{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"本文采用修正的膜模型与Nusselt凝结理论结合的方法,分析了双组分可凝气体的凝结吸收机理,探讨了竖直圆管内水蒸汽凝结与二氧化硫气体吸收的传热传质过程,并阐述了雷诺数、壁面温度及水蒸汽浓度等因素对二氧化硫气体传递的影响.","authors":[{"authorName":"贾力","id":"28b0cb3c-f800-47a6-a9a5-82704068578a","originalAuthorName":"贾力"},{"authorName":"鲁国丽","id":"97e79b6d-fea1-46b2-9d31-9471c2a4234e","originalAuthorName":"鲁国丽"}],"doi":"","fpage":"1010","id":"6328c5bb-b29c-4c88-86ac-7790dc72a5f4","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":"20272709-1dd3-4f47-84ba-fd81db79a30f","keyword":"混合气体","originalKeyword":"混合气体"},{"id":"070093c1-1ea1-4edb-add4-b21efcbbaacc","keyword":"凝结换热","originalKeyword":"凝结换热"},{"id":"8b10fb82-1590-4b8f-a464-6e2bc9ea61c0","keyword":"SO2吸收","originalKeyword":"SO2吸收"}],"language":"zh","publisherId":"gcrwlxb200306032","title":"竖直管内混合气体的凝结换热与SO2传递机理的理论研究","volume":"24","year":"2003"},{"abstractinfo":"针对现行钠碱法的缺点提出了膜电解法处理低浓度SO2吸收液的方法,给出了工艺流程图,描述了三室膜电解槽的结构及其工作原理,系统的讨论了其中主要结构单元材料的选择,如F4112阳离子交换膜、钛基二氧化铅阳极、活性镍阴极.实验得出了阳极室中硫酸溶液的最佳浓度、料液循环方式、操作电流密度和电流效率的关系.认为此新方法是一种有前途的处理低浓度SO2气体的方法.","authors":[{"authorName":"保积庆","id":"bbf1063e-5406-486c-8dfa-b1ff4b4a69fc","originalAuthorName":"保积庆"},{"authorName":"张启修","id":"595dd3a0-790d-456a-abf3-4789a598c2dc","originalAuthorName":"张启修"}],"doi":"10.3969/j.issn.1007-8924.2003.05.009","fpage":"37","id":"25b7463e-8a49-481d-a177-792b630423f9","issue":"5","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":"9cdeeca3-27ca-4000-ae66-71ace265e205","keyword":"二氧化硫","originalKeyword":"二氧化硫"},{"id":"1c7c1205-69d1-48e9-85cc-0ad76e947601","keyword":"膜电解","originalKeyword":"膜电解"},{"id":"acf2e8d3-53f6-4ae3-b5af-d62eb9277324","keyword":"金属阳极","originalKeyword":"金属阳极"},{"id":"a5ed1887-f079-4552-a54f-cdf2e7c472da","keyword":"离子膜","originalKeyword":"离子膜"}],"language":"zh","publisherId":"mkxyjs200305009","title":"三室膜电解槽处理低浓度SO2吸收液","volume":"23","year":"2003"},{"abstractinfo":"现代钢铁联合企业的高炉-转炉流程是铁-煤化工过程,针对该流程中烧结工序排放含二氧化硫烟气的特点,采用软锰矿、菱锰矿脱硫制取硫酸锰.采用菱锰矿调节和控制矿浆的pH值,利用软锰矿中MnO2的氧化性和SO2的还原性,用软锰矿矿浆在填料吸收塔内进行脱硫试验.试验结果表明:二氧化硫的吸收率在95%以上,该工艺还具有湿法除尘的特性,对烟尘的吸收率达90%以上,且副产品硫酸锰的质量能达到工业级,是一种真正实现\"综合治理、变废为宝\"的脱硫新技术.","authors":[{"authorName":"吴复忠","id":"f3e6a218-0f0a-4c39-a921-73b9d1d48cd3","originalAuthorName":"吴复忠"},{"authorName":"蔡九菊","id":"9abbbf1f-4dc0-4518-b3c6-ba9aa0f664bc","originalAuthorName":"蔡九菊"},{"authorName":"张琦","id":"789e52f6-3342-4d15-8c45-187b9f9a4800","originalAuthorName":"张琦"},{"authorName":"王建军","id":"3ffd18fd-b5b7-4a40-b894-25767940aeb6","originalAuthorName":"王建军"},{"authorName":"葛红","id":"8298cab3-99ed-49af-b5b6-c948ff25387b","originalAuthorName":"葛红"}],"doi":"","fpage":"78","id":"a07d7140-19b0-45af-8c6d-70e0fb038acd","issue":"4","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"fe62852f-ebe7-4654-b741-eeb32809a6c3","keyword":"烧结烟气","originalKeyword":"烧结烟气"},{"id":"5670023c-c443-4911-a0e9-ba5ca18a39e3","keyword":"软锰矿","originalKeyword":"软锰矿"},{"id":"9c782be5-e2c5-4d18-853c-1badd3366506","keyword":"菱锰矿","originalKeyword":"菱锰矿"},{"id":"2883f8e5-f2b5-476f-bbbe-c1909851d7a2","keyword":"脱硫","originalKeyword":"脱硫"},{"id":"39386e2e-60b4-4b60-9290-3fe033ae70db","keyword":"硫酸锰","originalKeyword":"硫酸锰"}],"language":"zh","publisherId":"gt200704020","title":"软锰矿、菱锰矿吸收烧结烟气中的SO2制取硫酸锰","volume":"42","year":"2007"},{"abstractinfo":"现代钢铁联合企业的高炉转炉流程是铁煤化工过程,针对该流程中烧结工序排放含二氧化硫烟气的特点,采用软锰矿、菱锰矿脱硫制取硫酸锰。采用菱锰矿调节和控制矿浆的pH值,利用软锰矿中MnO2的氧化性和SO2的还原性,用软锰矿矿浆在填料吸收塔内进行脱硫试验。试验结果表明:二氧化硫的吸收率在95%以上,该工艺还具有湿法除尘的特性,对烟尘的吸收率达90%以上,且副产品硫酸锰的质量能达到工业级,是一种真正实现“综合治理、变废为宝”的脱硫新技术。","authors":[{"authorName":"吴复忠","id":"41d11056-05f1-4acc-bb1e-e589ecc32254","originalAuthorName":"吴复忠"},{"authorName":"蔡九菊","id":"efcfd348-7e92-48b3-befc-cc78808a135a","originalAuthorName":"蔡九菊"},{"authorName":"张琦","id":"b1a885f9-c2cc-4878-ae92-fdecaf02a8a6","originalAuthorName":"张琦"},{"authorName":"王建军","id":"5a18ef05-01ca-462f-8cf2-1c0b5ac0618d","originalAuthorName":"王建军"},{"authorName":"葛红","id":"2637d65b-1df5-4625-bef5-000ec3ff3bf7","originalAuthorName":"葛红"}],"categoryName":"|","doi":"","fpage":"78","id":"d0ee42f2-8863-4b52-8d90-16fc54ad7ed1","issue":"4","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"da3fbd67-4792-40d4-ad4c-5be054388b4b","keyword":"烧结烟气;软锰矿;菱锰矿;脱硫;硫酸锰","originalKeyword":"烧结烟气;软锰矿;菱锰矿;脱硫;硫酸锰"}],"language":"zh","publisherId":"0449-749X_2007_4_15","title":"软锰矿、菱锰矿吸收烧结烟气中的SO2制取硫酸锰","volume":"42","year":"2007"},{"abstractinfo":"本文用我们自己研制的光谱测量系统测量了常温下的SO2在250~330 nm波段和NO2在280~600nm波段的吸收截面,波长分辨率优于0.1 nm。该测量结果可适用于传统低光谱分辨率仪器遥感大气污染气体含量,也可为激光差分吸收测量或激光雷达测量污染气体含量提供参考。","authors":[{"authorName":"魏合理","id":"a281e218-5bd6-4588-8ff5-8dd270d68659","originalAuthorName":"魏合理"},{"authorName":"龚知本","id":"0d556239-e912-4ad8-ae06-7190ed8e066b","originalAuthorName":"龚知本"},{"authorName":"马志军","id":"7e039b4b-eb0a-40ac-86dc-f61e92480746","originalAuthorName":"马志军"},{"authorName":"孙明","id":"8940348e-a7bd-4c1f-89dc-d7c9bb02b17e","originalAuthorName":"孙明"},{"authorName":"周金刚","id":"9749bf6c-73a4-4044-b998-292ab36ef01a","originalAuthorName":"周金刚"},{"authorName":"崔益本","id":"86c71ce1-1ffa-40e6-ab28-1c282e8f7405","originalAuthorName":"崔益本"},{"authorName":"邬承就","id":"9a775e82-5e1c-45b1-8c8f-d27ac62e54a7","originalAuthorName":"邬承就"}],"doi":"10.3969/j.issn.1007-5461.2001.01.003","fpage":"16","id":"ed69f02a-6b92-4cea-8792-ca5cecf990da","issue":"1","journal":{"abbrevTitle":"LZDZXB","coverImgSrc":"journal/img/cover/LZDZXB.jpg","id":"53","issnPpub":"1007-5461","publisherId":"LZDZXB","title":"量子电子学报 "},"keywords":[{"id":"aa3062d6-6a5c-45a1-b2a3-f45a295a1a85","keyword":"吸收截面","originalKeyword":"吸收截面"},{"id":"7be4274e-e0d6-43fd-a054-7e78d04832e0","keyword":"SO2","originalKeyword":"SO2"},{"id":"e41f5bf5-ac00-4d2b-9281-39410a5f37bd","keyword":"NO2","originalKeyword":"NO2"},{"id":"b68f6a48-5d71-482a-9c17-25e4704aeda2","keyword":"UV光谱","originalKeyword":"UV光谱"},{"id":"74ef9417-96d7-4b83-8e9a-5f1393b0cd98","keyword":"可见光谱","originalKeyword":"可见光谱"}],"language":"zh","publisherId":"lzdzxb200101003","title":"污染气体SO2和NO2紫外和可见光谱吸收截面测量","volume":"18","year":"2001"},{"abstractinfo":"采用中空纤维膜接触器对柠檬酸盐溶液吸收模拟烟气中SO2的行为进行了研究.考察了柠檬酸盐溶液浓度、溶液pH值对膜吸收效果的影响,对比了不同中空纤维膜材料的吸收效果,考察了吸收液中硫酸根的生成情况.研究结果表明:增大柠檬酸盐浓度有利于提高SO2的吸收速率和容量;吸收液pH值越高,吸收效果越好;疏水性中空纤维膜吸收效果优于亲水性膜;吸收液中硫酸根离子浓度随时间基本呈线性增加,增加的速率约为0.192 g/(L·h).","authors":[{"authorName":"薛娟琴","id":"7eb7f924-3b98-4a70-a0ad-573cabbba322","originalAuthorName":"薛娟琴"},{"authorName":"兰新哲","id":"ed66d613-e5b8-4404-a6fe-3d01f0349878","originalAuthorName":"兰新哲"},{"authorName":"王召启","id":"15142ad1-a458-4e6e-aeaf-7c894c7b780f","originalAuthorName":"王召启"},{"authorName":"孟令嫒","id":"8d2c68de-a240-4955-8233-18b6a4b6cc78","originalAuthorName":"孟令嫒"}],"doi":"10.3969/j.issn.1007-8924.2007.02.009","fpage":"45","id":"04621849-dce0-46b6-b4b3-b347e8c1dd4a","issue":"2","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":"04e1f74d-cdf5-4c9d-b1f3-bb4ac9565ce5","keyword":"中空纤维膜","originalKeyword":"中空纤维膜"},{"id":"7fa34b9b-4954-436c-9060-42800d408fd4","keyword":"膜吸收","originalKeyword":"膜吸收"},{"id":"a05d947f-b16c-410a-88cf-3b261523b296","keyword":"柠檬酸","originalKeyword":"柠檬酸"},{"id":"46a4c45c-7850-4546-b5e3-96056277f452","keyword":"低浓度SO2","originalKeyword":"低浓度SO2"}],"language":"zh","publisherId":"mkxyjs200702009","title":"中空纤维膜接触器用于柠檬酸盐溶液吸收模拟烟气中SO2的研究","volume":"27","year":"2007"},{"abstractinfo":"烧结过程中SO2的产生受加热温度、加热时间、氧气浓度、焦粉粒度、混合料水分、碱度等因素影响。通过对铁矿烧结过程SO2排放规律的系统研究,设计了烧结烟气脱硫综合方案,脱硫装置处理烟气中SO2 浓度提高50%左右, SO2脱除率达到98%。","authors":[{"authorName":"党玉华","id":"ea24d826-3ab3-4ab5-8c69-61c14c434bfd","originalAuthorName":"党玉华"}],"categoryName":"|","doi":"","fpage":"88","id":"c275787c-bdd0-4fce-9cd2-9b6de7a7d672","issue":"5","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"145ebdf6-ea08-414c-bdee-68cce0d328b0","keyword":"烧结;烟气脱硫;SO2脱除率","originalKeyword":"烧结;烟气脱硫;SO2脱除率"}],"language":"zh","publisherId":"0449-749X_2010_5_2","title":"烧结过程SO2脱除的研究","volume":"45","year":"2010"},{"abstractinfo":"研究了铁矿烧结过程中SO2的排放规律.研究结果表明:烧结过程中SO2的浓度受加热温度、加热时间、氧气浓度、焦粉粒度、混合料水分、碱度等因素影响.设计了烧结烟气脱硫综合方案,脱硫装置处理烟气中SO2浓度提高50%左右,SO2脱除率达到98%.","authors":[{"authorName":"党玉华","id":"68869c75-5217-4671-976d-c6b90df2dfb4","originalAuthorName":"党玉华"},{"authorName":"王海风","id":"69e4ce21-8acd-46d1-bb9f-614111a8f514","originalAuthorName":"王海风"},{"authorName":"齐渊洪","id":"6ca8f6bd-8cc4-4b02-a6e1-42500125735b","originalAuthorName":"齐渊洪"}],"doi":"","fpage":"88","id":"cb75cd2d-2a2e-49a7-8510-e9404d8df07b","issue":"5","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"ebe7284a-c5ec-490a-a531-0bf51ea16e69","keyword":"烧结","originalKeyword":"烧结"},{"id":"7ede77ad-88b2-41aa-99da-e864f4c05be2","keyword":"烟气脱硫","originalKeyword":"烟气脱硫"},{"id":"0bff61c6-812a-4c6b-a5e9-1d7d90af27d7","keyword":"SO2脱除率","originalKeyword":"SO2脱除率"}],"language":"zh","publisherId":"gt201005020","title":"烧结过程SO2脱除的研究","volume":"45","year":"2010"},{"abstractinfo":"湿式静电除尘技术是实现燃煤烟气超低排放的关键技术,本文研究了湿式静电中电晕放电对SO2强化吸收的影响规律,并就SO2对电晕电流的形成、粉尘脱除的影响进行了研究.结果表明:湿式静电中喷淋液滴对SO2具有洗涤作用,电晕放电可以强化液滴对SO2的吸收效果,提高气液相间的有效传质速度.湿态条件下放电可最高实现SO2传质提高13.8%,干态条件下放电对SO2无脱除效果.SO2吸附电子致使进入吸附区的自由电子数目减少,降低了颗粒的荷电,粉尘的脱除效率下降.","authors":[{"authorName":"杨正大","id":"77c3812d-c8cc-47b6-9314-f5e8d63f0e76","originalAuthorName":"杨正大"},{"authorName":"常倩云","id":"5ba5adf5-99b4-46dd-b3b7-9e86a6523788","originalAuthorName":"常倩云"},{"authorName":"岳涛","id":"2b9ce073-ba3e-450d-af1f-8b89c66e2e97","originalAuthorName":"岳涛"},{"authorName":"王毅","id":"4ec6eee8-5b0a-447c-bc14-47cc9f5c7aed","originalAuthorName":"王毅"},{"authorName":"郑成航","id":"0c151956-1fab-497d-bc9b-674cba0d8923","originalAuthorName":"郑成航"},{"authorName":"高翔","id":"3343336c-e366-40a1-a088-7b7b636f0f32","originalAuthorName":"高翔"}],"doi":"","fpage":"1365","id":"3cb4639e-3aed-4f7d-bf41-a06d23b259ef","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":"43abc1d5-3b8f-432a-aaf9-2edb0a1eb4ba","keyword":"湿式静电除尘","originalKeyword":"湿式静电除尘"},{"id":"fc72a4e5-8da4-4af6-b529-b615f7215da8","keyword":"电晕放电","originalKeyword":"电晕放电"},{"id":"56497ad1-6474-4d7f-93b0-90d1cbde00f2","keyword":"脱硫","originalKeyword":"脱硫"},{"id":"2b1b4238-0d6b-4e97-85ea-895ddf618d1c","keyword":"除尘","originalKeyword":"除尘"},{"id":"8f3ab8f7-e959-41c5-82d9-bdb2210bee82","keyword":"协同脱除","originalKeyword":"协同脱除"}],"language":"zh","publisherId":"gcrwlxb201506042","title":"湿式静电协同脱除SO2、PM试验研究","volume":"36","year":"2015"},{"abstractinfo":"The influence of NaCI deposition on the corrosion of zinc in atmospheres with and without SO2 was studied via quartz crystal microbalance. Regularity of the initial corrosion of zinc under these conditions was analyzed. The results show that NaCl can accelerate the corrosion of zinc. Mass gain of zinc increases with the exposure time, which can be correlated by using exponential decay function. The relationship between mass gain and amount of NaCl deposition is well linear at any time in air containing 1 ppm SO2, but follows quadratic function in air without SO2. More amount of NaCI deposition will slow down the corrosion to some extent after exposure for certain time in the presence of SO2. The combined effect of NaCl and SO2 on the corrosion of zinc is greater than that caused by each single component. Fourier transform infrared spectroscopy and X-ray diffraction were used to characterize the corrosion products of zinc. In the absence of SO2, simonkolleite, Zn-5(OH)(8)Cl-2 (.) H2O and zincite, ZnO are the dominant corrosion products, while zinc hydroxysulfate (Zn4SO4(OH)(6) (.) 3H(2)O), zinc chloride sulfate hydroxide hydrate (Zn-12(SO4)(3)Cl-3 (.) (OH)(15) (.) 5H(2)O) and simonkolleite dominate in the presence of SO2. Brief discussion on the mechanisms of atmospheric corrosion under these conditions was introduced. (C) 2002 Elsevier Science Ltd. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"2789","id":"100268b1-ca4f-4db3-86a6-6d2a16a10d2c","issue":"12","journal":{"abbrevTitle":"CS","id":"36011533-0ced-443e-899a-7c7323dae3b5","issnPpub":"0010-938X","publisherId":"CS","title":"Corrosion Science"},"keywords":[{"id":"75e1d63e-6323-4dcd-af12-7d39d7e3bc45","keyword":"zinc;atmospheric corrosion;corrosion regularity;quartz crystal;microbalance;NaCl;SO2;sulfur-dioxide","originalKeyword":"zinc;atmospheric corrosion;corrosion regularity;quartz crystal;microbalance;NaCl;SO2;sulfur-dioxide"}],"language":"en","publisherId":"0010-938X_2002_12_2","title":"Effects of NaCl and SO2 on the initial atmospheric corrosion of zinc","volume":"44","year":"2002"}],"totalpage":8403,"totalrecord":84021}