"},{"id":"bb780dcd-9d75-4e82-93c8-7177ecbdd006","keyword":"测试装置","originalKeyword":"测试装置"}],"language":"zh","publisherId":"gcrwlxb201202026","title":"覆<span style=\"color:red\">冰</span>垂直粘结强度的测试研究","volume":"33","year":"2012"},{"abstractinfo":"为研究重<span style=\"color:red\">冰</span>区覆<span style=\"color:red\">冰</span>对交流输电线路参数的影响，分析了线路覆<span style=\"color:red\">冰</span>对弧垂的影响以及弧垂对线路参数的影响。在MATLAB环境下，对同塔双回交流输电线路利用线路参数计算软件仿真验证弧垂变化对线路参数的影响。结果表明：覆<span style=\"color:red\">冰</span>对零序参数有较大影响，实际应用中需考虑该影响因素，在覆<span style=\"color:red\">冰</span>较厚情况下应对零序参数进行修正。","authors":[{"authorName":"魏延勋","id":"5337b142-30f6-4e63-bab5-f210233137f5","originalAuthorName":"魏延勋"},{"authorName":"朱清海","id":"a373a7e2-3d13-40ae-8930-def8b7bb0092","originalAuthorName":"朱清海"},{"authorName":"肖致黔","id":"43ad6c09-61dd-4a4c-b14e-d2bd938cf7c0","originalAuthorName":"肖致黔"},{"authorName":"王楠","id":"f96c5e43-c91d-467f-b682-f20f87cc3992","originalAuthorName":"王楠"},{"authorName":"周野","id":"86453e15-f149-4167-a359-fdf46b71d29c","originalAuthorName":"周野"}],"doi":"","fpage":"64","id":"486eede9-6cc9-4bd3-bfb3-7d7005b59608","issue":"10","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"f4684543-86f3-4b32-88b0-1835157319c1","keyword":"输电线路","originalKeyword":"输电线路"},{"id":"7f95314b-03fa-4e86-9623-6108cde18625","keyword":"覆<span style=\"color:red\">冰</span>","originalKeyword":"覆冰"},{"id":"63a2babd-8e03-4b3f-a1a9-85e809077673","keyword":"弧垂","originalKeyword":"弧垂"},{"id":"414805cc-45a7-4fde-9dde-93c718b5c909","keyword":"零序参数","originalKeyword":"零序参数"}],"language":"zh","publisherId":"jycltx201510014","title":"重<span style=\"color:red\">冰</span>区覆<span style=\"color:red\">冰</span>对同塔双回交流输电线路参数的影响研究","volume":"","year":"2015"}],"totalpage":15,"totalrecord":145}