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进入21世纪,随着科学技术的飞速发展,电子计算机应用已经渗透到各学科的每一个领域之中,各学科的进一步发展对计算机的依赖程度越来越高,化学工程学科也不例外。目前,计算机已经深入应用到化工模拟、计算化学和化工制图等化学工程学科的各个层面之中,对化学工程的发展起着巨大的促进推动作用。化学工作者应该抓住机遇,在新时期努力学习计算机知识、熟练掌握计算机工具,将其应用到化工设计、化学计算中去,使化工学科能够更快更高地发展。 相似文献
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第八届全国化学工程论文报告会暨第三届全国青年化学工程学术研讨会于1996年10月21日~24日在天津大学召开.从1963年在上海举行的第一届校际化学工程论文报告会至今的30余年中,我国的化学工程学科得到了长足的发展,成为在国民经济建设中发挥巨大作用的学科.本届会议论文反映了我国化学工程中化工热力学、化工流体力学与传热、传质与分离工程、化学反应工程、计算机在化工中的应用及过程系统工程、生物化学工程、环境化学工程等学科的最新研究成果.起到推动学术交流和扩大影响的重要作用. 相似文献
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化学工程是一门工程学科,它主要研究化学工业以及与化学有关的的产业的生产过程中所进行的物理、化学过程的规律。化学工程领域十分的广泛,包括有机无机化工、石油化工、煤化工以及冶金、环境化工等。这些属于化工领域的行业都是我国国民经济发展的重要领域,对我国的经济发展产生重大作用。随着科技的发展化学工程技术也有了很大的发展向着自动化、高效化的方向发展。本文就将探讨一下化学工程技术的发展历史,以及新时代的发展趋势,并且为促进化学工程技术更好地发展提出一些建议。 相似文献
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《化学工程》2021,49(7)
正为解决化工问题展开的数学建模活动,以及在化工人才培养中展开的数学教学改革探索,都指向化学与数学的跨领域融合,即"化工数学"。通过对概念的解读,不难发现化工数学属于"专门用途数学"范畴,它是一门基于数学思维、方法、工具去解决化工设计、工艺、生产等问题的学科,在知识构成、应用实践与价值体系上均具有一定独立性。事实上,数学在化学工程领域的应用早已存在、十分普遍,但传统应用模式下重点突出数学的工具价值,如公式推导、统计分析、剂量计算等,并没有深入渗透到化学工程的反应原理、工艺设计、过程系统等方面。随着计算机科学、仿真软件、模拟系统的持续进步,为面向化学问题的数学建模提供了有利条件,因此,以高度模块化思维解决化工问题成为化工数学的重要价值体现,也引起了化工专 相似文献
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动态模拟技术与化学工程 总被引:10,自引:1,他引:9
介绍了化工过程动态模拟技术及相应软件的发展与应用状况 ,总结了动态模拟技术的最新进展。指出动态模拟技术应当与动态优化技术相结合 ,动态计算机网络管理将实现石油化工过程的连续实时优化 ,动态模拟技术将向工艺流程和生产方案的合成、能量系统集成、结合生态工业园区实例进行动态流程模拟等方向发展 相似文献
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Andreas Lübbert 《化学,工程师,技术》1984,56(10):744-752
Use of computers in chemical engineering. It is shown by various examples from three directions of development how modern microelectronics, especially microcomputer technology, can be used effectively in chemical engineering applications. These are applications of microprocessors in complicated measuring tasks, the distribution of computing power in computer networks and the use of specialized processors. 相似文献
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S. S. Grover 《Catalysis Reviews》2013,55(1):153-164
During the last decade digital computers have had a tremendous impact on the computational aspects of the various disciplines of physical sciences and engineering. In the field of catalysis and chemical kinetics computers have proved to be a valuable tool in both research and engineering applications. In most chemical reacting systems the number of reactions proceeding simultaneously is large. Manual calculations for such systems become cumbersome when more than three or four reactions are involved. Usually these reactions are accompanied by thermal effects, and often diffusional and hydrodynamical flow considerations are important [1–3]. The free radical reactions invariably include many simultaneous reactions, and the computer becomes a logical tool for such applications [4]. Another area of computer applications is the optimum design of chemical reactors where the elaborate mathematical optimization procedures are superimposed on the already complex chemical reaction system [5]. 相似文献
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S. S. Grover 《Catalysis Reviews》1968,1(1):153-164
During the last decade digital computers have had a tremendous impact on the computational aspects of the various disciplines of physical sciences and engineering. In the field of catalysis and chemical kinetics computers have proved to be a valuable tool in both research and engineering applications. In most chemical reacting systems the number of reactions proceeding simultaneously is large. Manual calculations for such systems become cumbersome when more than three or four reactions are involved. Usually these reactions are accompanied by thermal effects, and often diffusional and hydrodynamical flow considerations are important [1-3]. The free radical reactions invariably include many simultaneous reactions, and the computer becomes a logical tool for such applications [4]. Another area of computer applications is the optimum design of chemical reactors where the elaborate mathematical optimization procedures are superimposed on the already complex chemical reaction system [5]. 相似文献
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Heinrich Nassenstein 《化学,工程师,技术》1981,53(8):631-637
Interface research and chemical engineering . This paper describes some advances in interface research and their importance for chemical engineering. In particular, new methods, new findings, and their applications are described in the fields: solid interfaces, fluid interfaces, and disperse systems. The report is based substantially on results obtained by the committee “Grenzflächen” of the GVC (VDI-Gesellschaft Verfahrenstechnik und Chemie-Ingenieurwesen). 相似文献
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紧跟学科发展步伐,改革化学化工类专业开设的《计算机在化学化工中的应用》课程体系,调整教学内容,更新教学方法,强化化学化工专业学生计算机实际应用能力的培养,满足化学化工专业的发展和社会对新一代化工人才的需求。 相似文献
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化工计算机应用课程教材编写心得 总被引:2,自引:1,他引:1
化学化工专业需要利用计算机解决许多问题,在该专业的本科生中开设化学化工计算机应用课程已是新世纪的基本要求,而有一本适合实际的好教材是学好该课程的基础。文章就化学化工计算机应用课程教材《计算机在化学化工中的应用》第一版和第二版编写过程中关于课程定位、教材内容、编写风格等问题的一些心得进行了讨论和阐述,并提出了教材进一步完善的思路和方向。 相似文献
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Additive manufacturing describes technologies that translate virtual computer‐aided design data into physical models in a fast process. While industries such as automotive and aerospace adopt this manufacturing technique rapidly, it is little applied within process engineering. Additive manufacturing offers freedom of design which gives access to novel shapes and geometries with fast production times. This review analyses the most important layer fabrication principles first and shows applications of additive manufacturing in fluid process engineering second. The review focuses on applications where liquids and gases are involved and it showcases the potential of additive manufacturing within process engineering of functional devices. Examples of current research projects show the potential of the technology for advances process engineering. 相似文献