{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"通过采用不同的脱模剂<span style=\"color:red\">稀释</span><span style=\"color:red\">用水</span>,研究了水质对镁合金压铸件质量的影响.结果表明:在脱模剂<span style=\"color:red\">稀释</span><span style=\"color:red\">用水</span>中加入一定浓度的钙离子,对压铸产品成形有利,产品质量好;但钙离子加入量过少时脱模剂附着性差,过多时则影响镁液流动性.纯水+CaCl2的<span style=\"color:red\">稀释</span>水使用方便,而且合格率高,质量稳定性好,可用于批量生产,且对后面工序无影响.","authors":[{"authorName":"杨丽景","id":"128e8290-8093-4c3f-b7ae-d045d151bb74","originalAuthorName":"杨丽景"},{"authorName":"卫英慧","id":"12a21000-4d4f-4c27-a71a-3956e312d331","originalAuthorName":"卫英慧"},{"authorName":"侯利锋","id":"0bb7a5da-a8df-4706-b8d1-a9bb148f391e","originalAuthorName":"侯利锋"},{"authorName":"王朱恩","id":"ff13e536-edd3-47c9-8bb1-35f7e0c29000","originalAuthorName":"王朱恩"},{"authorName":"于斌","id":"5ad9fc35-653b-4cc6-b014-7d1bc91ee3ba","originalAuthorName":"于斌"},{"authorName":"郭耀文","id":"c708d49e-0183-4730-b202-f0cb4a6ff1be","originalAuthorName":"郭耀文"},{"authorName":"许并社","id":"87911178-626b-4cce-9305-dc6d1f0203e2","originalAuthorName":"许并社"}],"doi":"10.3969/j.issn.1000-3738.2007.11.009","fpage":"30","id":"10037b2d-7b41-4b2f-a83b-86759220923b","issue":"11","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":"83a3f931-fb0c-481a-8cc1-3a8de1aac59d","keyword":"脱模剂","originalKeyword":"脱模剂"},{"id":"e141d323-5482-4aef-917e-7e1465e92a68","keyword":"<span style=\"color:red\">稀释</span><span style=\"color:red\">用水</span>","originalKeyword":"稀释用水"},{"id":"9a770fd1-ff36-4c5a-8d0b-2775a8540de5","keyword":"镁合金","originalKeyword":"镁合金"},{"id":"dd9f1796-7980-48a9-9ce7-0dd513ecdc76","keyword":"压铸","originalKeyword":"压铸"}],"language":"zh","publisherId":"jxgccl200711009","title":"脱模剂<span style=\"color:red\">稀释</span><span style=\"color:red\">用水</span>对镁合金压铸件质量的影响","volume":"31","year":"2007"},{"abstractinfo":"在工业固定污染源所安装的烟气连续监测系统中,<span style=\"color:red\">稀释</span>抽取采样方法占了大多数,而<span style=\"color:red\">稀释</span>比例的精确确定则是此类方法的关键.本文分析了影响烟气连续监测系统<span style=\"color:red\">稀释</span>比例的相关因素,提出相应改进措施,并在实际的烟气连续监测工程中应用验证.","authors":[{"authorName":"郑海明","id":"84e0b4dc-bec6-4169-941f-80a97edbffb7","originalAuthorName":"郑海明"},{"authorName":"蔡小舒","id":"4387f90e-6aca-40a1-8145-ca722ecd212f","originalAuthorName":"蔡小舒"}],"doi":"","fpage":"163","id":"9334b753-81b3-4af7-8ebf-d5772baad6fa","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":"ee08b1ec-5c57-408d-81df-ba59227a8c71","keyword":"烟气连续监测系统","originalKeyword":"烟气连续监测系统"},{"id":"30e5c0bd-eb53-485d-8aeb-7495f446b3b2","keyword":"<span style=\"color:red\">稀释</span>抽取采样","originalKeyword":"稀释抽取采样"},{"id":"45d32e4f-6aa1-450a-8e42-8edb0ffabb4f","keyword":"<span style=\"color:red\">稀释</span>比例","originalKeyword":"稀释比例"},{"id":"f3008b14-b0b5-4dbc-aba1-fd13c499eb7f","keyword":"临界小孔","originalKeyword":"临界小孔"}],"language":"zh","publisherId":"gcrwlxb200601051","title":"烟气连续监测系统<span style=\"color:red\">稀释</span>采样比例技术研究","volume":"27","year":"2006"},{"abstractinfo":"本文采用详细化学反应机理数值研究了添加不同<span style=\"color:red\">稀释</span>气体(氦气/氩气/氮气/二氧化碳)对甲烷/空气预混气体点火的影响,比较了氢气/空气/二氧化碳和甲烷/空气/二氧化碳的最小点火能与<span style=\"color:red\">稀释</span>极限.研究结果表明:<span style=\"color:red\">稀释</span>气体的热力学效应和火焰动力学效应均会导致最小点火能变大;在添加二氧化碳时,甲烷/空气的<span style=\"color:red\">稀释</span>极限远低于氢气/空气的<span style=\"color:red\">稀释</span>极限.","authors":[{"authorName":"张伟阔","id":"ccd13c9c-5117-4c90-bdbb-73e37ff2b5b8","originalAuthorName":"张伟阔"},{"authorName":"苟小龙","id":"4e637e6a-5b61-4777-866d-8db6c9d0a45d","originalAuthorName":"苟小龙"},{"authorName":"孔文俊","id":"226164ff-21a3-46a9-9411-170fd9b5e2a5","originalAuthorName":"孔文俊"},{"authorName":"陈正","id":"31879ee8-cee7-4796-9710-a1e4044b79d3","originalAuthorName":"陈正"}],"doi":"","fpage":"1189","id":"bb0ce26f-fb15-4d43-a50d-401cf6ef448d","issue":"6","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":"08bc1649-0a4a-4935-8bb4-0c364dc3b1aa","keyword":"<span style=\"color:red\">稀释</span>气体","originalKeyword":"稀释气体"},{"id":"f0487d77-d4ab-4e02-b02b-14ea6595d8a3","keyword":"甲烷/空气","originalKeyword":"甲烷/空气"},{"id":"cc82beae-45fb-4d27-a86a-c1d4c5e5b40f","keyword":"最小点火能","originalKeyword":"最小点火能"},{"id":"0cb00db8-c753-40a8-b452-6e0d0c44bf9b","keyword":"热力学效应","originalKeyword":"热力学效应"},{"id":"05f21b35-028e-4639-9973-fdfc51241b4e","keyword":"火焰动力学效应","originalKeyword":"火焰动力学效应"}],"language":"zh","publisherId":"gcrwlxb201306044","title":"<span style=\"color:red\">稀释</span>气体对预混甲烷/空气点火的影响","volume":"34","year":"2013"},{"abstractinfo":"对高能超声<span style=\"color:red\">稀释</span>原位反应烧结块制备锌铝合金基复合材料过程进行了研究,简要分析了超声<span style=\"color:red\">稀释</span>机理.研究表明,高能超声快速<span style=\"color:red\">稀释</span>烧结块是声空化与声流效应协同作用的结果.空化产生的瞬时高温可促进界面区域元素扩散,瞬时高压将裸露在界面上的长棒状的TiAl3击断,打破了烧结块的网状结构,并将其周围的高致密度的Al2O3和TiB2颗粒聚集区击碎.另一方面,声流引起的强烈搅拌作用减薄了过渡层,并使短棒状的TiAl3颗粒及Al2O3、TiB2微细颗粒均匀分布在熔体中.在上述分析基础上,建立了元素扩散模型和烧结块在锌铝合金中的<span style=\"color:red\">稀释</span>过程模型.","authors":[{"authorName":"潘蕾","id":"94ecc6f2-ad3b-4028-8436-5ceccc9a3db5","originalAuthorName":"潘蕾"},{"authorName":"陶杰","id":"2ccda5a7-de05-410b-8134-40aebdfb8ad9","originalAuthorName":"陶杰"},{"authorName":"吴申庆","id":"1c8cd726-3b45-43e3-acb0-1fecb8bffc53","originalAuthorName":"吴申庆"},{"authorName":"陈锋","id":"ecb81dd7-2027-4853-b113-8491c18710fa","originalAuthorName":"陈锋"},{"authorName":"刘子利","id":"442fdb82-9cd1-4d64-83fa-5ed5de42a9d6","originalAuthorName":"刘子利"},{"authorName":"陈照峰","id":"d539353e-ff55-4a61-849d-5a835b424b48","originalAuthorName":"陈照峰"}],"doi":"10.3321/j.issn:1000-3851.2005.06.007","fpage":"37","id":"ec513bd5-7986-49a7-8e3f-eca43d6719d0","issue":"6","journal":{"abbrevTitle":"FHCLXB","coverImgSrc":"journal/img/cover/FHCLXB.jpg","id":"26","issnPpub":"1000-3851","publisherId":"FHCLXB","title":"复合材料学报"},"keywords":[{"id":"bdd9d2c1-2806-41c8-94fe-ef3d86444e2f","keyword":"烧结块","originalKeyword":"烧结块"},{"id":"8d97d01d-23bf-406f-89fc-311e141569ff","keyword":"声空化","originalKeyword":"声空化"},{"id":"9a2ad593-c265-4e41-b529-eb27e4b40b8b","keyword":"声流","originalKeyword":"声流"},{"id":"a606dde6-a132-48d2-b465-3dde03fd04a6","keyword":"<span style=\"color:red\">稀释</span>","originalKeyword":"稀释"}],"language":"zh","publisherId":"fhclxb200506007","title":"原位反应烧结块的高能超声<span style=\"color:red\">稀释</span>过程分析","volume":"22","year":"2005"},{"abstractinfo":"在世界范围内,膜技术越来越多地用于满足高质量供水的需求.由于饮<span style=\"color:red\">用水</span>中难以杀灭的,而又致命的细菌的历史性的爆发,人们发现膜可以作为去除这些细菌和病毒的安全屏障,从而被广泛用于引<span style=\"color:red\">用水</span>生产和供应.在废水处理领域,膜可以用于分离废水中的悬浮颗粒和物质,通过膜技术深度处理后的水可以回用.文章对超滤膜在饮<span style=\"color:red\">用水</span>、工业<span style=\"color:red\">用水</span>及废水回用方面的应用情况进行了综述.","authors":[{"authorName":"","id":"5d54f2b5-5d10-4081-b69a-df96b180066f","originalAuthorName":""},{"authorName":"","id":"6b0c37c0-6ed1-40c5-bb15-c5e3c6392d71","originalAuthorName":""},{"authorName":"","id":"3bc49cd3-8797-42d1-a548-3e7e758d2850","originalAuthorName":""},{"authorName":"申蕾","id":"e5e65f80-2902-4e2a-8fc7-a8f2206a5540","originalAuthorName":"申蕾"}],"doi":"10.3969/j.issn.1007-8924.2003.04.043","fpage":"246","id":"55916ddb-1634-41c7-98fb-1f2ca9e6861f","issue":"4","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":"f720634b-36ae-4554-93b0-94b60ea645a7","keyword":"超滤","originalKeyword":"超滤"},{"id":"405de8a3-8b21-487b-a32f-cf3282fdbfee","keyword":"毛细管膜","originalKeyword":"毛细管膜"},{"id":"299e2758-c1b1-404f-80e5-955417f0b1d4","keyword":"饮<span style=\"color:red\">用水</span>","originalKeyword":"饮用水"},{"id":"4bcc3645-6c12-4109-bc0d-5832b2f362ab","keyword":"工业<span style=\"color:red\">用水</span>","originalKeyword":"工业用水"},{"id":"9fb9b3a6-959e-433b-a73a-ec6a427e18c7","keyword":"废水","originalKeyword":"废水"}],"language":"zh","publisherId":"mkxyjs200304043","title":"超滤技术用于饮<span style=\"color:red\">用水</span>、工业<span style=\"color:red\">用水</span>及废水处理","volume":"23","year":"2003"},{"abstractinfo":"论文针对注浆成本高,煤矸石活性低、利用率低等问题,结合我国当前注浆材料和煤矸石活性激发的研究现状,配制一种注浆专<span style=\"color:red\">用水</span>泥.首先采用机械活化方式,结合比表面积和能耗,优选出最佳的煤矸石机械粉磨时间,然后研究煅烧温度和化学激发剂掺量对水泥强度影响的变化规律,并结合各种活化方法对水泥流动度、凝结时间的影响规律得出煤矸石水泥的最佳配比.利用电化学工作站分析了煤矸石基水泥内部孔结构的变化规律；利用SEM对煤矸石的活性增强机理、煤矸石水泥强度增强机理进行了探讨,为注浆专<span style=\"color:red\">用水</span>泥的进一步研究提供了可靠的依据.","authors":[{"authorName":"朱伶俐","id":"bdbd194a-2d15-4a59-ab5e-76e391129eeb","originalAuthorName":"朱伶俐"},{"authorName":"赵宇","id":"e3f2a45e-143f-463d-b5cd-c372725288ea","originalAuthorName":"赵宇"}],"doi":"","fpage":"206","id":"d2d67723-4022-4286-869d-7953a85ec420","issue":"1","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"82ff2c6b-235e-4204-9b3d-61c01248a25f","keyword":"煤矸石-水泥","originalKeyword":"煤矸石-水泥"},{"id":"a5c57f9b-86c0-42d8-a840-8c935a39367d","keyword":"机械活化","originalKeyword":"机械活化"},{"id":"81ef0438-a4d4-407a-b3e3-a382f6a8fc57","keyword":"化学激发剂","originalKeyword":"化学激发剂"}],"language":"zh","publisherId":"gsytb201201045","title":"注浆专<span style=\"color:red\">用水</span>泥的实验研究","volume":"31","year":"2012"},{"abstractinfo":"综述了城市饮<span style=\"color:red\">用水</span>膜处理技术,介绍了新型膜处理技术具有适应的水质范围广,出水水质好,占地面积小等优点,及其在国外的推广应用.这种新型的膜处理技术不仅能有效地去除水中的浊度、病原微生物和病原寄生虫,纳滤膜还能有效地去除水中的有机污染物,包括常规工艺很难去除的农药等.","authors":[{"authorName":"王琳","id":"785d2513-6674-4a98-adec-773771527cbb","originalAuthorName":"王琳"},{"authorName":"王宝贞","id":"949d6369-573a-4bda-81f9-6ebee1ce688d","originalAuthorName":"王宝贞"},{"authorName":"杨鲁豫","id":"43b76e27-85a3-4394-b67b-eec6220c93ef","originalAuthorName":"杨鲁豫"}],"doi":"10.3969/j.issn.1007-8924.2001.03.013","fpage":"53","id":"a8c11fcd-6556-4e95-a969-7e5cd19a1faa","issue":"3","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":"d4763553-007e-4b8e-a084-95fa9314c6a4","keyword":"膜处理工艺","originalKeyword":"膜处理工艺"},{"id":"73cac891-f6ca-470b-ac15-9b0d06ffd8fb","keyword":"浊度","originalKeyword":"浊度"},{"id":"42b7607e-8b3d-4d1d-a433-beacbbf6c71b","keyword":"病原微生物","originalKeyword":"病原微生物"},{"id":"9079f0dd-0066-4121-aff2-c734f936d21d","keyword":"有机污染物","originalKeyword":"有机污染物"}],"language":"zh","publisherId":"mkxyjs200103013","title":"城市饮<span style=\"color:red\">用水</span>膜处理技术","volume":"21","year":"2001"},{"abstractinfo":"通过对<span style=\"color:red\">稀释</span>剂在NOx治理方面的作用展开了简要的分析和评价.分析表明,氧浓度越高,CO2<span style=\"color:red\">稀释</span>效果越明显,NOx浓度越低;N2<span style=\"color:red\">稀释</span>燃料火焰质量流量的效果比<span style=\"color:red\">稀释</span>空气对降低NOx浓度更加有效.CO2和N2两者不论是空气还是燃料<span style=\"color:red\">稀释</span>,都会减少NOx的<span style=\"color:red\">稀释</span>量,在同一速度下,<span style=\"color:red\">稀释</span>空气比<span style=\"color:red\">稀释</span>燃料对NOx降低更有效.不过,<span style=\"color:red\">稀释</span>浓度的增加会导致温度的下降.而SO2在贫燃料状态下,N/S中的S越大,NOx生成越小;在富燃料状态下,S越大NOx生成越大.","authors":[{"authorName":"邓伟强","id":"d87375d7-48fa-447c-b497-50f46e0446b2","originalAuthorName":"邓伟强"},{"authorName":"曾令可","id":"d3a0f39e-0cf9-4158-bb84-2fc3f90862e6","originalAuthorName":"曾令可"},{"authorName":"刘艳春","id":"1a97c823-8f97-4a45-8d46-712916783e68","originalAuthorName":"刘艳春"},{"authorName":"税安泽","id":"956f2ce1-4d41-402a-92bc-6669b57680dc","originalAuthorName":"税安泽"},{"authorName":"王慧","id":"9cd606f7-ed55-417f-b25d-e6b4f4616efb","originalAuthorName":"王慧"},{"authorName":"段碧林","id":"a1b97939-3280-4e77-a9c5-7b4e0139e50a","originalAuthorName":"段碧林"}],"doi":"10.3969/j.issn.1001-1625.2007.01.030","fpage":"138","id":"fa735c0e-c135-4e39-a1b7-bd65d68e7c4d","issue":"1","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"72019acc-2f99-4d57-b0ea-56f8ca78928d","keyword":"<span style=\"color:red\">稀释</span>剂","originalKeyword":"稀释剂"},{"id":"35861704-625a-4152-a23a-c730c5b8bcba","keyword":"NOx","originalKeyword":"NOx"},{"id":"d147fde0-d565-4251-8c16-083e9c5b653b","keyword":"贫燃料状态","originalKeyword":"贫燃料状态"},{"id":"6010a837-e746-4505-86b4-200372b071f8","keyword":"富燃料状态","originalKeyword":"富燃料状态"},{"id":"23b43d21-11e0-42e7-9fc3-81e36cae52ad","keyword":"火焰","originalKeyword":"火焰"}],"language":"zh","publisherId":"gsytb200701030","title":"<span style=\"color:red\">稀释</span>剂对氮氧化物生成的影响","volume":"26","year":"2007"},{"abstractinfo":"采用苯乙烯作为RTM用BMI/DABPA树脂体系的活性<span style=\"color:red\">稀释</span>剂,对树脂粘度、反应性以及耐热性等方面进行了研究.结果表明,这种活性<span style=\"color:red\">稀释</span>剂可以极大程度地降低BMI/DABPA树脂的粘度,改善树脂体系的流动性能;由于苯乙烯与BMI/DABPA树脂能发生交联反应,故树脂体系没有低分子挥发物产生,这样在降低树脂体系粘度的同时,兼顾了BMI树脂良好的耐热性能及力学性能.此外,本文还探讨了双马来酰亚胺、二烯丙烯双酚A以及苯乙烯之间的反应机理.实验数据表明,在BMI/DABPA树脂体系中加入25%(W%)的苯乙烯,既可满足RTM用BMI树脂粘度的要求,又可兼顾固化树脂良好的热性能.","authors":[{"authorName":"金保宏","id":"04d6dc5b-96ed-410b-8ca1-9ba685f4b3c0","originalAuthorName":"金保宏"},{"authorName":"王柏臣","id":"b8b51218-70ef-4533-94a7-0ca46dab6e8f","originalAuthorName":"王柏臣"},{"authorName":"陈平","id":"a2f7b9ec-b9e2-4ff5-a1a9-eb8741b28bca","originalAuthorName":"陈平"},{"authorName":"徐信孟","id":"5ce60742-15c7-4880-89f0-ec23c4631436","originalAuthorName":"徐信孟"}],"doi":"10.3969/j.issn.1003-0999.2011.01.009","fpage":"36","id":"0d4c31ee-39ac-47e7-bca0-eac89be31d44","issue":"1","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":"5038a216-e815-4058-b826-d7c411ded719","keyword":"双马来酰亚胺树脂","originalKeyword":"双马来酰亚胺树脂"},{"id":"1d33a027-d1d2-46fc-b1d6-40d0b29cd345","keyword":"二烯丙烯双酚A","originalKeyword":"二烯丙烯双酚A"},{"id":"b31641bd-357e-4aa8-80bd-285e3b8c3f17","keyword":"苯乙烯","originalKeyword":"苯乙烯"},{"id":"c913bff1-91c6-4b12-ba26-bc86e621937d","keyword":"活性<span style=\"color:red\">稀释</span>剂","originalKeyword":"活性稀释剂"}],"language":"zh","publisherId":"blgfhcl201101009","title":"RTM用BMI树脂的活性<span style=\"color:red\">稀释</span>剂研究","volume":"","year":"2011"},{"abstractinfo":"饮<span style=\"color:red\">用水</span>深度净化材料为提高饮<span style=\"color:red\">用水</span>的卫生安全质量发挥了重要作用.本文对近几年国内外常用的饮<span style=\"color:red\">用水</span>深度净化材料的研究现状进行了综述,并指出了在实际应用过程中存在的一些问题和未来主要研究方向.","authors":[{"authorName":"陈超","id":"7403305e-dd82-4e5c-bcf2-789c823ddc20","originalAuthorName":"陈超"},{"authorName":"何勇","id":"44ec2431-79d6-47e5-a293-7db30f992bc5","originalAuthorName":"何勇"},{"authorName":"陈鹏","id":"f6f96ca0-5721-4f4c-b860-265d59ff15e4","originalAuthorName":"陈鹏"},{"authorName":"陈勇","id":"044732b1-a4f0-47b1-add5-b11687d1d042","originalAuthorName":"陈勇"}],"doi":"","fpage":"87","id":"9979e285-b696-4881-8f64-37107997502b","issue":"2","journal":{"abbrevTitle":"CLKFYYY","coverImgSrc":"journal/img/cover/CLKFYYY.jpg","id":"10","issnPpub":"1003-1545","publisherId":"CLKFYYY","title":"材料开发与应用"},"keywords":[{"id":"2d7a6b60-38e1-41e2-9a73-7df14e697c8d","keyword":"深度净化材料","originalKeyword":"深度净化材料"},{"id":"de091688-3ce4-4184-9645-4bde7215f158","keyword":"膜材料","originalKeyword":"膜材料"},{"id":"3bd43b75-a4f4-411f-95c8-218d9e091b72","keyword":"光催化","originalKeyword":"光催化"},{"id":"4717f8ea-6cef-469a-a00c-54a82e1709d9","keyword":"TiO2","originalKeyword":"TiO2"}],"language":"zh","publisherId":"clkfyyy201402018","title":"饮<span style=\"color:red\">用水</span>深度净化材料研究进展","volume":"29","year":"2014"}],"totalpage":358,"totalrecord":3571}