A novel membrane reactor for catalyst activity control

一种用于催化剂活性控制的新型膜反应器

• 批准号: EP/E033687/1
• 负责人: Ian Metcalfe
• 金额: $ 39.98万
• 依托单位: Newcastle University
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2007
• 资助国家: 英国
• 起止时间: 2007 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=EP%2FE033687%2F1
• 关键词: novel; membrane; reactor; catalyst; activity

The UK's 21st century chemical industry needs to continue to innovate to deliver more efficient, environmentally friendlier and increasingly intensified chemical processes. Many such processes are catalytic in nature. Indeed globally catalysis is playing an increasingly vital role in the innovation of new green chemistry and sustainable production. To maintain its competitive advantage, the UK chemical industry needs new methods for developing catalysts that enhance innovation and reduce cycle times. However, once a catalyst is loaded into a reactor there is little that can be done to control or optimise its performance by external means. Imagine a way of operating catalytic reactors in which the performance of the catalyst could be dramatically modified in a controllable way by external means. Catalyst activity could be optimised and catalyst selectivity could be manipulated in such a way as to 'switch off' unwanted side reactions. Such technology would produce a step change in the global presence of the UK chemical's sector.This work is motivated by the need to supply high catalyst surface areas to catalytic systems undergoing catalytic control through electrochemical promotion. System fabrication must be low cost and construction simple. In particular this proposal intends to build upon recent advances in the understanding of electrochemical promotion and recent advances in the fabrication of controlled-microstructure mixed conducing membranes. For the first time we will be able to electrochemically promote and control the catalytic activity of a highly-dispersed metal catalyst (all previous applications have used low surface area continuous metal electrodes).Recent EC FP6 proposals from the key players in Europe have failed to identify a technically feasible alternative to low catalyst surface areas in systems designed to exploit electrochemical promotion. However, the experimental work and theoretical insights developed in Professor Metcalfe's group are here used to suggest appropriate materials for the electrochemical promotion of a highly dispersed catalyst as well as an operating strategy for catalyst control. The membrane technology required has begun to be developed through EPSRC grants GR/S12197/01 and GR/S12203/01 with Dr K Li of Imperial College.We have begun to seek appropriate protection for the intellectual property associated with the reactor fabrication and the operating strategy and for this reason we ask that this proposal be treated as confidential.

英国21世纪的化学工业需要继续创新，以提供更高效、更环保和日益强化的化学过程。许多这样的过程本质上是催化的。事实上，在全球范围内，催化在新型绿色化学和可持续生产的创新中发挥着越来越重要的作用。为了保持其竞争优势，英国化学工业需要新的方法来开发催化剂，以加强创新和减少循环时间。然而，一旦催化剂被装载到反应器中，就很难通过外部手段来控制或优化其性能。想象一种操作催化反应器的方法，在这种方法中，催化剂的性能可以通过外部手段以可控的方式被显著地改变。催化剂活性可以优化，催化剂选择性可以通过这样的方式来“关闭”不需要的副反应。这种技术将使英国化工行业的全球地位发生重大变化。这项工作的动机是需要提供高催化剂表面积的催化系统进行催化控制，通过电化学促进。系统制造必须成本低，施工简单。特别地，本提案旨在建立在电化学促进的最新进展和控制微观结构混合导电膜的制造的最新进展。这是我们第一次能够电化学地促进和控制高度分散的金属催化剂的催化活性（所有以前的应用都使用低表面积连续金属电极）。欧洲主要参与者最近提出的EC FP6提案未能确定技术上可行的替代方案，以利用电化学促进系统的低催化剂表面积。然而，Metcalfe教授小组的实验工作和理论见解在这里被用来为高度分散催化剂的电化学促进提供合适的材料，以及催化剂控制的操作策略。所需的膜技术已经开始通过EPSRC拨款GR/S12197/01和GR/S12203/01与帝国理工学院的李国强博士开发。我们已经开始为与反应堆制造和运行策略相关的知识产权寻求适当的保护，因此，我们要求将这一建议视为机密。

项目成果

Development and testing of an intermediate temperature glass sealant for use in mixed ionic and electronic conducting membrane reactors

用于混合离子和电子导电膜反应器的中温玻璃密封剂的开发和测试

• DOI: 10.1016/j.ssi.2010.03.031
• 发表时间: 2010
• 期刊: Solid State Ionics
• 影响因子: 3.2
• 作者: Hatcher J