{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":2,"startPagecode":1},"records":[{"abstractinfo":"为准确预测管道腐蚀速率并得到精度较高的腐蚀速率预测模型,采用已有统计数据作为研究对象.首先,采用三次指数平滑法,建立管道腐蚀速率预测模型,对腐蚀速率数据进行拟合与预测分析;然后,得出预测模型中最合理的权重系数α;最后,通过与一次指数平滑法、二次指数平滑法进行对比分析,得出了三次指数平滑法预测精度较高,预测值与实际值相符合的结论.结果表明,三次指数平滑法预测模型符合管道腐蚀速率的特点,对有效预测管道腐蚀具有一定的参考价值和指导意义.","authors":[{"authorName":"王海涛","id":"4c5e3336-93fc-4326-a797-8178c4675a9c","originalAuthorName":"王海涛"},{"authorName":"孔明慧","id":"c949edd8-bd88-4163-b41c-2065dc438ea6","originalAuthorName":"孔明慧"}],"doi":"10.11973/fsyfh-201601002","fpage":"8","id":"2cb44a29-756a-435e-858d-bb78b8ace267","issue":"1","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"dd276ad7-2646-4ba9-befc-e4c77db60f89","keyword":"管道腐蚀","originalKeyword":"管道腐蚀"},{"id":"328a9941-5a6e-4e21-85f4-a0b387186201","keyword":"腐蚀速率预测","originalKeyword":"腐蚀速率预测"},{"id":"c2e30822-40f8-4168-bef6-375e42cbb5d1","keyword":"预测模型","originalKeyword":"预测模型"},{"id":"8b6a8287-31c4-4c26-b0bb-5eb46e1445c5","keyword":"三次指数平滑法","originalKeyword":"三次指数平滑法"},{"id":"a514443d-6520-4e8f-8058-ceeac17939f8","keyword":"权重系数","originalKeyword":"权重系数"},{"id":"c0cd715d-41cf-44f0-83ce-59bcade7aa23","keyword":"对比分析","originalKeyword":"对比分析"}],"language":"zh","publisherId":"fsyfh201601002","title":"三次指数平滑法预测管道腐蚀速率的应用","volume":"37","year":"2016"},{"abstractinfo":"采用热压法制备了CaCu3Ti4O12(CCTO)-电木复合材料,加入CCTO不但明显提高了电木的介电常数,而且显著地降低了其介电损耗.随CCTO含量增加,电阻率先变化甚少,而后急剧降低,到80wt％ CCTO时为107 Ω·m.大量添加CCTO将阻碍聚合物的交联固化,气孔明显增多.综合考虑,添加50wt％CCTO复合材料性能最好.","authors":[{"authorName":"黄旭","id":"de5319c9-fda1-43e3-91d5-80af6a06b947","originalAuthorName":"黄旭"},{"authorName":"郑兴华","id":"1ae75136-d68d-4718-b142-b5995ff3ea55","originalAuthorName":"郑兴华"},{"authorName":"汤德平","id":"e7fc0486-5afd-4cab-9f02-10156660b004","originalAuthorName":"汤德平"},{"authorName":"杨小炳","id":"5f443cec-d813-4392-92ee-cd2b5e3190cd","originalAuthorName":"杨小炳"},{"authorName":"洪聪杰","id":"8936009e-d87b-4d0d-80a8-6f8a8ff4fcdd","originalAuthorName":"洪聪杰"},{"authorName":"林芬","id":"e5db1774-46b2-44a8-9f8d-e2b2ff601a63","originalAuthorName":"林芬"}],"doi":"","fpage":"33","id":"616c5226-21e1-4306-a4fd-3cd5b861d4dd","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":"f90793fe-de5d-470d-ba6f-44f523f6cb35","keyword":"CCTO","originalKeyword":"CCTO"},{"id":"947c25f6-9049-4b31-a7e9-bf0d463cc990","keyword":"电木","originalKeyword":"电木"},{"id":"546c93e9-77c9-44ba-bf2a-d1e3313a354e","keyword":"热压","originalKeyword":"热压"},{"id":"b1871b99-58cc-4c82-a016-b3fd37871812","keyword":"介电性能","originalKeyword":"介电性能"}],"language":"zh","publisherId":"gsytb201201007","title":"CCTO-电木复合材料的制备、结构和介电性能","volume":"31","year":"2012"},{"abstractinfo":"研究了不同温度烧结对掺Nd3+的Ni-Zn铁氧体组织和磁性能的影响.随着烧结温度的增加,含Nd3+铁氧体粒度和数量相应增加,气孔明显减少.实验发现,烧结温度为1250℃时的试样有较好的综合性能,不仅具有较高的磁导率而且损耗也较小.","authors":[{"authorName":"闫永旺","id":"f266a583-e721-426f-a14b-a5a30589ed26","originalAuthorName":"闫永旺"},{"authorName":"范秀风","id":"d2e569da-efba-4bd4-838e-18d772c64057","originalAuthorName":"范秀风"},{"authorName":"任慧平","id":"37532179-f9bd-4991-83eb-f66e7341b83d","originalAuthorName":"任慧平"},{"authorName":"张羊换","id":"79155d8d-09f2-47f1-b2d6-973af3367ce9","originalAuthorName":"张羊换"}],"doi":"10.3969/j.issn.1004-0277.2012.04.019","fpage":"90","id":"d1b19a55-6633-4f02-beb9-b14b5564b2a4","issue":"4","journal":{"abbrevTitle":"XT","coverImgSrc":"journal/img/cover/XT.jpg","id":"65","issnPpub":"1004-0277","publisherId":"XT","title":"稀土"},"keywords":[{"id":"0b7cf0de-f61a-49a9-be65-afa2a8872461","keyword":"烧结温度","originalKeyword":"烧结温度"},{"id":"1c224849-87da-4eb5-b27a-51d384dfc2f7","keyword":"掺Nd3+的Ni-Zn铁氧体","originalKeyword":"掺Nd3+的Ni-Zn铁氧体"},{"id":"4745e37a-d270-49e5-a6ea-49bf1b870f80","keyword":"磁导率","originalKeyword":"磁导率"},{"id":"e3f07d24-7986-458a-81df-65dde9d3fa41","keyword":"损耗","originalKeyword":"损耗"}],"language":"zh","publisherId":"xitu201204019","title":"烧结温度对掺Nd3+的Ni-Zn铁氧体组织和磁性能的影响","volume":"33","year":"2012"},{"abstractinfo":"用挤出成型的方法制备高性能陶瓷膜用Al2O3＞99%支撑体,制备中受初始颗粒度、烧成温度、粘结剂等因素的影响,因此可以调节一个或几个因素来控制支撑体的性能.用硬脂酸铝为造孔剂,调节支撑体的孔径和气孔率时发现造孔剂质量分数＜5%和＞5%在坯体中的分布不同,成孔的作用也不一样.造孔剂用量＜5%时,对成孔作用不大,＞5%时成孔明显,但造孔剂的添加量不宜超过15%.","authors":[{"authorName":"丁祥金","id":"a604f6c6-7a9f-4315-9a4f-b2db0fdbdf8e","originalAuthorName":"丁祥金"},{"authorName":"张继周","id":"ad3c8a7d-60d3-4447-a1cb-d00127cf055a","originalAuthorName":"张继周"},{"authorName":"宝志琴","id":"5494666e-dc6f-4c1e-b03b-bed4e7bacf01","originalAuthorName":"宝志琴"},{"authorName":"丁传贤","id":"5f037c8b-9ee3-4675-8746-cfd5f5a4662f","originalAuthorName":"丁传贤"}],"doi":"10.3969/j.issn.1007-8924.2000.01.004","fpage":"17","id":"5b4e40f1-1d2e-454f-ad67-54347561a7db","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":"f4403c31-cf5d-4b63-abed-0779a1a258f0","keyword":"Al2O3多孔支撑体","originalKeyword":"Al2O3多孔支撑体"},{"id":"cd1443c4-1893-4950-87f0-d8b008587d8b","keyword":"挤出成型","originalKeyword":"挤出成型"},{"id":"c1f41468-03ca-458d-a125-c5afdc1feb8d","keyword":"硬脂酸铝","originalKeyword":"硬脂酸铝"}],"language":"zh","publisherId":"mkxyjs200001004","title":"氧化铝多孔支撑体的研究","volume":"20","year":"2000"},{"abstractinfo":"在氧化铬材料中分别引入0.3%、0.6%、0.9%和1.2%(按Cr2O3的质量分数计)的纳米Cr2O3前驱体--氢氧化铬溶胶,通过喷雾造粒、等静压成型,将制备的致密氧化铬试样在氮气气氛中分别于1 350、1 400、1 450 ℃下烧成后,测定烧后试样的显气孔率和常温抗折强度,并采用SEM分析烧成后试样的显微结构.结果表明:加入氢氧化铬溶胶促进了致密氧化铬材料的烧结,其加入量为w(Cr2O3)=0.3%时,材料中的气孔明显减少,常温抗折强度显著提高;加入适量氢氧化铬溶胶促进了材料的烧结致密化,使试样结构更加致密,气孔呈微细化均匀分布.","authors":[{"authorName":"徐延庆","id":"827d4bf3-cd52-48ca-acbf-250ea9dc8979","originalAuthorName":"徐延庆"},{"authorName":"吕世坪","id":"18532fe5-5a8c-44d8-a411-446ef73bf532","originalAuthorName":"吕世坪"},{"authorName":"范志辉","id":"1bbcddc1-3937-447b-b094-99056d855313","originalAuthorName":"范志辉"},{"authorName":"王金相","id":"3828a5ef-4bfa-4fc7-b515-86f6cca5871c","originalAuthorName":"王金相"},{"authorName":"洪彦若","id":"5d0aa0de-169a-40ca-8e9e-f0fdd66023bd","originalAuthorName":"洪彦若"},{"authorName":"陈肇友","id":"e0be80b4-21d7-46a8-adf8-88786b2c8a9e","originalAuthorName":"陈肇友"}],"doi":"10.3969/j.issn.1001-1935.2010.01.008","fpage":"30","id":"48c8cf6e-2154-429a-b151-2a8ec0d30804","issue":"1","journal":{"abbrevTitle":"NHCL","coverImgSrc":"journal/img/cover/NHCL.jpg","id":"55","issnPpub":"1001-1935","publisherId":"NHCL","title":"耐火材料 "},"keywords":[{"id":"59b57caf-ce5c-4f9e-8632-1c21516abee8","keyword":"氢氧化铬溶胶","originalKeyword":"氢氧化铬溶胶"},{"id":"4537bbcd-9f0f-4247-a07b-9f3d1a720ee8","keyword":"纳米氧化铬","originalKeyword":"纳米氧化铬"},{"id":"5a6cf8df-70e7-41ba-8558-843dff8bcccf","keyword":"致密氧化铬材料","originalKeyword":"致密氧化铬材料"},{"id":"2663599e-95d4-43c4-af96-371b117b8487","keyword":"烧结","originalKeyword":"烧结"},{"id":"4e53a43e-0036-441a-a05f-4c3d6be1a21d","keyword":"致密化","originalKeyword":"致密化"},{"id":"95f0bb2e-c819-4667-8aed-f79ff5e3c998","keyword":"微气孔","originalKeyword":"微气孔"}],"language":"zh","publisherId":"nhcl201001008","title":"引入纳米Cr2O3前驱体对致密氧化铬材料烧结的影响","volume":"44","year":"2010"},{"abstractinfo":"中锰钢预热系数小，膨胀系数高且具有良好的耐磨特性，在工业领域应用广泛。但因其运行环境恶劣，常受到外界压力的持续冲击，加之铸造过程中表面形成气孔、夹杂等缺陷使得中锰钢常因疲劳而破裂损坏。为了解决这一问题，运用表面改性技术，使用自蔓延特种陶瓷焊条对坦克装甲履带中锰钢表面进行焊接，在中锰钢的表面熔入大量的 TiC 颗粒。实验结果表明：熔有陶瓷相的中锰钢的表面组织更加均匀，气孔明显减少，并且 TiC 陶瓷相均匀分布在中锰钢中，与中锰钢组织结合良好，无明显裂纹出现。实验证明 TiC 陶瓷相的加入可有效地提高中锰钢的硬度和耐磨性能。","authors":[{"authorName":"张啸宇","id":"a6fa45b4-7a86-45dc-a8d1-a1d452c9ac00","originalAuthorName":"张啸宇"},{"authorName":"谭俊","id":"2e81a882-2ec9-4d70-bdf7-78902ac92bc0","originalAuthorName":"谭俊"},{"authorName":"任伟","id":"96adeb14-341d-4b27-98f4-fc4da28bd2e2","originalAuthorName":"任伟"},{"authorName":"张勇","id":"8667ba7d-a1a7-4257-8996-21bd67efbb7d","originalAuthorName":"张勇"},{"authorName":"董美伶","id":"c2036afc-3dd7-4ea0-9f9a-17895b4b70cd","originalAuthorName":"董美伶"},{"authorName":"兰龙","id":"04507e31-00f8-4a36-93b9-f36eb009abaf","originalAuthorName":"兰龙"}],"doi":"10.11896/j.issn.1005-023X.2015.12.023","fpage":"106","id":"b251bfcb-2e44-42fc-8557-e1c62fd8ffa8","issue":"12","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"93f730b5-6b46-4698-af68-a9f8d8354d9f","keyword":"中锰钢","originalKeyword":"中锰钢"},{"id":"406306da-7cff-4948-ae86-03dac5488385","keyword":"TiC 颗粒","originalKeyword":"TiC 颗粒"},{"id":"0aa349a9-1e67-4e68-ac01-7b63b919fcec","keyword":"耐磨性","originalKeyword":"耐磨性"},{"id":"eb72768d-7f4a-4975-9e2e-550e60ec54ce","keyword":"硬度","originalKeyword":"硬度"}],"language":"zh","publisherId":"cldb201512023","title":"中锰钢表面堆焊 TiC 的组织与性能?","volume":"","year":"2015"},{"abstractinfo":"本文应用Sol－Gel方法制备了YSZ薄膜，研究了工艺条件对薄膜微观结构的影响.实验发现：基片的选择和清洁、样品的凝胶化速度、热处理过程中的升降温速率等是影响薄膜开裂的几个主要因素．XRD和SEM分析结果表明：应用Sol－Gel方法制备的YSZ薄膜，热处理温度须达800℃以上才能完全排除其中的酸根、有机基因和碳元素，且形成完整的立方相结构．薄膜经500℃、1h热处理后，其表面呈明显的海绵状结构．随着烧结温度的升高，薄膜表面变得致密，气孔明显减少，至1050℃时，薄膜表面光滑、无裂纹、无针孔、圆球形的小颗粒均匀分布．薄膜与衬底的结合紧密，薄膜厚度均匀，膜厚约为1.0μm.","authors":[{"authorName":"章天金","id":"fb2ed993-4ba0-4bb0-9e07-bfb6d441f5af","originalAuthorName":"章天金"},{"authorName":"唐超群","id":"61abe2a3-966e-4204-9f85-d7eb39caf6b3","originalAuthorName":"唐超群"},{"authorName":"周东祥","id":"d8e9fe48-347e-4456-a858-de97f8aa6594","originalAuthorName":"周东祥"},{"authorName":"潘小龙","id":"e53d1e42-8c07-4df5-8356-ae66793ea0ba","originalAuthorName":"潘小龙"}],"categoryName":"|","doi":"","fpage":"200","id":"ccfa7481-9c5f-4a92-be58-0dcd86f05d59","issue":"2","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":"9c97d44c-ed32-4fcb-83f8-aa27f513ee4d","keyword":"Sol-Gel法","originalKeyword":"Sol-Gel法"},{"id":"c041cc0f-1530-468a-9bea-d88f23843906","keyword":" YSZ films","originalKeyword":" YSZ films"},{"id":"5d824c97-6588-46e4-8128-b99519db31d4","keyword":" preparation","originalKeyword":" preparation"},{"id":"c34fbc06-d497-4abe-88c0-2526d6f91213","keyword":" crack","originalKeyword":" crack"}],"language":"zh","publisherId":"1000-324X_1997_2_15","title":"YSZ薄膜Sol-Gel法制备及其结构分析","volume":"12","year":"1997"},{"abstractinfo":"系统研究了在K417高温合金真空熔铸过程中施加由工频交流电磁场和恒稳直流电磁场组成的复合电磁场对高温合金铸锭凝固组织的影响.实验结果表明:在浇注完毕后同时施加60A旋转电磁场和290A恒稳直流电磁场的工艺条件下,由于恒稳直流电磁场在金属液面处产生的电磁制动效应可以抑制施加旋转电磁场所引起的金属液面的波动,不仅避免了因金属液面波动太大而使铸锭缩孔恶化的情况出现,而且大幅提高了旋转电磁场在金属液凝固过程中的作用范围和效果,最终得到细小等轴晶比例达到96％、缩孔明显改善的优质高温合金铸锭.","authors":[{"authorName":"金文中","id":"cd6caac6-6bb0-4cfe-a104-e8842383088a","originalAuthorName":"金文中"},{"authorName":"李素芳","id":"c7c11de9-2138-4b45-b1a3-002a3dd2db4a","originalAuthorName":"李素芳"},{"authorName":"李廷举","id":"309ad0c5-e326-4142-bd2d-d334d7af4c0a","originalAuthorName":"李廷举"},{"authorName":"殷国茂","id":"71a31016-7d14-4acf-ae2f-24591209bc70","originalAuthorName":"殷国茂"}],"doi":"","fpage":"1546","id":"cdb6c78a-8f04-4cce-b87b-f4ddb93ea264","issue":"6","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":"1cfc59e5-beb2-4365-a525-613ec13cf6c3","keyword":"复合电磁场","originalKeyword":"复合电磁场"},{"id":"b2256c5a-82f9-4480-ad52-0c4fae96d289","keyword":"高温合金铸锭","originalKeyword":"高温合金铸锭"},{"id":"aa61c4f2-9b08-4259-9bfc-f66e9aca2594","keyword":"真空熔铸","originalKeyword":"真空熔铸"},{"id":"6e6df5bd-1f1d-4d48-b722-f983a0d259d6","keyword":"电磁制动","originalKeyword":"电磁制动"},{"id":"4f4d871c-0548-4915-b781-6bc57111ed39","keyword":"缩孔","originalKeyword":"缩孔"}],"language":"zh","publisherId":"xyjsclygc201506048","title":"复合电磁场作用下高温合金锭的真空熔铸技术研究","volume":"44","year":"2015"},{"abstractinfo":"为研究养护条件和水灰比对混凝土抗氯离子渗透性与微观孔结构的影响规律与程度,采用压汞法和RCM法对-3℃养护条件下和标准养护条件下的不同水灰比的混凝土28 d微观孔结构和氯离子渗透系数进行了测试.试验结果表明:-3℃负温养护条件下混凝土的临界孔径和最可几孔径明显大于标准养护条件下的同种混凝土,孔径粗化严重,粗大孔明显增多,其氯离子渗透系数也明显大于标准养护条件下的混凝土,与孔结构的发展规律一致.标准养护条件下,随着水灰比的提高,混凝土水泥石孔结构劣化,混凝土抗氯离子渗透性减弱;但在-3℃养护条件下,混凝土水泥石孔结构随着水灰比的提高呈现出先优化后劣化的趋势,混凝土抗氯离子渗透性变化规律亦与之相同.","authors":[{"authorName":"谢超","id":"c33b5edb-f6ce-465d-804d-65b963fe8ddc","originalAuthorName":"谢超"},{"authorName":"王起才","id":"38d0e705-3014-46c6-b1f7-f4cc2917d35d","originalAuthorName":"王起才"},{"authorName":"李盛","id":"e9fda6ab-7aa2-4008-85fd-3604cc73c171","originalAuthorName":"李盛"},{"authorName":"惠兵","id":"4b6cb894-2074-4dc2-860c-de76df25c0ce","originalAuthorName":"惠兵"}],"doi":"","fpage":"3663","id":"05b78419-f80b-4ded-80de-fb07c82ba8e8","issue":"12","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"150b999f-5c99-4683-868c-5ae9d06ef421","keyword":"-3℃养护条件","originalKeyword":"-3℃养护条件"},{"id":"96084d5b-9617-4e57-9c5a-d647bd0cebf5","keyword":"水灰比","originalKeyword":"水灰比"},{"id":"5cef80cf-b3f0-4524-bbd0-e01cc07611ec","keyword":"混凝土","originalKeyword":"混凝土"},{"id":"9d81fa94-e82e-42fb-9ec8-69d5e682519e","keyword":"孔结构","originalKeyword":"孔结构"},{"id":"e4831957-2348-4dad-b54b-3ba2daf5c7b9","keyword":"渗透性","originalKeyword":"渗透性"}],"language":"zh","publisherId":"gsytb201512048","title":"养护温度和水灰比对混凝土微观孔结构及抗氯离子渗透性影响研究","volume":"34","year":"2015"},{"abstractinfo":"为研究养护条件和水灰比对混凝土抗氯离子渗透性和细观孔结构的影响规律与程度,采用气孔分析法和直流电量法对-3℃养护条件下和标准养护条件下的不同水灰比的混凝土28 d细观孔结构和电通量进行了测试.试验结果表明:-3℃负温养护条件下的混凝土气孔间距系数和平均气孔直径明显大于标准养护条件下的同种混凝土,孔径粗化严重,粗大孔明显增多;-3℃负温养护条件下的混凝土电通量值也明显大于标准养护条件下的混凝土,与细观孔结构测试结果一致.标准养护条件下,随着水灰比的提高,混凝土细观孔结构随之劣化,抗氯离子渗透性减弱;但在-3℃养护条件下,混凝土细观孔结构随着水灰比的提高反而优化,抗氯离子渗透性亦随之变强,究其原因,在-3℃养护条件下,随着水灰比提高,混凝土中液相水含量随之增大,水化反应更加充分,故出现上述现象.水灰比对细观孔结构和抗氯离子渗透性的影响程度较养护条件小,且随着水灰比的增大,养护条件对其影响程度减弱.","authors":[{"authorName":"谢超","id":"1ad9a5fb-6c09-4375-a0dd-9942a5a0da60","originalAuthorName":"谢超"},{"authorName":"王起才","id":"c2e7df6b-ff9b-4929-b205-499fa847e562","originalAuthorName":"王起才"},{"authorName":"于本田","id":"da853aec-04f0-4d41-9f79-448baf6d7d09","originalAuthorName":"于本田"},{"authorName":"段运","id":"7caa0fb5-88b7-46e4-b74c-5ec1b3bac9e4","originalAuthorName":"段运"}],"doi":"","fpage":"2119","id":"0a8d1887-8a65-471d-9a4d-4f848ac59027","issue":"8","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"206218a6-6b0e-4f21-b2fb-f0c736ca6889","keyword":"-3℃养护条件","originalKeyword":"-3℃养护条件"},{"id":"cc5042c6-5713-4aea-92d1-43e73504186f","keyword":"水灰比","originalKeyword":"水灰比"},{"id":"407cd135-cf7f-4378-8231-3d9ac172972c","keyword":"混凝土","originalKeyword":"混凝土"},{"id":"1393a0e3-8500-446b-89e1-a75e9255f45f","keyword":"孔结构","originalKeyword":"孔结构"},{"id":"83bce529-c622-4311-9f8e-4e4476c14e4c","keyword":"渗透性","originalKeyword":"渗透性"}],"language":"zh","publisherId":"gsytb201508008","title":"负温养护条件及水灰比对混凝土抗氯离子渗透性和细观结构影响试验研究","volume":"34","year":"2015"}],"totalpage":2,"totalrecord":14}