{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"导热系数是衡量纳米流体强化换热的最重要的参数,但在不同学者的研究中,对于同一种纳米流体所测得的导热系数却有很大差别.本文针对影响纳米流体导热系数实验测量的因素进行研究,在相同的实验条件下,分别运用Hotdisk导热仪和闪光法导热仪对水基二氧化钛纳米流体的导热系数进行了测量.实验结果表明,用Hotdisk法的测量结果比用闪光法测得的高21%~34%.通过计算分析发现:自然对流是引起纳米流体导热系数测量结果多变的重要原因之一.","authors":[{"authorName":"李兴","id":"6c021f18-3715-455e-bef6-820c5edf3496","originalAuthorName":"李兴"},{"authorName":"陈颖","id":"d5778ec4-c325-4e05-ba53-beed3c8237f7","originalAuthorName":"陈颖"},{"authorName":"莫松平","id":"8bf5a12d-c2a9-4c13-b45c-a47674c86869","originalAuthorName":"莫松平"},{"authorName":"刘琢玮","id":"a4b75957-fab7-42d8-976f-9feff88d8da7","originalAuthorName":"刘琢玮"}],"doi":"","fpage":"592","id":"ee47e3af-979e-43fd-b413-b93b8e20983b","issue":"4","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":"e2bb713f-cd45-4a1c-b12a-f3451fccbdbb","keyword":"纳米流体","originalKeyword":"纳米流体"},{"id":"716136a0-1a55-489d-88f3-cbb7012fe8b6","keyword":"导热系数","originalKeyword":"导热系数"},{"id":"c12bee2a-d63c-4e05-8847-26d6027fc2d4","keyword":"实验测试法","originalKeyword":"实验测试法"},{"id":"93b1c72b-aa24-4189-850f-0fa5003e5890","keyword":"自然对流","originalKeyword":"自然对流"},{"id":"864585eb-a954-44b7-90b1-6f8510527309","keyword":"分散剂","originalKeyword":"分散剂"}],"language":"zh","publisherId":"clkxygc201304025","title":"影响纳米流体导热系数实验测试的因素","volume":"31","year":"2013"},{"abstractinfo":"介绍了涂料工业中常用的几种测量粒度及粒度分布的方法及适用范围,并从几个方面阐述了激光衍射粒度测试法作为一种新颖的颗粒粒度测量技术在涂料工业中的应用.","authors":[{"authorName":"黄宁","id":"57a5a051-31af-40c1-a03f-56c8436c9307","originalAuthorName":"黄宁"},{"authorName":"周湘玲","id":"b94b030a-2db2-43b9-87fe-d77f352e0a17","originalAuthorName":"周湘玲"},{"authorName":"张永刚","id":"28a484d2-9622-4cd0-8492-072160d5cfef","originalAuthorName":"张永刚"}],"doi":"10.3969/j.issn.0253-4312.2006.09.013","fpage":"43","id":"c36a5763-fd62-4b85-a76d-f1b5698e1429","issue":"9","journal":{"abbrevTitle":"TLGY","coverImgSrc":"journal/img/cover/TLGY.jpg","id":"61","issnPpub":"0253-4312","publisherId":"TLGY","title":"涂料工业 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"},"keywords":[{"id":"f3c6d9eb-54e2-419b-9a3b-10e9bb8463eb","keyword":"粒度分布分维","originalKeyword":"粒度分布分维"},{"id":"29671363-b6b5-4ab3-b4c1-d34c23f58dce","keyword":"粉体流动性","originalKeyword":"粉体流动性"},{"id":"145ab201-2ec7-449d-8846-2aecdab8ff88","keyword":"卡尔指数","originalKeyword":"卡尔指数"},{"id":"d37a1a98-e593-47d2-b6e4-1265655f7b56","keyword":"图像处理","originalKeyword":"图像处理"}],"language":"zh","publisherId":"gsytb200606011","title":"粉体颗粒流动性的分形维测试法","volume":"25","year":"2006"},{"abstractinfo":"研究了圆柱腔体共振频率的测量方法,测试了新建立的声速实验系统,结果显示圆柱共鸣腔具有较高的信噪比,共振频率的测量不确定度小于5×10^-6.采用Ar气(99.999%)标定了声速共鸣腔的有效长度,不确定度为1.8×10^-5。开展了303~333K下CO2的气相声速实验研究,实验结果表明,当实验工质具有较高的纯度(〉99.995%)时,气相声速的测量精度优于0.01%。","authors":[{"authorName":"冯晓娟","id":"a61f4481-24f6-465d-9e03-1fd7f7a0452a","originalAuthorName":"冯晓娟"},{"authorName":"刘强","id":"e2c5ee44-e45d-4fcd-bd2e-e721a6ceb047","originalAuthorName":"刘强"},{"authorName":"周孟夏","id":"35d7bf9e-fbd8-4e7c-8352-4c3b0fdcd454","originalAuthorName":"周孟夏"},{"authorName":"林鸿","id":"aa315b36-2986-49c5-a9b3-127be0e57634","originalAuthorName":"林鸿"},{"authorName":"段远源","id":"b16f9085-a1a8-4d5a-bd80-ca32e44b72d7","originalAuthorName":"段远源"}],"doi":"","fpage":"7","id":"61c5827a-e210-40c2-8182-10371eb94736","issue":"1","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":"15b60fbb-17af-47c6-875b-78cbd794cfee","keyword":"圆柱定程干涉","originalKeyword":"圆柱定程干涉"},{"id":"b07dffc3-b495-4d05-9b28-59230f4ea3d1","keyword":"气相声速","originalKeyword":"气相声速"},{"id":"33304cff-6a55-4e8d-b40e-5443cab68ba7","keyword":"频率测量","originalKeyword":"频率测量"},{"id":"6ce7bc64-1e50-42d9-a086-93cae4c6f155","keyword":"CO2","originalKeyword":"CO2"}],"language":"zh","publisherId":"gcrwlxb201201002","title":"圆柱定程干涉法声速测量系统的实验测试","volume":"33","year":"2012"},{"abstractinfo":"评述了用鼓膜实验方法测试薄膜与基体界面结合强度的现状和最新进展,分析了该方法针对圆孔、膜内无残余应力柔性膜试样和矩形孔或圆孔、膜内有残余应力试样(薄膜为柔性膜或刚性膜)所用解析解力学模型建立的薄膜力学性能假设前提条件、能量平衡思路和推导过程.介绍了用硅微技术制备Si基体试样的过程,指出了制备方法和解析解力学模型的特点及所存在的问题.给出了该实验方法的应用实例,指出了需要解决非硅基体的制样和薄膜塑性变形阶段力学模型等问题.","authors":[{"authorName":"任凤章","id":"7eb1e9f6-bd3b-4d6c-986d-80bfc0aedcbb","originalAuthorName":"任凤章"},{"authorName":"郑茂盛","id":"bed5218d-b7c4-4535-b663-79cd6e791594","originalAuthorName":"郑茂盛"},{"authorName":"刘平","id":"74e97b53-57d6-463c-96bb-e451eff76d14","originalAuthorName":"刘平"},{"authorName":"贾淑果","id":"881bfbcf-c318-4e6f-b083-237491efccc6","originalAuthorName":"贾淑果"},{"authorName":"JU Xihua","id":"dc195b11-1240-47cb-81a7-585c54321cce","originalAuthorName":"JU Xihua"},{"authorName":"马战红","id":"8c5e6354-17b2-4b72-bee9-b5dc8cbb4233","originalAuthorName":"马战红"},{"authorName":"祝要民","id":"41e64d7b-473f-4ada-8c49-e8ec6503497a","originalAuthorName":"祝要民"}],"doi":"10.3321/j.issn:1005-3093.2006.04.002","fpage":"346","id":"2a2a636e-b71f-4925-a863-fa598ad69ba0","issue":"4","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"01363f35-dd04-414c-a1de-b846ceabd91b","keyword":"薄膜","originalKeyword":"薄膜"},{"id":"f59238f0-039b-4dc8-9c00-70b36cbb2223","keyword":"鼓膜实验","originalKeyword":"鼓膜实验"},{"id":"c28b965b-96cb-42c4-b85b-99c3493be75f","keyword":"界面结合强度","originalKeyword":"界面结合强度"},{"id":"b4ac61b8-d397-43b4-8da3-e215491b2546","keyword":"力学模型","originalKeyword":"力学模型"},{"id":"142758fc-87a7-431a-9eea-e2b6650d8116","keyword":"残余应力","originalKeyword":"残余应力"}],"language":"zh","publisherId":"clyjxb200604002","title":"鼓膜实验法测试薄膜基体界面结合强度的进展","volume":"20","year":"2006"},{"abstractinfo":"文中对用Zn空心阴极灯作光源测定Cu与Cu空心阴极灯测定Cu,用Cd空心阴极灯作光源测定Ag与Ag空心阴极灯测定Ag,用Ca空心阴极灯作光源测定Mg与Mg空心阴极灯测定Mg,进行了比较实验研究.通过实验发现,可以用Zn空心阴极灯代替Cu空心阴极灯测定Cu,用Cd空心阴极灯代替Ag空心阴极灯测定Ag,用Ca空心阴极灯代替Mg空心阴极灯测定Mg;其测定检出限相近、精密度高.用国家地球化学标准样品GBW 07401(GSS-1)、GBW 07311(GSD-11)进行验证,其准确度较好.","authors":[{"authorName":"聂凤莲","id":"d40533ea-ccc2-4372-a554-1a4bc99081b4","originalAuthorName":"聂凤莲"},{"authorName":"张蜀冀","id":"a1aac8bf-49e8-48b2-898d-7db8d9c9c54f","originalAuthorName":"张蜀冀"},{"authorName":"陈雪","id":"5c35c069-5279-40f1-8b2d-d146007b0be3","originalAuthorName":"陈雪"},{"authorName":"陈占生","id":"c581ea40-c331-4c52-845e-03fdef4fba68","originalAuthorName":"陈占生"}],"doi":"10.3969/j.issn.1001-1277.2010.11.014","fpage":"50","id":"1de34f20-95e4-4ca0-9943-dd93aaf7c632","issue":"11","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"4efa83d2-21f7-4dc2-abd6-794a82551d8e","keyword":"原子吸收光谱法","originalKeyword":"原子吸收光谱法"},{"id":"8e3cf96a-5606-4f96-8511-a02feddd1603","keyword":"分析测试","originalKeyword":"分析测试"},{"id":"a50d5c8b-8b4c-481e-a0ee-179d80959620","keyword":"实验研究","originalKeyword":"实验研究"}],"language":"zh","publisherId":"huangj201011014","title":"原子吸收光谱法一灯多用技术在分析测试中的实验研究","volume":"31","year":"2010"},{"abstractinfo":"采用标准约定的方法,测试了氧化铝和氧化锆等典型精细陶瓷的硬度,验证了方法的可行性;同时,改变实验条件进行测试,对影响精细陶瓷硬度测试结果的因素及原因进行了探讨.","authors":[{"authorName":"运新跃","id":"0aadc52f-1e0c-4397-93d6-88fbd07c942d","originalAuthorName":"运新跃"},{"authorName":"蒋丹宇","id":"dafc0b1a-4c87-4baf-9d1c-1b44ec079d68","originalAuthorName":"蒋丹宇"},{"authorName":"周丽玮","id":"b2a8aeb3-55d9-4628-9ccd-18c5d9c09132","originalAuthorName":"周丽玮"},{"authorName":"高建华","id":"fc95f0da-79d0-42c8-8664-86e88ea9871a","originalAuthorName":"高建华"},{"authorName":"朱国强","id":"47df3c5d-606d-4e85-8c0a-8f67bb75af48","originalAuthorName":"朱国强"},{"authorName":"吴皓","id":"33670a44-f60d-47aa-8575-11df8bb857f9","originalAuthorName":"吴皓"}],"doi":"","fpage":"1158","id":"a82024d0-b422-4b4e-9121-97e7015d86f0","issue":"z2","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":"66c992a1-51b3-44bd-b32f-83312fc9bb74","keyword":"精细陶瓷","originalKeyword":"精细陶瓷"},{"id":"9bfaa980-9274-454d-8a90-69cf5df24ae1","keyword":"硬度测试","originalKeyword":"硬度测试"},{"id":"ba9d2c54-a966-4f91-a3dc-351e0408ff54","keyword":"实验验证","originalKeyword":"实验验证"}],"language":"zh","publisherId":"xyjsclygc2009z2307","title":"精细陶瓷硬度测试方法实验验证","volume":"38","year":"2009"},{"abstractinfo":"混凝土渗透性是表征其耐久性的一项重要指标.现场混凝土与实验室混凝土有很大差异,因此现场混凝土渗透性的就地测试尤为重要.对国内外可用于混凝土渗透性的就地测试方法研究进展进行了综合评述,这些方法可分为表面测试法和钻孔测试法两大类.表面测试方法中的Autoclam测试方法操作简单、应用范围广,钻孔测试法对混凝土结构有一定的损害,并且不能测试有表面处理的试件.Permit试验法是较好的现场测试离子渗透的测试方法.最后就混凝土渗透性就地测试方法的进一步研究和改进提出建议.","authors":[{"authorName":"贾路风","id":"2e42888e-30fb-4acc-8f77-7ac27376118b","originalAuthorName":"贾路风"},{"authorName":"史才军","id":"511404c2-8555-427b-b30f-dfc40651a792","originalAuthorName":"史才军"},{"authorName":"曹张","id":"9049e5ad-e741-498e-b588-a35b2258f2e0","originalAuthorName":"曹张"},{"authorName":"王德辉","id":"a89f4f7f-4759-4a04-9166-ec3ca04a8404","originalAuthorName":"王德辉"},{"authorName":"胡张莉","id":"b3933b4e-16c6-435b-8e94-7b1060c3b1bc","originalAuthorName":"胡张莉"},{"authorName":"吴泽媚","id":"679385bc-748c-4713-b09f-f46344e8bfb6","originalAuthorName":"吴泽媚"},{"authorName":"欧志华","id":"5e0f4ffc-9308-4120-b631-15c7f5e611f3","originalAuthorName":"欧志华"}],"doi":"","fpage":"106","id":"6a2983dc-4c1a-40d2-91bc-2ec2b2c2ac55","issue":"21","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"48aecad2-203d-4364-96fc-5f102c928e37","keyword":"渗透性","originalKeyword":"渗透性"},{"id":"c1eeaf9d-3879-4bd9-9aaa-366574496033","keyword":"就地测试方法","originalKeyword":"就地测试方法"},{"id":"9fa096bd-c272-4151-9a46-466cf589455a","keyword":"耐久性","originalKeyword":"耐久性"},{"id":"effd771e-cf28-4028-8d15-436349279656","keyword":"混凝土","originalKeyword":"混凝土"}],"language":"zh","publisherId":"cldb201321022","title":"混凝土渗透性的就地测试方法综述","volume":"27","year":"2013"},{"abstractinfo":"钢包是冶金生产中的重要设备,其使用寿命的长短对企业生产有直接影响.利用有限元法建立了钢包的温度分布模型,针对实际工况确定了可行的测试方案,并进行了测试实验.结果表明,测试得到的温度值与计算的结论基本吻合.","authors":[{"authorName":"蒋国璋","id":"2f333913-b426-4bfb-b67d-4c65b6f1beb3","originalAuthorName":"蒋国璋"},{"authorName":"孔建益","id":"b5c91cd9-556c-4a74-8703-0631b7c5ca81","originalAuthorName":"孔建益"},{"authorName":"李公法","id":"f13abe37-b2d2-41fe-bf39-c1748a018c4e","originalAuthorName":"李公法"},{"authorName":"白晨","id":"78486d79-4770-4e96-8bef-53862961ef5d","originalAuthorName":"白晨"},{"authorName":"陈世杰","id":"5c3f7b30-a2fe-4f97-b297-5dd594c30fda","originalAuthorName":"陈世杰"}],"doi":"10.3969/j.issn.1006-9356.2006.11.007","fpage":"30","id":"ab9e6623-a588-486e-b40d-aa549358a4c1","issue":"11","journal":{"abbrevTitle":"ZGYJ","coverImgSrc":"journal/img/cover/ZGYJ.jpg","id":"87","issnPpub":"1006-9356","publisherId":"ZGYJ","title":"中国冶金"},"keywords":[{"id":"66a51252-345c-4208-a1e3-507b21c74a03","keyword":"钢包","originalKeyword":"钢包"},{"id":"4df54c4a-1175-4d5d-953b-ce7169941fa6","keyword":"温度场","originalKeyword":"温度场"},{"id":"c7a0606d-3f79-4615-96bb-0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