{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"在Strathmann等人[1]提出的诱导期概念的基础上,对PES制膜体系的亚层形成机理进行研究,进一步阐明:成膜过程中由于诱导期的影响使后生成的核比先生成的核的生长滞后,从而导致核的生长存在“先核生长优势”,并采用两步分相[2~4]、凝胶等实验方法对PES制膜体系成膜过程中的凝胶行为进行研究,从非溶剂进入膜液的角度,借助提出的先核生长优势概念对成膜结构做出解释.","authors":[{"authorName":"王连军","id":"a9d0d478-ee4e-42ea-adb6-7af8ff63265d","originalAuthorName":"王连军"},{"authorName":"李恕广","id":"76732b65-f4f9-4e7a-9a9a-caf0c3571cd0","originalAuthorName":"李恕广"},{"authorName":"江成璋","id":"95e33857-a572-441a-bf1e-5304847a6edf","originalAuthorName":"江成璋"}],"doi":"10.3969/j.issn.1007-8924.2001.01.002","fpage":"4","id":"64652cdb-533c-4fa0-82cd-aa2cf7b3a0d3","issue":"1","journal":{"abbrevTitle":"MKXYJS","coverImgSrc":"journal/img/cover/MKXYJS.jpg","id":"54","issnPpub":"1007-8924","publisherId":"MKXYJS","title":"膜科学与技术 "},"keywords":[{"id":"72a92d89-d1e3-49ba-836e-e2ce106a434e","keyword":"PES","originalKeyword":"PES"},{"id":"590e04a3-71da-458b-9d3a-2169fa417c86","keyword":"两步分相","originalKeyword":"两步分相"},{"id":"67989ddb-3d09-4f9c-be12-c5f8c11a8075","keyword":"凝胶","originalKeyword":"控速凝胶"},{"id":"80a31f63-42d2-4b0a-b1d1-2870d22312e1","keyword":"先核生长优势","originalKeyword":"先核生长优势"}],"language":"zh","publisherId":"mkxyjs200101002","title":"PES制膜体系亚层形成机理的研究","volume":"21","year":"2001"},{"abstractinfo":"为了使冷工艺生产的高性能Q500qE桥梁钢具有较低的屈强比和良好的韧性,采用Gleeble-3800试验机模拟了试验钢不同冷冷工艺,研究了冷对组织和力学性能的影响.结果表明:5~25℃/s冷却速率下形成针状铁素体、粒状贝氏体铁素体和少量弥散M-A岛构成的多相组织.随冷增加,铁素体晶粒细化,M-A岛尺寸减小;强度和屈强比提高,冲击功先升高后降低.试验钢满足力学性能要求的冷冷却速率范围是15~20℃/s.","authors":[{"authorName":"吴年春","id":"6ede6c01-78c2-4da0-b73b-b53326d2cf7d","originalAuthorName":"吴年春"},{"authorName":"崔强","id":"7bcc1041-bfae-4eec-8269-705a96577585","originalAuthorName":"崔强"},{"authorName":"范益","id":"6960404f-863f-4328-94db-4c46b02e0aca","originalAuthorName":"范益"},{"authorName":"李恒坤","id":"2c7bfdd5-51c2-40b8-9247-90d2a51d2bb1","originalAuthorName":"李恒坤"},{"authorName":"李翔","id":"9bcaaaff-56c1-48b3-ac71-ab5485fb0a86","originalAuthorName":"李翔"}],"doi":"10.13228/j.b0yuan.issn0449-749x.20130633","fpage":"94","id":"7c99b6c2-bc09-46f1-a1c3-5cd16ebf196e","issue":"8","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"840eb0ff-250d-4172-ab9c-4842784a5e2e","keyword":"高性能桥梁钢","originalKeyword":"高性能桥梁钢"},{"id":"4969c286-c683-4093-9f3a-5926ea314913","keyword":"中温转变铁素体","originalKeyword":"中温转变铁素体"},{"id":"6501369d-acbe-4033-9726-483294ec8232","keyword":"M-A岛","originalKeyword":"M-A岛"},{"id":"0ce42c44-b369-41b4-8a83-7ebc589c7a8f","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"gt201408017","title":"冷冷对高性能桥梁钢组织和力学性能的影响","volume":"49","year":"2014"},{"abstractinfo":"通过建立模拟高拉板坯连铸中间包内钢液流动的水模型和数值模拟,研究了挡渣墙、坝和抑湍器等流装置对中间包内流体流动特性的影响.结果表明,有无冲击板对中间包流动特性的影响不大,抑湍器与单墙双坝的合理搭配对中间包内夹杂物有效去除的流动特性十分重要,否则会起负面影响.提出了一个流结构优化设计的方案.","authors":[{"authorName":"李永祥","id":"583104a3-87a2-46ab-a18d-1dee213229f9","originalAuthorName":"李永祥"},{"authorName":"程乃良","id":"e7914f7d-8a1d-40e1-873b-69005fa24fd0","originalAuthorName":"程乃良"},{"authorName":"冷祥贵","id":"1a7c0152-3044-41e3-af70-3310bbb0cfc8","originalAuthorName":"冷祥贵"},{"authorName":"郑淑国","id":"6db50e21-0e2b-43a5-bbf5-2e009cb54990","originalAuthorName":"郑淑国"},{"authorName":"曹娜","id":"d82603f5-3919-45ca-ad0f-140fa4d90875","originalAuthorName":"曹娜"},{"authorName":"朱苗勇","id":"d7126f15-a8a1-4efe-a99a-9a4739917e1f","originalAuthorName":"朱苗勇"}],"doi":"10.3969/j.issn.1005-4006.2007.06.002","fpage":"7","id":"a7d2d034-e03f-43e5-b0a8-1f4dd48d6512","issue":"6","journal":{"abbrevTitle":"LZ","coverImgSrc":"journal/img/cover/LZ.jpg","id":"52","issnPpub":"1005-4006","publisherId":"LZ","title":"连铸"},"keywords":[{"id":"3b8f6ba6-f6b7-4362-85ac-787dff9c3529","keyword":"中间包","originalKeyword":"中间包"},{"id":"b3675f7b-050e-4292-920c-ea24e63a29ae","keyword":"流装置","originalKeyword":"控流装置"},{"id":"cb68e904-1640-4efd-8ba9-cae26c8d2884","keyword":"水模型","originalKeyword":"水模型"},{"id":"c7f68201-ddb6-48d0-aa72-6bdc6f2db369","keyword":"数值模拟","originalKeyword":"数值模拟"},{"id":"eeba6357-ee2b-4952-b260-2527a67bee29","keyword":"抑湍器","originalKeyword":"抑湍器"}],"language":"zh","publisherId":"lz200706002","title":"优化高拉板坯连铸中间包流装置的水模型和数值模拟","volume":"","year":"2007"},{"abstractinfo":"通过热模拟试验研究了冷却速率和冷终止温度对V-N微合金化600 MPa高强钢筋组织和性能的影响.由动态CCT(Continuous Cooling Transformation)曲线和组织分析可知,实验钢筋在冷为0.5 ~1℃/s时得到的室温组织为块状铁素体和珠光体;当冷速达到3℃/s时有少量的贝氏体(含量为5%)出现;当冷在8℃/s以上时,实验钢筋的显微组织为少量的晶界铁素体+贝氏体+马氏体.因此,为了得到具有高强度和良好塑性的显微组织,轧后冷却速率应控制在0.5 ~3℃/s.此外,冷终止温度应控制在600~ 625℃,显微组织为细小的块状铁素体+珠光体+少量的贝氏体(含量为0~8%),铁素体的晶粒尺寸为4.5 ~5.2 μm,试样维氏硬度为263 ~274 HV,其对应的抗拉强度为875 ~908 MPa,有足够的强度余量.","authors":[{"authorName":"张婧","id":"7121dc38-6857-42db-9d95-40d240f9ff00","originalAuthorName":"张婧"},{"authorName":"王福明","id":"f9df64c3-cadf-4894-aae7-9e3f8a7bb86c","originalAuthorName":"王福明"},{"authorName":"李长荣","id":"825e25dd-4000-47f0-a0da-872aac0ef18e","originalAuthorName":"李长荣"},{"authorName":"何煜天","id":"510ec3eb-12f6-479b-8ae2-a1bbbf07ad77","originalAuthorName":"何煜天"}],"doi":"","fpage":"93","id":"2d4feb61-5584-4255-933d-bdfea4b4f2da","issue":"1","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":"7445f7b8-04b8-4870-9eee-a3a279049ef9","keyword":"高强钢筋","originalKeyword":"高强钢筋"},{"id":"a3f04ea3-040d-4aa9-920f-146d9f50e055","keyword":"冷却速率","originalKeyword":"冷却速率"},{"id":"2876b14f-531e-4b9d-a654-d9dcb450a72d","keyword":"冷终止温度","originalKeyword":"控冷终止温度"},{"id":"6bb0f9b6-c2fb-4997-8ffe-073263ab6d5a","keyword":"显微组织","originalKeyword":"显微组织"},{"id":"4182fc6e-c99a-4346-9dcf-8bc7016c019f","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"jsrclxb201601018","title":"冷冷终止温度对600 MPa高强钢筋组织和性能的影响","volume":"37","year":"2016"},{"abstractinfo":"本文创新性地将POSS核树枝状凝胶因子(POSS-G1-BOC)加入基体液晶分子5CB中,并且将偶氮苯化合物(Azo)作为光响应剂掺杂至该体系中制备得到液晶物理凝胶.通过管反演法、DSC、旋转流变仪等方法研究液晶物理凝胶凝胶行为.采用SEM、紫外分光光度计、雾度仪等手段研究液晶物理凝胶的表观形貌、紫外吸收、透光率等.研究结果表明:在凝胶因子含量仅为0.5wt%即可形成凝胶强度良好的液晶物理凝胶,且此时体系溶胶-凝胶温度可达到111℃,远高于基体液晶的相转变温度35℃,具有良好的热稳定性.由于体系中偶氮苯光响应剂的存在,使得其对365nm紫外光及455nm蓝光也具有可逆的响应行为.本文成功地制备了具有光、热双性质的液晶物理凝胶,为其在防伪商标、食品包装材料、光热传感器、生物医用材料等领域的应用提供了可能.","authors":[{"authorName":"罗骁","id":"c09b178c-f799-459f-b07b-33c3f0a1d4e6","originalAuthorName":"罗骁"},{"authorName":"陈思","id":"86a7eeb2-a96a-401a-add4-aae357464eac","originalAuthorName":"陈思"},{"authorName":"施燕琴","id":"24df1b80-9805-43ae-825e-440c1395dc68","originalAuthorName":"施燕琴"},{"authorName":"马猛","id":"d8577005-1915-4e97-b607-dd754f21c1e8","originalAuthorName":"马猛"},{"authorName":"吴波震","id":"7abbc89b-e59b-4643-9400-f89acddaeea3","originalAuthorName":"吴波震"},{"authorName":"何荟文","id":"e8faa543-83f0-4ad4-8ffe-46edfbf9134d","originalAuthorName":"何荟文"},{"authorName":"王旭","id":"c50fbe1a-9560-4913-99cb-971e23e1838e","originalAuthorName":"王旭"}],"doi":"10.14136/j.cnki.issn 1673-2812.2015.05.013","fpage":"685","id":"2a14d592-63f4-421b-9b3e-1dba72dc28b8","issue":"5","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":"c2133225-5cd6-4d01-a8aa-6da607283d68","keyword":"树枝状","originalKeyword":"树枝状"},{"id":"f101124a-9c4f-464e-842a-1d6685050aa6","keyword":"凝胶因子","originalKeyword":"凝胶因子"},{"id":"227fca05-712d-49d1-8bbc-589ea5ef9e3f","keyword":"液晶物理凝胶","originalKeyword":"液晶物理凝胶"},{"id":"fbc27ada-a011-4060-a1de-6c7547da74e5","keyword":"光、热双","originalKeyword":"光、热双控"}],"language":"zh","publisherId":"clkxygc201505013","title":"基于POSS核凝胶因子的光、热双液晶物理凝胶","volume":"33","year":"2015"},{"abstractinfo":"以聚丙烯酰胺丙烯酸和聚乙二醇/聚丙烯酸两种水凝胶作为模板,丙烯酸做抑制剂合成纳米颗粒.水凝胶的缓慢吸水和网络结构,减缓了钛酸四丁酯的水解速率,并抑制TiO2的颗粒长大,制备出的TiO2纳米粉粒径分布窄,且为锐钛矿相结构.对比研究发现,聚乙二醇/聚丙烯酸水凝胶的吸水膨胀率更小,前驱体溶液的稳定性更高.选用聚乙二醇/聚丙烯酸前驱体溶液,采用微流技术制备TiO2微球,制备出的微球具有球形度好、单分散的优点,焙烧后TiO2的晶体结构为锐钛矿.","authors":[{"authorName":"丁学强","id":"1ceb5fb7-1444-44d1-a466-7526690ee595","originalAuthorName":"丁学强"},{"authorName":"张骋","id":"1ce9e38a-d9ea-41b6-bbe6-2e67f2eeb073","originalAuthorName":"张骋"},{"authorName":"董利民","id":"25276ed4-5526-4fbd-b475-88563db61c5f","originalAuthorName":"董利民"},{"authorName":"王晨","id":"3d7aff58-042a-4283-8913-fa0380afed7a","originalAuthorName":"王晨"},{"authorName":"梁彤祥","id":"c6ac45a9-9721-4ce4-8d30-43cdd13e9cad","originalAuthorName":"梁彤祥"}],"doi":"10.15541/jim20140590","fpage":"605","id":"bafbe562-9d6d-4c34-b8f0-4e4b259eae95","issue":"6","journal":{"abbrevTitle":"WJCLXB","coverImgSrc":"journal/img/cover/WJCLXB.jpg","id":"62","issnPpub":"1000-324X","publisherId":"WJCLXB","title":"无机材料学报"},"keywords":[{"id":"09a1ff09-9aa7-481d-baa8-a2d476963f59","keyword":"水凝胶","originalKeyword":"水凝胶"},{"id":"a6de7f23-86fd-4f2d-aecd-4bd58e138f6c","keyword":"水解","originalKeyword":"水解"},{"id":"a17118f2-4bca-4264-a6c4-4d033682e0ad","keyword":"TiO2","originalKeyword":"TiO2"},{"id":"f870d8c9-a937-427b-9eaa-1cbb42c4a989","keyword":"微流","originalKeyword":"微流控"}],"language":"zh","publisherId":"wjclxb201506008","title":"水凝胶模板制备纳米TiO2及微流合成TiO2微球","volume":"30","year":"2015"},{"abstractinfo":"通过Gleeble模拟一种高铌微合金管线钢冷过程,研究了其组织及相变特征和变形对相变过程的影响。由膨胀量变化分析及组织观察,建立了该钢的连续冷却相变CCT曲线。结果表明,铌元素及变形促进了针状铁素体的形成,采用两阶段轧,当冷由0.5℃/s增加到50℃/s时,组织由多边形铁素体、准多边形铁素体向针状铁素体转变,但冷低于5℃/s时,组织转变对冷变化较敏感,当冷继续增加时,组织结构变化不明显,而基体中的M/A组元变得更细小、弥散。","authors":[{"authorName":"朱利敏","id":"545b63fa-d1dd-4735-af62-34fba467cbd6","originalAuthorName":"朱利敏"},{"authorName":"文九巴","id":"8c6b84d4-cfeb-4d1e-b71d-2c56882de1db","originalAuthorName":"文九巴"}],"doi":"","fpage":"106","id":"55a22f7b-8ca5-4a99-9621-f46f242136f9","issue":"2","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":"207ce399-4f0e-4bdc-b9e0-f14130315869","keyword":"管线钢","originalKeyword":"管线钢"},{"id":"c96ea4ec-6c28-4548-a755-3d9b65f80db5","keyword":"针状铁素体","originalKeyword":"针状铁素体"},{"id":"c0cbd82e-5453-40e0-af42-0bc5a59c0cb9","keyword":"相变","originalKeyword":"相变"},{"id":"6e030029-50dd-4d51-a4cc-748d9e4294f1","keyword":"CCT曲线","originalKeyword":"CCT曲线"}],"language":"zh","publisherId":"jsrclxb201202022","title":"冷对高铌钢连续冷却相变的影响","volume":"33","year":"2012"},{"abstractinfo":"利用热模拟试验机研究了低碳高铌钢在不同冷参数下组织的变化规律.结果表明:随着变形温度的降低和变形量的增加,准多边形铁素体的含量增加,粒状贝氏体的含量减少,贝氏体的形貌逐渐由板条状变为粒状;当冷低于5℃·s-1时,形成由铁素体和珠光体组成的组织,当冷高于5℃·s-1时,组织中的贝氏体含量随之增加,晶粒明显更加细小均匀;试样的显微硬度随着冷的增加而逐渐增大.","authors":[{"authorName":"钟荣","id":"4f3b1abc-1a90-4d0e-be1e-36e4185e9cae","originalAuthorName":"钟荣"},{"authorName":"张志波","id":"3159d6e6-4222-4404-9e14-a1f1fc1cdd58","originalAuthorName":"张志波"},{"authorName":"阴树标","id":"6b45c831-e4bd-4d22-89d1-c1de06ed1178","originalAuthorName":"阴树标"},{"authorName":"刘清友","id":"83b3a1fb-5b22-4f06-95fa-e6b0e8ba15b8","originalAuthorName":"刘清友"},{"authorName":"王华昆","id":"3c0b37d3-7477-4dfb-b1da-ced38807d191","originalAuthorName":"王华昆"}],"doi":"","fpage":"59","id":"baf590b6-d2f9-42c4-89b4-dca2c0e48be0","issue":"1","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":"73339598-db90-4c6f-9b53-4b542071d1b4","keyword":"低碳高铌钢","originalKeyword":"低碳高铌钢"},{"id":"53269fcf-839b-43ac-8b64-9f4e2da0a8ee","keyword":"未再结晶区","originalKeyword":"未再结晶区"},{"id":"2e4e320f-1da6-4a1f-a788-e55b31f275dd","keyword":"先共析铁素体","originalKeyword":"先共析铁素体"},{"id":"d9b2974f-4524-4f29-b9eb-eecb9a35f9ec","keyword":"贝氏体","originalKeyword":"贝氏体"},{"id":"acb358df-aad4-4792-9e03-4e90ae34f303","keyword":"显微硬度","originalKeyword":"显微硬度"}],"language":"zh","publisherId":"jxgccl201301016","title":"未再结晶区冷工艺对低碳高铌钢组织的影响","volume":"37","year":"2013"},{"abstractinfo":"利用Gleeble-1500型热模拟试验机研究了含铌微合金钢在不同冷参数下组织的变化规律.结果表明:低温变形由于引发了形变诱导铁素体相变,对珠光体转变的促进作用更加明显;珠光体片层间距随变形温度的升高而减小,并且随冷却速率增加明显减小;高温变形扩大了贝氏体相变的冷区间,低温变形由于引发形变诱导铁素体相变,对贝氏体相变起到了抑制作用.","authors":[{"authorName":"贾志鑫","id":"d0942704-8e0e-4579-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