静电胶体微推进器毛细管发射器工作模式的数学与实验模拟

Q3 Energy

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Pub Date : 2024-06-05 DOI:10.21122/1029-7448-2024-67-3-193-208

S. V. Redko, E. Chubenko, V. P. Bondarenko, I. Nikiforov, M. Krakov

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引用次数: 0

摘要

这项工作从实验和理论上分析了以离子液体为工作流体的毛细管发射器发射离子的动力学过程。这种发射器可用于低质量卫星的能源系统，作为喷气推进源。通过实验研究了微型发动机的推力与供电功率的关系，从而确定了微型推进器最有效的工作模式。这对于在低质量卫星电力供应有限的条件下提高后者的能源效率很有意义。研究发现，"电场电压-发射器推力 "特征是非单调的，有一个明显的最大值，这对发射器中电场的大小造成了限制。为了解释发射强度的限制，我们构建了毛细管内离子移动的扩散-对流模型。该模型的主要思想是假定离子发射强度由其在毛细管出口处的浓度决定，且发射离子的速度高于作为连续介质的离子液体在毛细管中的流速。此外，离子在发射器出口处的加速度随外力的增加而非线性增加。离子在发射时浓度的降低必须通过其在毛细管内的扩散和对流来补偿，而对流的速度是有限的。对所构建的方程组进行了数值分析。对于纳维-斯托克斯方程组，采用了 Chorin 提出的投影法。根据已知的速度场、密度和浓度分布，对运动方程采取时间步长。然后，考虑到已发现的速度，对流扩散方程采取一个时间步长，并重新计算密度场。所创建的代码证实了离子最大质量流量（即微电机推力）存在的可能性，这与实验数据在质量上是一致的。最大值的大小及其位置主要取决于毛细管出口处离子加速度系数的非线性程度。

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Mathematical and Experimental Simulation of Operating Modes of Capillary Emitter of Electrostatic Colloidal Microthruster

This work experimentally and theoretically analyzes the dynamics of the process of ion emission from a capillary emitter filled with an ionic liquid as a working fluid. Such emitters can be used in the energy system of low-mass satellites as a source of jet propulsion. The dependence of the thrust of a micromotor on the electrical power supplied to it was experimentally studied, which made it possible to determine the most efficient operating modes of the microthruster. This is of interest from the point of view of increasing the energy efficiency of the latter in conditions of limited power availability of low-mass satellites. It was found that the characteristic “electric field voltage – emitter thrust” is non-monotonic with a pronounced maximum, which imposes restrictions on the magnitude of the electric field in the emitter. To explain the limit of emission intensity, a diffusion-convective model of ion movement inside the capillary was constructed. The main idea of the proposed model is the assumption that the intensity of ion emission is determined by their concentration at the outlet of the capillary, and the velocity of the emitted ions is higher than the velocity of flow of the ionic liquid in the capillary as a continuous medium. Moreover, the acceleration of ions at the outlet of the emitter increases nonlinearly with increasing external forces. The decrease in the concentration of ions as they are emitted must be compensated by their diffusion inside the capillary and convective flows, the velocity of which is limited. The constructed system of equations is analyzed numerically. For the system of Navier – Stokes equations, the projection method proposed by Chorin is applied. Based on the known velocity field, density, and concentration distribution, a time step is taken for the equations of motion. Then, taking into account the found velocity, a time step is taken for the convective diffusion equations and the density field is recalculated. The created code made it possible to confirm the possibility of the existence of a maximum mass flow rate of ions, i.e., micromotor thrust, which is in qualitative agreement with the experimental data. The main factor on which the magnitude of the maximum and its position depend is the degree of nonlinearity of the coefficient responsible for the acceleration of ions at the outlet of the capillary.

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来源期刊

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Energy-Nuclear Energy and Engineering

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The most important objectives of the journal are the generalization of scientific and practical achievements in the field of power engineering, increase scientific and practical skills as researchers and industry representatives. Scientific concept publications include the publication of a modern national and international research and achievements in areas such as general energetic, electricity, thermal energy, construction, environmental issues energy, energy economy, etc. The journal publishes the results of basic research and the advanced achievements of practices aimed at improving the efficiency of the functioning of the energy sector, reduction of losses in electricity and heat networks, improving the reliability of electrical protection systems, the stability of the energetic complex, literature reviews on a wide range of energy issues.