{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"指出只有当<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>中全碱浓度小于或等于赤泥<span style=\"color:red\">洗液</span>中全碱浓度时,才有利于赤泥洗涤;利用2000年上半年实际生产数据,计算出<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>最大允许全碱质量浓度为61.56 g/L.分析比较了处理高浓度<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>的3种方案,结果表明:将全碱浓度为95.06 g/L的<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>直接送到稀释槽,可使赤泥一洗槽溢流浓度降低约6 g/L,每吨<span style=\"color:red\">氧化铝</span>赤泥附碱损失减小0.25 kg<span style=\"color:red\">氧化</span>钠,每年可节省碱耗费约54.9万元;而且还能将<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>中的浮游物反溶解进入稀释液,有利于精液Rp(<span style=\"color:red\">氧化铝</span>与苛性<span style=\"color:red\">氧化</span>钠的质量比)的提高,同时避免了其进入赤泥而被损失,每年可减少<span style=\"color:red\">氧化铝</span>损失费约35.3万元.并提出了简单可行的<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>流程改造的具体方案.","authors":[{"authorName":"王龙章","id":"72ef89e5-84d9-46b7-80b4-cd5b3adf38a6","originalAuthorName":"王龙章"},{"authorName":"甘国耀","id":"915996a9-2fd7-4a51-9502-50baf5ce65fc","originalAuthorName":"甘国耀"},{"authorName":"刘保伟","id":"dd883922-147b-4473-b624-036d2a1b8f55","originalAuthorName":"刘保伟"}],"doi":"","fpage":"721","id":"c1408fa6-f50e-4ac3-b704-dd9839391fb0","issue":"4","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":"43976e56-2b63-4250-beee-0cb0a84f7586","keyword":"<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>","originalKeyword":"氢氧化铝洗液"},{"id":"05766f6a-9f8e-400d-82a2-ce19ca53815b","keyword":"全碱质量浓度","originalKeyword":"全碱质量浓度"},{"id":"9d8da170-5bb7-4f8e-8580-6c6338fef30a","keyword":"流程改造","originalKeyword":"流程改造"}],"language":"zh","publisherId":"zgysjsxb200104039","title":"平果铝厂<span style=\"color:red\">氢氧化铝</span><span style=\"color:red\">洗液</span>最大允许全碱浓度的计算及流程改造方案","volume":"11","year":"2001"},{"abstractinfo":"超细<span style=\"color:red\">氢氧化铝</span>是一种重要的无机阻燃填料,但由于其分解温度低而影响使用性能.根据晶体成核与生长理论,以<span style=\"color:red\">氢氧化铝</span>为核材,以镁盐和<span style=\"color:red\">氢氧化</span>钠为原料,通过非均相成核方式使<span style=\"color:red\">氢氧化</span>镁沉积在<span style=\"color:red\">氢氧化铝</span>表面,形成<span style=\"color:red\">氢氧化</span>镁包覆<span style=\"color:red\">氢氧化铝</span>的核-壳结构,制备的<span style=\"color:red\">氢氧化铝</span>镁复合阻燃剂兼有<span style=\"color:red\">氢氧化铝</span>和<span style=\"color:red\">氢氧化</span>镁的优点.通过研究温度、加料方式以及复合阻燃剂中<span style=\"color:red\">氢氧化铝</span>与<span style=\"color:red\">氢氧化</span>镁理化质量比等对复合阻燃剂热稳定性的影响,得到复合阻燃剂优化的制备工艺条件.制备的铝镁复合阻燃剂,初始热分解温度可达到260℃,进一步提高了<span style=\"color:red\">氢氧化铝</span>的阻燃性能,有机高聚物填充铝镁复合阻燃剂后其氧指数可达到33,主要力学性能指标均优于国家标准.","authors":[{"authorName":"刘磊","id":"58246396-6c95-4439-8c57-df68791c0098","originalAuthorName":"刘磊"},{"authorName":"王建立","id":"d01f84d0-f571-4d71-9334-2396be31d47d","originalAuthorName":"王建立"}],"doi":"","fpage":"225","id":"53def879-85a6-4593-be62-31634117b535","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":"ad1f04b7-7e82-45d0-9837-df3b682ab36c","keyword":"铝镁复合阻燃剂","originalKeyword":"铝镁复合阻燃剂"},{"id":"32eca426-4307-4e31-9076-16cdf2740cdd","keyword":"制备","originalKeyword":"制备"},{"id":"6e0d5df1-166e-4f7b-8f90-300673c15c0b","keyword":"非均相沉淀","originalKeyword":"非均相沉淀"},{"id":"a5be697b-a4f3-4bde-a08d-acdd2802517f","keyword":"热稳定性","originalKeyword":"热稳定性"}],"language":"zh","publisherId":"gsytb201401044","title":"<span style=\"color:red\">氢氧化铝</span>镁复合阻燃剂制备技术研究","volume":"33","year":"2014"},{"abstractinfo":"利用离子膜电解铝酸钠溶液的方法制备<span style=\"color:red\">氢氧化铝</span>,研究制备过程中分解条件和非离子型表面活性剂聚乙二醇对产品<span style=\"color:red\">氢氧化铝</span>的影响,并通过扫描电镜以及红外光谱分析等检测手段对产品<span style=\"color:red\">氢氧化铝</span>进行表征.结果表明:当搅拌速度为400 r/min、苛碱浓度为150 g/L、温度为35℃时,<span style=\"color:red\">氢氧化铝</span>粒度分布情况最好:聚乙二醇的加入有利于制备粒度较细且分散性好的<span style=\"color:red\">氢氧化铝</span>,且随其添加量的增加,<span style=\"color:red\">氢氧化铝</span>平均粒径减小;聚乙二醇的最佳添加浓度为0.175 g/L,对应产品<span style=\"color:red\">氢氧化铝</span>的平均粒径为3.9μm.红外光谱表明:聚乙二醇通过在<span style=\"color:red\">氢氧化铝</span>表面的吸附作用抑制颗粒间的附聚,离子膜电解铝酸钠溶液的产品为拜耳型<span style=\"color:red\">氢氧化铝</span>.","authors":[{"authorName":"董觉","id":"381dc74c-a03d-46a2-b6fd-5cf36b10c365","originalAuthorName":"董觉"},{"authorName":"","id":"df40a069-5200-49b8-82f4-6a474232d055","originalAuthorName":""},{"authorName":"尹周澜","id":"0fb72402-8a5c-4b9c-bf9b-e575498742af","originalAuthorName":"尹周澜"}],"doi":"","fpage":"1330","id":"6118bb1f-ad22-44e7-8a70-80b17ba81799","issue":"7","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":"379166f5-e561-47d9-8b2d-1498c449a911","keyword":"超细<span style=\"color:red\">氢氧化铝</span>","originalKeyword":"超细氢氧化铝"},{"id":"3d651179-6865-4ef0-b931-dcb4ac66cbc8","keyword":"铝酸钠溶液","originalKeyword":"铝酸钠溶液"},{"id":"f5e6977e-a6f5-469d-b388-6ff75d4b752d","keyword":"离子膜电解","originalKeyword":"离子膜电解"},{"id":"9c89cd86-e6b4-4282-bd81-7a9ccc8294cf","keyword":"聚乙二醇","originalKeyword":"聚乙二醇"}],"language":"zh","publisherId":"zgysjsxb200807026","title":"离子膜电解铝酸钠溶液制备超细<span style=\"color:red\">氢氧化铝</span>","volume":"18","year":"2008"},{"abstractinfo":"结合超细<span style=\"color:red\">氢氧化铝</span>的研究现状,在实验室对铝酸钠溶液加晶种分解制备超细<span style=\"color:red\">氢氧化铝</span>的工艺条件进行了系统研究,重点研究了分解温度、分解时间、种子率、精液分子比对<span style=\"color:red\">氢氧化铝</span>粒度分布以及铝酸钠溶液分解率的影响.结果表明,最佳条件为:反应温度50℃,时间10 h,分子比1.5,种子率20％.","authors":[{"authorName":"姜妲","id":"8d64641e-c588-4b9c-aeb3-2a842394579a","originalAuthorName":"姜妲"},{"authorName":"张帅","id":"4168d64d-257b-4ef4-81ff-bb6efa37c064","originalAuthorName":"张帅"},{"authorName":"曲丽英","id":"8b6e3a3b-1bcf-4762-85bd-66cbb344757a","originalAuthorName":"曲丽英"}],"doi":"10.14186/j.cnki.1671-6620.2015.01.013","fpage":"62","id":"f4cde46f-a57c-4cdc-9f3d-f95410fef43f","issue":"1","journal":{"abbrevTitle":"CLYYJXB","coverImgSrc":"journal/img/cover/CLYYJXB.jpg","id":"17","issnPpub":"1671-6620","publisherId":"CLYYJXB","title":"材料与冶金学报"},"keywords":[{"id":"12e80b4b-0e92-4135-9771-97c1ff38be28","keyword":"晶种分解","originalKeyword":"晶种分解"},{"id":"59b27703-5299-45ce-8e3f-2a57c9c48a92","keyword":"超细<span style=\"color:red\">氢氧化铝</span>","originalKeyword":"超细氢氧化铝"},{"id":"e4c3c848-ac45-4c75-9ae9-33505c6c1938","keyword":"铝酸钠溶液","originalKeyword":"铝酸钠溶液"},{"id":"f066a805-b92d-47e0-8b80-d7f899d2b685","keyword":"分解率","originalKeyword":"分解率"}],"language":"zh","publisherId":"clyyjxb201501013","title":"铝酸钠溶液晶种分解制备超细<span style=\"color:red\">氢氧化铝</span>","volume":"14","year":"2015"},{"abstractinfo":"考察了<span style=\"color:red\">氢氧化铝</span>改性磷-氮环氧树脂复合体系的阻燃性,分析了<span style=\"color:red\">氢氧化铝</span>的热分解温度和用量对氮-磷环氧树脂阻燃性的影响. 结果表明,<span style=\"color:red\">氢氧化铝</span>经过热处理,其热分解温度可从195.35 ℃提高到242.15 ℃;在氮-磷环氧树脂体系中,<span style=\"color:red\">氢氧化铝</span>与环氧树脂的质量比为(77.5～85)∶ 100;树脂中磷的质量分数为2.8%,氮的质量分数为1.6%时,树脂的燃烧等级(UL-94等级)可达到V0等级,氧指数可达36%～37%.","authors":[{"authorName":"李来丙","id":"17470177-b588-471f-a0ff-dc328db30650","originalAuthorName":"李来丙"},{"authorName":"何晓梅","id":"0ea49936-9dfd-4873-9c59-4521b2bcfc92","originalAuthorName":"何晓梅"}],"doi":"10.3969/j.issn.1000-0518.2005.06.016","fpage":"652","id":"0fa27de2-b4a3-4cd3-af59-863bb00f8ecf","issue":"6","journal":{"abbrevTitle":"YYHX","coverImgSrc":"journal/img/cover/YYHX.jpg","id":"73","issnPpub":"1000-0518","publisherId":"YYHX","title":"应用化学"},"keywords":[{"id":"af7c29e1-4071-43f5-b6d8-254dbbaace38","keyword":"正交试验","originalKeyword":"正交试验"},{"id":"424d9e1e-9455-4167-9264-4faa6ea7ef52","keyword":"阻燃性","originalKeyword":"阻燃性"},{"id":"a307047a-7d34-4592-8ecb-00a2797212dd","keyword":"燃烧等级","originalKeyword":"燃烧等级"},{"id":"689328d5-25b5-42b1-8856-a56158aa3f26","keyword":"氧指数","originalKeyword":"氧指数"}],"language":"zh","publisherId":"yyhx200506016","title":"<span style=\"color:red\">氢氧化铝</span>-氮-磷环氧树脂体系的阻燃性能","volume":"22","year":"2005"},{"abstractinfo":"用湿法纺丝工艺制备出海藻酸钙纤维和纳米<span style=\"color:red\">氢氧化铝</span>/海藻酸钙复合纤维.用场发射扫描电镜和红外光谱仪表征了两种纤维的表观形态和微观机制,用热重分析仪测试了两种纤维的热稳定性能.研究表明,纳米<span style=\"color:red\">氢氧化铝</span>已较好地分散到纤维中,且纳米<span style=\"color:red\">氢氧化铝</span>与海藻酸钙分子之间产生了新的键合作用.TG和DTG测试结果表明,复合纤维的热稳定性要优于海藻酸钙纤维.同时还对两种纤维进行了吸湿性试验和纤维强力测试,结果说明纳米<span style=\"color:red\">氢氧化铝</span>的引入降低了材料的吸湿性能,但与海藻酸钙纤维相比,纳米<span style=\"color:red\">氢氧化铝</span>/海藻酸钙复合纤维的强度有了很大的提高.","authors":[{"authorName":"张建军","id":"03efd174-85e1-4869-bb96-87c6b29f93b4","originalAuthorName":"张建军"},{"authorName":"纪全","id":"e40fd808-4bf8-47ee-b2b9-79e992cb1a31","originalAuthorName":"纪全"},{"authorName":"谭立文","id":"d21b1432-5ffc-4652-a21a-039b2582bb07","originalAuthorName":"谭立文"},{"authorName":"夏延致","id":"ca97ffee-e517-4997-b7ce-14db2291ac0a","originalAuthorName":"夏延致"},{"authorName":"孔庆山","id":"9e3e8b70-3c7a-408f-9e25-5e7473495a3d","originalAuthorName":"孔庆山"}],"doi":"","fpage":"820","id":"64a06cde-d552-4582-9863-7fcc246f3f03","issue":"5","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"325f5759-0b34-4bd5-83e8-fe477f0bf915","keyword":"海藻酸钠","originalKeyword":"海藻酸钠"},{"id":"009139ec-54f0-445a-8c6d-8c907e83429d","keyword":"纳米<span style=\"color:red\">氢氧化铝</span>","originalKeyword":"纳米氢氧化铝"},{"id":"f1de1411-2fd4-4cff-bb67-2bebe2cf9fdb","keyword":"湿法纺丝","originalKeyword":"湿法纺丝"},{"id":"e96821ed-802e-417b-b8f6-a8330936ca99","keyword":"热稳定性能","originalKeyword":"热稳定性能"},{"id":"10389280-fefc-4534-ba4a-6a0bc8f36291","keyword":"强度","originalKeyword":"强度"}],"language":"zh","publisherId":"gncl201105012","title":"海藻酸钙/纳米<span style=\"color:red\">氢氧化铝</span>纤维的制备与性能研究","volume":"42","year":"2011"},{"abstractinfo":"采用相转化法制备了纳米<span style=\"color:red\">氢氧化铝</span>镁/PVDF杂化膜,考察了纳米<span style=\"color:red\">氢氧化铝</span>镁的加入对膜的纯水通量、截留率、孔径、孔隙率、微观结构、机械性能、热稳定性和吸附性能的影响.并通过X射线光电子能谱(XPS)和X射线能谱(EDS)分析了膜表面和断面的元素含量.与不添加纳米<span style=\"color:red\">氢氧化铝</span>镁的PVDF膜性能对比,结果表明,纳米<span style=\"color:red\">氢氧化铝</span>镁的加入明显提高了膜的纯水通量、截留率、机械性能和吸附性能,而对膜的孔径和孔隙率影响不大.SEM和热重分析表明,纳米<span style=\"color:red\">氢氧化铝</span>镁的加入明显改变了膜的孔结构,其热性能却略有降低.","authors":[{"authorName":"魏汉辉","id":"b49e740f-68de-4e56-b0bf-f788da1b11a0","originalAuthorName":"魏汉辉"},{"authorName":"刘红斌","id":"2b3edfb3-dd31-4b56-8961-dd9b9e622d2d","originalAuthorName":"刘红斌"},{"authorName":"吕晓龙","id":"a170a679-f6d3-42d2-a5d3-f34d885a8f50","originalAuthorName":"吕晓龙"},{"authorName":"马军","id":"4e6c50fc-28f9-4fcb-adf0-0b9cf708c04d","originalAuthorName":"马军"}],"doi":"10.3969/j.issn.1007-8924.2009.06.005","fpage":"20","id":"919074de-dec5-4163-ba58-faec7a8ac5b5","issue":"6","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":"7a5b58ca-88ad-4293-9191-c6b13f8a8640","keyword":"纳米<span style=\"color:red\">氢氧化铝</span>镁","originalKeyword":"纳米氢氧化铝镁"},{"id":"09430ac8-b034-4a33-9775-67361635d024","keyword":"聚偏氟乙烯","originalKeyword":"聚偏氟乙烯"},{"id":"edc1b5b7-17af-49bf-8223-472a14172d21","keyword":"改性","originalKeyword":"改性"},{"id":"bb46feb0-2fcb-479e-9800-29d9efc4b9a4","keyword":"杂化膜","originalKeyword":"杂化膜"}],"language":"zh","publisherId":"mkxyjs200906005","title":"纳米<span style=\"color:red\">氢氧化铝</span>镁改性PVDF膜性能的研究","volume":"29","year":"2009"},{"abstractinfo":"用甘油对<span style=\"color:red\">氢氧化铝</span>超细粉体填料进行表面改性,用红外光谱对改性样品进行分析,结果表明,改性后的填料表面被改性剂有机化,提高了其在有机物中的填充性能,研究了反应温度对<span style=\"color:red\">氢氧化铝</span>超细粉体填料活化指数的影响,并浅析了改性机理.","authors":[{"authorName":"朱静","id":"caf59023-3917-4281-99b2-377a6abf6562","originalAuthorName":"朱静"},{"authorName":"裴秀中","id":"b25cb71a-2079-46df-acfc-11ce82724ca2","originalAuthorName":"裴秀中"}],"doi":"10.3969/j.issn.1001-1560.2003.08.005","fpage":"16","id":"c32e32b6-4c1a-4110-8c00-4b47ce21b739","issue":"8","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"c74e1624-1d29-4d59-8ba0-bcfc66f6ec34","keyword":"<span style=\"color:red\">氢氧化铝</span>","originalKeyword":"氢氧化铝"},{"id":"4f7c9073-8a13-4933-ad94-24a673014747","keyword":"超细粉体填料","originalKeyword":"超细粉体填料"},{"id":"504dc111-1226-4b61-b3d7-1baa00350a3f","keyword":"表面改性","originalKeyword":"表面改性"},{"id":"3a3a9583-dd18-4c3e-94bc-9a319308daab","keyword":"红外光谱","originalKeyword":"红外光谱"}],"language":"zh","publisherId":"clbh200308005","title":"表面改性<span style=\"color:red\">氢氧化铝</span>超细粉体填料的红外光谱研究","volume":"36","year":"2003"},{"abstractinfo":"论述了<span style=\"color:red\">氢氧化铝</span>粉体填料的用途、应用现状及加工现状,该产品目前在供应与需求方面显现出的矛盾.针对此项问题阐述了选用气流粉碎磨生产<span style=\"color:red\">氢氧化铝</span>粉体材料的目的、意义,充分对比了气流粉碎磨和普通万能粉碎磨的SiO2%,Fe2O3%,Na2O%,+320%、附水等产品质量指标,产能和电单耗等消耗指标.气流粉碎技术在<span style=\"color:red\">氢氧化铝</span>粉体生产中应用之后,<span style=\"color:red\">氢氧化铝</span>粉体填料的质量得到了比较大的提高,创造了可观的经济效益;同时,生产能力有较大幅度提高,且设备自动化程度高,有效减轻了职工的劳动强度.","authors":[{"authorName":"杨纪倩","id":"d37f3625-2aa3-49c0-9b20-10e9bdc4c5bb","originalAuthorName":"杨纪倩"},{"authorName":"张浩","id":"b23ecdf1-b88a-4ca7-800a-6f33b6127db8","originalAuthorName":"张浩"},{"authorName":"戚平","id":"9d00991e-609e-4295-8aa7-c860497ccab0","originalAuthorName":"戚平"}],"doi":"10.3969/j.issn.0258-7076.2006.z1.018","fpage":"72","id":"5e6f50fa-f5e0-4564-b339-b77c76319d25","issue":"z1","journal":{"abbrevTitle":"XYJS","coverImgSrc":"journal/img/cover/XYJS.jpg","id":"67","issnPpub":"0258-7076","publisherId":"XYJS","title":"稀有金属"},"keywords":[{"id":"e0aad586-f573-4e69-b39c-cda556866c7a","keyword":"气流粉碎","originalKeyword":"气流粉碎"},{"id":"7dfb3a5d-5d66-496f-ad14-5e00cc892bcc","keyword":"<span style=\"color:red\">氢氧化铝</span>","originalKeyword":"氢氧化铝"},{"id":"acc9d36f-9b44-434f-a8c0-18988411244a","keyword":"粒度","originalKeyword":"粒度"}],"language":"zh","publisherId":"xyjs2006z1018","title":"气流粉碎技术在<span style=\"color:red\">氢氧化铝</span>生产中的应用","volume":"30","year":"2006"},{"abstractinfo":"较全面地介绍了新型阻燃剂<span style=\"color:red\">氢氧化铝</span>的阻燃机理、制备方法、改性技术以及它在各领域中的广泛应用现状,并对其发展趋势进行了简要的展望.","authors":[{"authorName":"黄东","id":"1e38d50d-81dc-4927-ac16-43e54374c78a","originalAuthorName":"黄东"},{"authorName":"南海","id":"352fe29b-0509-4fce-8e99-9025cde645b7","originalAuthorName":"南海"},{"authorName":"吴鹤","id":"0d447b6a-e88e-475f-a656-f38ef710b58b","originalAuthorName":"吴鹤"}],"doi":"10.3969/j.issn.1003-1545.2004.03.010","fpage":"33","id":"d5043ea2-66be-438e-ab36-2568534dd073","issue":"3","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":"acd8e164-51d9-41df-a7f2-b19ef83eb984","keyword":"<span style=\"color:red\">氢氧化铝</span>","originalKeyword":"氢氧化铝"},{"id":"ca71d75f-b2ca-4a4b-9f9b-09f2c1db5fb6","keyword":"阻燃剂","originalKeyword":"阻燃剂"},{"id":"c037495e-d33a-409d-9d77-25e44c98a80b","keyword":"性质","originalKeyword":"性质"},{"id":"843637df-226c-44a1-9361-8d9e03c3afa1","keyword":"应用","originalKeyword":"应用"}],"language":"zh","publisherId":"clkfyyy200403010","title":"<span style=\"color:red\">氢氧化铝</span>的阻燃性质与应用研究","volume":"19","year":"2004"}],"totalpage":2982,"totalrecord":29819}