{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"讨论连铸生产过程中铸坯温度对含Nb钢高温塑性的影响,在此基础上确定铸坯在二冷段各区的表面目标温度,介绍计算二冷配水的方法,并讨论中间罐钢水温度对二冷配水的影响.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">克强</span>","id":"f2f206da-c749-4f08-a42c-e05f40802957","originalAuthorName":"张克强"},{"authorName":"吴国庆","id":"86e080cd-9226-49b9-b897-e817ccbb1d24","originalAuthorName":"吴国庆"},{"authorName":"吴建忠","id":"b6fb2433-2d62-4851-8754-aec200a2cdd3","originalAuthorName":"吴建忠"},{"authorName":"宋雯琦","id":"20b3dae2-d68d-484a-8093-7357923bddb2","originalAuthorName":"宋雯琦"}],"doi":"10.3969/j.issn.1005-4006.2002.06.001","fpage":"1","id":"432ca537-17a1-473a-ad67-f803c231e455","issue":"6","journal":{"abbrevTitle":"LZ","coverImgSrc":"journal/img/cover/LZ.jpg","id":"52","issnPpub":"1005-4006","publisherId":"LZ","title":"连铸"},"keywords":[{"id":"1fe88de4-a7ed-43f8-ad41-040dede7287f","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"lz200206001","title":"含铌钢板坯连铸二冷目标温度及配水","volume":"","year":"2002"},{"abstractinfo":"从理论上分析了高碳钢方坯连铸中心缩孔产生的原因及降低的途径.通过32炉浇钢试验,得出拉速对中心缩孔的作用大于钢水过热度,同时讨论了强冷段、强冷段水量、二冷段水量等参数对中心缩孔的影响.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">克强</span>","id":"7fc94a3e-325d-4257-82f9-c84821db9003","originalAuthorName":"张克强"},{"authorName":"齐振亚","id":"900d11dc-3a3c-4b65-8ea6-408b78e13a87","originalAuthorName":"齐振亚"},{"authorName":"王长栓","id":"804572a7-2df5-4355-9f0e-987c5533d44a","originalAuthorName":"王长栓"},{"authorName":"王坚","id":"a8fca913-c331-47b9-8492-642674b485db","originalAuthorName":"王坚"},{"authorName":"抗小敏","id":"5a7aa76c-a5f9-48eb-828c-f1a895e0e858","originalAuthorName":"抗小敏"}],"doi":"","fpage":"27","id":"49b8f2cc-6aa1-4ea8-9074-8e295a1da19d","issue":"1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"e6df717a-0308-482d-b33c-52a127c28178","keyword":"中心缩孔","originalKeyword":"中心缩孔"},{"id":"9e34c96b-f6b5-4c93-85f4-eeed94524967","keyword":"高碳钢","originalKeyword":"高碳钢"},{"id":"6f564685-0074-4dd3-98c5-606082d383a9","keyword":"方坯连铸","originalKeyword":"方坯连铸"}],"language":"zh","publisherId":"gt200401007","title":"高碳钢方坯连铸中心缩孔去除","volume":"39","year":"2004"},{"abstractinfo":"连铸坯的二次冷却技术对连铸机的产量及铸坯的质量极为重要.目前最新的连铸二次冷却技术为上位机配水技术,它包括铸坯目标温度确定、上位机与PLC的通讯、上位机理论计算、二冷水量确定等.杭钢转炉厂1号连铸机通过采用二级配水技术,铸坯的内部质量得到明显改善.≥2级的铸坯内部角裂纹由8.3%下降为0,铸坯总内部缺陷是同型号其他连铸机的36.3%;同时由于铸坯表面温度适当下降,铸坯表面氧化铁皮也有明显的减少.上位机从读数据、显示数据、计算水量到写给PLC数据,每6 s循环一次,实现了上位机在线闭环控制二冷水量.","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">克强</span>","id":"ff353d03-8f33-4752-b94b-c4356156d31d","originalAuthorName":"张克强"},{"authorName":"林宪","id":"5cf3d486-c914-4769-8be9-1456f28577cb","originalAuthorName":"林宪"},{"authorName":"高海","id":"7d2b6119-e1ca-4d6c-9c8b-cc45335d8eab","originalAuthorName":"高海"},{"authorName":"林剑平","id":"1f2b3d3e-b09b-4798-8169-71ca16a4f5a0","originalAuthorName":"林剑平"},{"authorName":"吕森强","id":"0706e02b-4903-486e-a954-9c7b722d249e","originalAuthorName":"吕森强"}],"doi":"","fpage":"39","id":"d1ff2757-b77b-491d-a4ce-0a8fba84cd96","issue":"1","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"51b06a5d-5264-40a0-a7a6-d19112cc4a3d","keyword":"二级配水","originalKeyword":"二级配水"},{"id":"f8773e03-ecf5-48d8-8846-fd2095370ac0","keyword":"二次冷却","originalKeyword":"二次冷却"},{"id":"4d6a426a-3519-47df-b5ac-f895c3c752cf","keyword":"铸坯质量","originalKeyword":"铸坯质量"}],"language":"zh","publisherId":"gt200601009","title":"方坯连铸二级配水技术研究","volume":"41","year":"2006"},{"abstractinfo":"本文研究了喷雾水滴与高温物体表面之间的传热。试验测定了锥形喷嘴的冷态特性和水滴与高温表面的传热系数,讨论了影响传热系数因素,并得出了h∝W关系式。","authors":[{"authorName":"<span style=\"color:red\">张</span><span style=\"color:red\">克强</span>","id":"458bed6a-4759-4ba7-a1d2-c709112b5616","originalAuthorName":"张克强"},{"authorName":"袁伟霞","id":"4343db6d-f527-4b5d-88cd-5ff17c0e7582","originalAuthorName":"袁伟霞"},{"authorName":"蔡开科","id":"b4a2f32a-650f-4b28-8659-c92764aef57d","originalAuthorName":"蔡开科"}],"categoryName":"|","doi":"","fpage":"77","id":"baeaf124-2c6b-43a4-b04f-9b563eb0d117","issue":"6","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[],"language":"zh","publisherId":"0412-1961_1985_6_8","title":"喷雾冷却传热研究","volume":"21","year":"1985"},{"abstractinfo":"在对轧制时钢管的温降原因进行分析的基础上,给出一种定<span style=\"color:red\">张</span>减温降计算模型,该模型考虑了辐射、接触传导、内部传导对温度的影响.通过对轧制实验测定得到钢管的温降数据与此模型实例计算的结果进行对比分析,表明该模型比较准确,能够满足生产实际的要求,可用于自动控制系统中定<span style=\"color:red\">张</span>减温降的计算,从而为控制系统比较准确地对轧机进行设定及调整提供依据.","authors":[{"authorName":"付国忠","id":"2df6a851-8f47-4b56-8f72-ddb7bbbcfe8c","originalAuthorName":"付国忠"},{"authorName":"刘建平","id":"7bbce9ac-9a32-45eb-96fd-189eee9a7fcf","originalAuthorName":"刘建平"},{"authorName":"赵晓峰","id":"447ac541-0f77-4dc8-b74d-90d05019a5dc","originalAuthorName":"赵晓峰"},{"authorName":"刘建明","id":"dab886da-88c3-485b-acd8-36bdef7ca181","originalAuthorName":"刘建明"},{"authorName":"吕庆功","id":"ca75c975-aa2d-40d9-a1bc-e6c2a6290dd3","originalAuthorName":"吕庆功"},{"authorName":"彭龙洲","id":"191fb78f-9fa7-4ff8-bd3d-f5d577b2254b","originalAuthorName":"彭龙洲"}],"doi":"","fpage":"51","id":"f9f1b624-57cd-4daa-8c3b-87273c5da7af","issue":"12","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"86dbadc0-1405-4493-8908-e33b69ac127a","keyword":"定<span style=\"color:red\">张</span>减","originalKeyword":"定张减"},{"id":"9e7152eb-09a1-44ea-a2de-6bbe76d243e5","keyword":"温降","originalKeyword":"温降"},{"id":"5b41b920-ede8-4551-8e68-3e12ea48cca0","keyword":"模型","originalKeyword":"模型"}],"language":"zh","publisherId":"gt200412013","title":"定<span style=\"color:red\">张</span>减温降计算模型","volume":"39","year":"2004"},{"abstractinfo":"通过对高压输电用耐<span style=\"color:red\">张</span>线夹及夹持导线的宏观形貌、化学成分、腐蚀产物进行分析,探讨了该线夹腐蚀失效的原因.结果表明:该线夹在压接时即存在铝线断股现象,服役过程中使酸性雨水更易进入到压接管内部,对线夹与钢芯铝绞线结合面进行腐蚀生成腐蚀产物,导致耐<span style=\"color:red\">张</span>线夹电阻增大;随着腐蚀的进行,线夹电阻不断增大,其温度也随之升高;当温度超过临界温度时,热平衡状态被打破,最终线夹过热,导致高温烧损失效;应加强线夹压接管位置的红外测温监控,及时更换温度明显异常的压接管.","authors":[{"authorName":"王若民","id":"67613948-e11f-48e5-825a-945647e34637","originalAuthorName":"王若民"},{"authorName":"詹马骥","id":"c5bfcec7-5a00-4e3d-b8c3-cc8ae36b1c5e","originalAuthorName":"詹马骥"},{"authorName":"季坤","id":"fad04bbc-1535-4f0d-b2d0-e0a6c3cd18b9","originalAuthorName":"季坤"},{"authorName":"严波","id":"5762aad4-1316-4f1b-a398-6bef540edc39","originalAuthorName":"严波"},{"authorName":"王夫成","id":"293d7a45-367c-4e72-b1e8-54671748e326","originalAuthorName":"王夫成"},{"authorName":"杜晓东","id":"34fa50d8-c180-4b94-bef4-334bb0b32a93","originalAuthorName":"杜晓东"}],"doi":"10.11973/jxgccl201703023","fpage":"112","id":"70c96a82-1183-4792-9903-a2d3f429c779","issue":"3","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":"ba9620cc-12e4-4c4a-8ed2-dabf99baee9b","keyword":"耐<span style=\"color:red\">张</span>线夹","originalKeyword":"耐张线夹"},{"id":"e9262adb-ad1f-42ae-a53f-f8cf601c190c","keyword":"腐蚀","originalKeyword":"腐蚀"},{"id":"b1c65b70-8df7-4c01-b691-fbe881df0505","keyword":"热击穿","originalKeyword":"热击穿"},{"id":"08076d01-a062-4829-9d0a-13eb956fbedd","keyword":"钢芯铝绞线","originalKeyword":"钢芯铝绞线"}],"language":"zh","publisherId":"jxgccl201703024","title":"高压输电用耐<span style=\"color:red\">张</span>线夹失效的原因","volume":"41","year":"2017"},{"abstractinfo":"分析了宝钢1420冷轧酸轧机#机架后的测<span style=\"color:red\">张</span>辊在正常轧制中产生的划伤问题,通过对测<span style=\"color:red\">张</span>辊的表面状态、辊径、安装高度以及轴承的改进,彻底解决了因测<span style=\"color:red\">张</span>辊表面划伤而直接导致带钢表面划伤的产品质量问题.","authors":[{"authorName":"陈松","id":"49272655-146f-4cbc-84c1-2b2664d55eec","originalAuthorName":"陈松"},{"authorName":"符寒光","id":"e5d26514-5d18-4a3c-932a-02e08ffd7448","originalAuthorName":"符寒光"}],"doi":"10.3969/j.issn.1001-7208.2002.06.005","fpage":"20","id":"47514943-7c51-4f1e-bf3e-32d27788e620","issue":"6","journal":{"abbrevTitle":"SHJS","coverImgSrc":"journal/img/cover/SHJS.jpg","id":"59","issnPpub":"1001-7208","publisherId":"SHJS","title":"上海金属"},"keywords":[{"id":"31f17eb1-f1ce-4ccd-acfb-7f4cd9f4fa54","keyword":"酸轧机组","originalKeyword":"酸轧机组"},{"id":"684f41a3-ab59-4919-9359-c7c51e7f6b90","keyword":"测<span style=\"color:red\">张</span>辊","originalKeyword":"测张辊"},{"id":"73562d3f-7aac-47e8-aa62-9de0e87ad5f2","keyword":"冷轧带钢","originalKeyword":"冷轧带钢"},{"id":"c4f9713a-3335-4538-99ea-8403d4c12ebc","keyword":"表面划伤","originalKeyword":"表面划伤"}],"language":"zh","publisherId":"shjs200206005","title":"冷轧机组测<span style=\"color:red\">张</span>辊表面划伤的研究","volume":"24","year":"2002"},{"abstractinfo":"对断裂的汽车<span style=\"color:red\">张</span>紧轮紧固螺栓的显微组织、化学成分、硬度以及断口的宏、微观特征进行了综合分析,找出其断裂的原因.结果表明:螺栓在搓丝加工过程中挤压量过大,使螺纹尖端产生较多微裂纹,同时螺纹根部也存在一些加工缺陷,并在之后的热处理过程中进一步扩展;在使用过程中,微裂纹和加工缺陷处产生应力集中,使螺栓材料的疲劳强度降低,裂纹源的过早形成最终导致了螺栓发生疲劳断裂而失效.","authors":[{"authorName":"柴武倩","id":"da907f57-90f8-4c53-98bf-e3369a0b89a6","originalAuthorName":"柴武倩"},{"authorName":"杨强云","id":"a7086465-8523-42b4-9854-22ab6a3fd3f5","originalAuthorName":"杨强云"},{"authorName":"杨川","id":"8009d472-714c-4b40-be98-7d783ceea493","originalAuthorName":"杨川"},{"authorName":"高国庆","id":"7c8ab93c-3dd5-4af0-9a4f-28f1622efa78","originalAuthorName":"高国庆"},{"authorName":"崔国栋","id":"de001797-404a-4cb5-b0ed-e937bc85e3db","originalAuthorName":"崔国栋"}],"doi":"10.11973/jxgccl201509024","fpage":"103","id":"de2ae3fc-935a-4985-bed5-e3dec17b9161","issue":"9","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":"fca7a64f-70c5-4cec-a74e-1e5413ce3901","keyword":"螺栓","originalKeyword":"螺栓"},{"id":"c902c41f-c6f5-41bd-8f37-8de4d8259594","keyword":"微裂纹","originalKeyword":"微裂纹"},{"id":"241ba6c4-95e4-425c-9942-023afc14ff39","keyword":"缺陷","originalKeyword":"缺陷"},{"id":"e4ae4e6c-cab5-4ae1-8863-83cbb54c0a40","keyword":"疲劳断裂","originalKeyword":"疲劳断裂"}],"language":"zh","publisherId":"jxgccl201509024","title":"汽车<span style=\"color:red\">张</span>紧轮紧固螺栓断裂分析","volume":"39","year":"2015"},{"abstractinfo":"在纤维束缠绕时施加<span style=\"color:red\">张</span>紧力,使得固化成型后的飞轮内部形成一定的预加径向压应力,这是提高飞轮径向强度的有效方法之一.基于过盈配合的思想建立了计算<span style=\"color:red\">张</span>紧力缠绕导致的复合材料飞轮内部预应力和变形的简化模型和方法.通过算例分析发现:等张力缠绕产生的环向应力在半径方向上先减小后增大,径向压应力不断变小;变张力缠绕过程中,<span style=\"color:red\">张</span>紧力由小逐渐变大时,飞轮的径向压应力增大,径向强度提高;飞轮设计中仅仅依靠<span style=\"color:red\">张</span>紧力缠绕是不够的,还必须和固化成型后的厚壁筒之间的过盈套装一起来设计合理的径向预加压应力.","authors":[{"authorName":"秦勇","id":"af6d458c-0798-4cb7-b698-30bc691b33b2","originalAuthorName":"秦勇"},{"authorName":"夏源明","id":"d865c7cb-7c8f-411b-9310-aa59550a6a92","originalAuthorName":"夏源明"},{"authorName":"毛天祥","id":"c4d5e1dc-6421-415a-a8b6-0a4021b94fd2","originalAuthorName":"毛天祥"}],"doi":"10.3321/j.issn:1000-3851.2003.06.017","fpage":"87","id":"eb32fe6a-aeec-4ee8-b3b0-8e92fed631d5","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":"031af711-1656-42dd-811e-991de2cf2e4e","keyword":"复合材料飞轮","originalKeyword":"复合材料飞轮"},{"id":"6403bb38-7f8a-4d12-b7e6-f9aed0a53d34","keyword":"<span style=\"color:red\">张</span>紧力","originalKeyword":"张紧力"},{"id":"0033d921-d223-4324-a31c-a6e92e6877f3","keyword":"缠绕","originalKeyword":"缠绕"},{"id":"8637c0b3-6bd5-4b44-b015-77a5767c5d67","keyword":"过盈配合","originalKeyword":"过盈配合"},{"id":"b45ae1b8-9b85-4461-a291-11130105d070","keyword":"径向强度","originalKeyword":"径向强度"}],"language":"zh","publisherId":"fhclxb200306017","title":"纤维束<span style=\"color:red\">张</span>紧力缠绕复合材料飞轮的预应力简化分析","volume":"20","year":"2003"},{"abstractinfo":"张力调节是板带材生产工艺中的重要环节,为研究平整分卷线上三辊张力装置的增<span style=\"color:red\">张</span>机理和张力调节能力,采用弹塑性有限元方法对其工作过程进行数值模拟,得到了板厚、开卷张力、上张力辊压下量和设备结构参数等对张力装置增<span style=\"color:red\">张</span>能力的影响规律.将有限元模拟结果作为训练样本,结合国内某厂实测数据,建立了三辊张力装置增<span style=\"color:red\">张</span>能力的BP神经网络预测模型,预测结果与实测数据吻合良好,实现了张力调节定量控制.","authors":[{"authorName":"许石民","id":"19e1b82c-4fb6-4fd7-8331-6191035f5653","originalAuthorName":"许石民"},{"authorName":"黄华贵","id":"9caf8b77-a208-4058-811a-55c09c17ea8b","originalAuthorName":"黄华贵"},{"authorName":"臧新良","id":"f27b3a90-b44f-444f-a15f-b9548f313b35","originalAuthorName":"臧新良"},{"authorName":"杜凤山","id":"13c0be46-6277-429c-a9a0-3e88b5f4bb77","originalAuthorName":"杜凤山"},{"authorName":"蒋松","id":"27d54d06-1b96-48bc-aa98-a6fd0f62a7d0","originalAuthorName":"蒋松"}],"doi":"","fpage":"53","id":"bed55c6f-19c7-413c-a960-483a2717939f","issue":"7","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"036314ce-264a-4b1d-8bd8-13ec3d331321","keyword":"三辊张力装置","originalKeyword":"三辊张力装置"},{"id":"958ed6cf-48d1-423c-b216-5f64ae18d82d","keyword":"张力调节","originalKeyword":"张力调节"},{"id":"99b3c291-7530-497d-9973-80a0ab2f0386","keyword":"弹塑性有限元法","originalKeyword":"弹塑性有限元法"},{"id":"6c721ec7-205f-430e-9361-01a8cbcc4a89","keyword":"BP神经网络","originalKeyword":"BP神经网络"}],"language":"zh","publisherId":"gt200907014","title":"三辊张力装置增<span style=\"color:red\">张</span>能力的数值模拟分析","volume":"44","year":"2009"}],"totalpage":21,"totalrecord":209}