Applications of thermal plasma flow, energy and particle nucleation fields control in the materials and energy sectors

热等离子体流、能量和粒子成核场控制在材料和能源领域的应用

• 批准号: RGPIN-2018-04425
• 负责人: Meunier, JeanLuc
• 金额: $ 2.84万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=712593
• 关键词: Applications; thermal; plasma; flow; energy

This research program is on the development of technologies based on "thermal plasmas" consisting of ionized gases at extreme temperatures reaching 10,000 C and close to atmospheric pressure. Thermal plasma devices are used and modeled in the present program for generating carbon-based nano-structures such as graphene nanoflakes (GNF). The GNF are in the shape of 2-dimensional sheet-like materials having a small number of atomic layers, these being generated in our reactors from the atomic level through particle nucleation occurring between 4,400 C and 5,200 C. A particular emphasis of the research program is in the development of control strategies within the synthesis reactors that will enable three specific areas of applications opening new opportunities in the energy sector, the environment, and advanced materials. Thermal plasma reactor design are studied in terms of the plasma flow and temperature fields, as well as particle nucleation mapping occurring within the reactor and the chemical species being generated. A particular focus is made on the control of the plasma flow expansion. This control provides, as a 1st application, the possibility to use the "active" chemical species generated in the plasma to add chemical functionalities on powders and surfaces while maintaining the surfaces relatively cold and at atmospheric pressure. Examples of this 1st application would be to make fully wettable (hydrophillic) or fully non-wettable (hydrophobic) surfaces (wood or particles for example) at rapid industrial scales. A 2nd application of the flow control is in the energy and environment sector, focusing particularly on the 292 northern Canadian communities using diesel-based electrical power independent from the electrical distribution grid system. These power generators produce a large amount of greenhouse gases (GHG) but also an important loss of electrical energy due to their poor on/off capabilities for adjusting to the energy demand. The plasma systems developed uses a GHG (methane) for generating the carbon-based particles, and hydrogen as a by-product. Hydrogen can thus act as a means of storage of the excess electrical energy generated, and then further used to provide electricity through fuel cell based systems. This program targets the design of a plasma reactor that will optimize hydrogen production while maintaining the high added value carbon powder production, and eliminating a GHG. A 3rd application of the plasma flow control relates to plasma spraying applications for producing advanced coatings particularly for the aeronautics sector. A constant problem in plasma spraying is controlling the thermal history of the particles injected in the very turbulent plasma flow. We apply here our control strategies based on plasma expansion to generate more uniform flow patterns and increase the efficiency of plasma spraying processes.

这项研究计划是关于开发基于“热等离子体”的技术，该技术由极端温度达到10，000摄氏度和接近大气压的电离气体组成。热等离子体装置在本程序中用于生成碳基纳米结构，如石墨烯纳米片（GNF）。GNF是具有少量原子层的二维片状材料的形状，这些原子层是在我们的反应堆中通过在4，400 C和5，200 C之间发生的粒子成核从原子水平产生的。该研究计划的一个特别重点是在合成反应器内的控制策略的开发，这将使三个特定的应用领域在能源部门，环境和先进材料中开辟新的机会。 热等离子体反应器的设计进行了研究，在等离子体流场和温度场，以及粒子成核映射发生在反应器和生成的化学物种。一个特别的重点是对等离子体流膨胀的控制。作为第一种应用，这种控制提供了使用等离子体中产生的“活性”化学物质来在粉末和表面上添加化学功能的可能性，同时保持表面相对较冷并处于大气压下。这种第一种应用的例子是以快速工业规模制造完全亲水（亲水）或完全非亲水（疏水）表面（例如木材或颗粒）。 流量控制的第二个应用是在能源和环境部门，特别侧重于加拿大北方292个社区，这些社区使用独立于配电网系统的柴油电力。这些发电机产生大量的温室气体（GHG），但由于它们用于调节能量需求的开/关能力差，也产生重要的电能损失。开发的等离子体系统使用GHG（甲烷）来产生碳基颗粒，并使用氢作为副产品。因此，氢可以作为储存所产生的过量电能的手段，然后进一步用于通过基于燃料电池的系统提供电力。该计划的目标是设计一个等离子体反应器，该反应器将优化氢气生产，同时保持高附加值的碳粉生产，并消除温室气体。 等离子体流控制的第三应用涉及用于生产先进涂层的等离子体喷涂应用，特别是用于航空领域。等离子喷涂中的一个常见问题是控制在非常湍流的等离子体流中注入的颗粒的热历史。我们在这里应用我们的控制策略的基础上等离子体膨胀，以产生更均匀的流动模式，提高等离子喷涂工艺的效率。