Hostname: page-component-78c5997874-xbtfd Total loading time: 0 Render date: 2024-11-16T18:25:34.615Z Has data issue: false hasContentIssue false

Radiometric flow in periodically patterned channels: fluid physics and improved configurations

Published online by Cambridge University Press:  07 December 2018

Ali Lotfian
Affiliation:
High Performance Computing (HPC) Laboratory, Department of Mechanical Engineering, Ferdowsi University of Mashhad, 91775-1111, Mashhad, Iran
Ehsan Roohi*
Affiliation:
High Performance Computing (HPC) Laboratory, Department of Mechanical Engineering, Ferdowsi University of Mashhad, 91775-1111, Mashhad, Iran
*
Email address for correspondence: [email protected]

Abstract

With the aid of direct simulation Monte Carlo (DSMC), we conduct a detailed investigation pertaining to the fluid and thermal characteristics of rarefied gas flow with regard to various arrangements for radiometric pumps featuring vane and ratchet structures. For the same, we consider three categories of radiometric pumps consisting of channels with their bottom or top surfaces periodically patterned with different structures. The structures in the design of the first category are assumed to be on the bottom wall and consist of either a simple vane, a right-angled triangular fin or an isosceles triangular fin. The arrangements on the second category of radiometric pumps consist of an alternating diffuse–specular right-angled fin and an alternating diffuse–specular isosceles fin on the bottom wall. The third category contains either a channel with double isosceles triangular fins on its lowermost surface or a zigzag channel with double isosceles triangular fins on both walls. In the first and the third categories, the surfaces of the channel and its structures are considered as diffuse reflectors. The temperature is kept steady on the horizontal walls of the channel; thus, radiometric flow is created by subjecting the adjacent sides of the vane/ratchet to constant but unequal temperatures. On the other hand, for the second category, radiometric flow is introduced by specifying different top/bottom channel wall temperatures. The DSMC simulations are performed at a Knudsen number based on the vane/ratchet height of approximately one. The dominant mechanism in the radiometric force production is clarified for the examined configurations. Our results demonstrate that, at the investigated Knudsen number, the zigzag channel experiences maximum induced velocity with a parabolic velocity profile, whereas its net radiometric force vanishes. In the case of all other configurations, the flow pattern resembles a Couette flow in the open section of the channel situated above the vane/ratchet. To further enhance the simulations, the predictions of the finite volume discretization of the Boltzmann Bhatnagar–Gross–Krook (BGK)–Shakhov equation for the mass flux dependence on temperature difference and Knudsen number are also reported for typical test cases.

Type
JFM Papers
Copyright
© 2018 Cambridge University Press 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Akhlaghi, H., Roohi, E. & Stefanov, S. 2018 On the consequences of successively repeated collisions in no-time-counter collision scheme in DSMC. Comput. Fluids 161, 2332.Google Scholar
Aoki, K., Degond, P. & Mieussens, L. 2009 Numerical simulations of rarefied gases in curved channels: thermal creep, circulating flow, and pumping effect. Commun. Comput. Phys. 6 (5), 919954.Google Scholar
Aoki, K., Sone, Y., Takata, S., Takahashi, K. & Bird, G. 2001 One-way flow of a rarefied gas induced in a circular pipe with a periodic temperature distribution. In Rarefied Gas Dynamics: 22nd International Symposium (ed. Bartel, T. J. & Gallis, M. A.), pp. 940947. AIP, Melville.Google Scholar
Baier, T., Hardt, S., Shahabi, V. & Roohi, E. 2017 Knudsen pump inspired by Crookes radiometer with a specular wall. Phys. Rev. Fluids 2 (3), 033401.Google Scholar
Bond, D., Wheatley, V. & Goldsworthy, M. 2016 Numerical investigation into the performance of alternative Knudsen pump designs. Intl J. Heat Mass Transfer 93, 10381058.Google Scholar
Chen, J., Stefanov, S. K., Baldas, L. & Colin, S. 2016 Analysis of flow induced by temperature fields in ratchet-like microchannels by Direct Simulation Monte Carlo. Intl J. Heat Mass Transfer 99, 672680.Google Scholar
Cornella, B. M., Ketsdever, A. D., Gimelshein, N. E. & Gimelshein, S. F. 2012 Analysis of multivane radiometer arrays in high-altitude propulsion. J. Propul. Power 28 (4), 831839.Google Scholar
Crookes, W. 1874 XV. On attraction and repulsion resulting from radiation. Phil. Trans. R. Soc. Lond. A 164, 501527.Google Scholar
Donkov, A. A., Tiwari, S., Liang, T., Hardt, S., Klar, A. & Ye, W. 2011 Momentum and mass fluxes in a gas confined between periodically structured surfaces at different temperatures. Phys. Rev. E 84 (1), 016304.Google Scholar
Gimelshein, N., Gimelshein, S., Ketsdever, A. & Selden, N. 2011a Impact of vane size and separation on radiometric forces for microactuation. J. Appl. Phys. 109 (7), 074506.Google Scholar
Gimelshein, N. E., Gimelshein, S. F., Ketsdever, A. D. & Selden, N. P. 2011b Shear force in radiometric flows. In Rarefied Gas Dynamics: 27th International Symposium (ed. Levin, D. A., Wysong, I. J. & Garcia, A. L.), AIP Conference Proceedings, vol. 1333, pp. 661666.Google Scholar
Guo, Z., Wang, R. & Xu, K. 2015 Discrete unified gas kinetic scheme for all Knudsen number flows. II. Thermal compressible case. Phys. Rev. E 91 (3), 033313.Google Scholar
Ketsdever, A., Gimelshein, N., Gimelshein, S. & Selden, N. 2012 Radiometric phenomena: from the 19th to the 21st century. Vacuum 86 (11), 16441662.Google Scholar
Nallapu, R. T., Tallapragada, A. & Thangavelautham, J.2017 Radiometric actuators for spacecraft attitude control. arXiv:1701.07545.Google Scholar
Ohwada, T., Sone, Y. & Aoki, K. 1989 Numerical analysis of the Poiseuille and thermal transpiration flows between two parallel plates on the basis of the Boltzmann equation for hard-sphere molecules. Phys. Fluids A 1 (12), 20422049.Google Scholar
Palharini, R. C., White, C., Scanlon, T. J., Brown, R. E., Borg, M. K. & Reese, J. M. 2015 Benchmark numerical simulations of rarefied non-reacting gas flows using an open-source DSMC code. Comput. Fluids 120, 140157.Google Scholar
Roohi, E. & Stefanov, S. 2016 Collision partner selection schemes in DSMC: From micro/nano flows to hypersonic flows. Phys. Rep. 656, 138.Google Scholar
Roohi, E., Stefanov, S., Shoja-Sani, A. & Ejraei, H. 2018 A generalized form of the Bernoulli Trial collision scheme in DSMC: derivation and evaluation. J. Comput. Phys. 354, 476492.Google Scholar
Scanlon, T., Roohi, E., White, C., Darbandi, M. & Reese, J. 2010 An open source, parallel DSMC code for rarefied gas flows in arbitrary geometries. Comput. Fluids 39 (10), 20782089.Google Scholar
Selden, N., Ngalande, C., Gimelshein, N., Gimelshein, S. & Ketsdever, A. 2009 Origins of radiometric forces on a circular vane with a temperature gradient. J. Fluid Mech. 634, 419431.Google Scholar
Shahabi, V., Baier, T., Roohi, E. & Hardt, S. 2017 Thermally induced gas flows in ratchet channels with diffuse and specular boundaries. Sci. Rep. 7, 41412.Google Scholar
Stefanov, S. K. 2011 On DSMC calculations of rarefied gas flows with small number of particles in cells. SIAM J. Sci. Comput. 33 (2), 677702.Google Scholar
Strongrich, A., Pikus, A., Sebastião, I. B. & Alexeenko, A. 2017 Microscale in-plane knudsen radiometric actuator: design, characterization, and performance modeling. J. Microelectromech. Syst. 26 (3), 528538.Google Scholar
Su, C., Tseng, K., Cave, H., Wu, J., Lian, Y., Kuo, T. & Jermy, M. 2010 Implementation of a transient adaptive sub-cell module for the parallel-DSMC code using unstructured grids. Comput. Fluids 39 (7), 11361145.Google Scholar
Taguchi, S. & Aoki, K. 2012 Rarefied gas flow around a sharp edge induced by a temperature field. J. Fluid Mech. 694, 191224.Google Scholar
Taguchi, S. & Aoki, K. 2015 Motion of an array of plates in a rarefied gas caused by radiometric force. Phys. Rev. E 91 (6), 063007.Google Scholar
Takata, S. & Funagane, H. 2013 Singular behaviour of a rarefied gas on a planar boundary. J. Fluid Mech. 717, 3047.Google Scholar
Vargo, S., Muntz, E., Shiflett, G. & Tang, W. 1999 Knudsen compressor as a micro-and macroscale vacuum pump without moving parts or fluids. J. Vac. Sci. Technol. A 17 (4), 23082313.Google Scholar
White, C., Borg, M., Scanlon, T., Longshaw, S., John, B., Emerson, D. & Reese, J. 2018 dsmcFoam+: an OpenFOAM based direct simulation Monte Carlo solver. Comput. Phys. Commun. 224, 2243.Google Scholar
White, C., Borg, M. K., Scanlon, T. J. & Reese, J. M. 2013 A DSMC investigation of gas flows in micro-channels with bends. Comput. Fluids 71, 261271.Google Scholar
Zhu, L., Chen, S. & Guo, Z. 2017 dugksFoam: an open source OpenFOAM solver for the Boltzmann model equation. Comput. Phys. Commun. 213, 155164.Google Scholar
Zhu, L. & Guo, Z. 2017a Application of discrete unified gas kinetic scheme to thermally induced nonequilibrium flows. Comput. Fluids (in press).Google Scholar
Zhu, L. & Guo, Z. 2017b Numerical study of nonequilibrium gas flow in a microchannel with a ratchet surface. Phys. Rev. E 95 (2), 023113.Google Scholar