Abstract
One of the important design criteria of micropropulsion systems in particular VLM is the type of microheater, its layout and placement with a view to achieve uniform heating of propellant, fast heat transfer efficiency with minimum input power. Thrust produced by microthruster not only depends on the structural geometry of the thruster and propellant flow rate, but also on the chamber temperature to produce super saturated dry stream at the exit nozzle. Detailed design of microheater in thermal and electrical domains using co-solvers available in MEMS software tools along with material’s thermal property, temperature dependence of electrical resistivity and thermal conductivity have been considered in the present work to achieve precise modeling and experimental accuracy of heater operation. The chamber temperature was analytically calculated and subsequently the required resistance and power were estimated. The boron diffused microheaters of meanderline configuration in silicon substrate has been designed and its finite element based electro-thermal modeling was employed to predict the heater characteristics. The variation of microheater temperature with time, applied voltage and along chamber length has been determined from the modeling. Subsequently the designed microheater was realized on silicon wafer by lithography and boron diffusion process and its detailed testing was evaluated. It was found that boron diffused resistor of 820 Ω can generate 405 K temperature with applied input power 2.4 W. Finally the simulated results were validated by experimental data.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baroncini M, Placidi P, Cardinali GC, Scorzoni A (2004) Thermal characterization of a microheater for micromachined gas sensors. Sens Actuators A 115:8–14
Briand D, Krauss A, Van der Schoot B, Weimar U, Barsan N, Göpel W, De Rooij NF (2000) Design and fabrication of high-temperature micro-hotplates for drop-coated gas sensors. Sens Actuators B 68:223–233
Fung SKH, Tang Z, Chan PCH, Sin JKO, Cheung PW (1996) Thermal analysis and design of a micro-hotplate for integrated gas-sensor applications. Sen Actuators A 54:482–487
Gajda MA, Ahmed H (1995) Applications of thermal silicon sensors on membranes. Sens Actuators A 49:1–9
Glod S, Poulikakos D, Zhao Z, Yadigaroglu G (2002) An investigation of microscale explosive vaporization of water on an ultra-thin Pt wire. Int J Heat Mass Transf 45:367–379
Iida Y, Okuyama K (1994) Boiling nucleation on a very small film heater subjected to extremely rapid heating. Int J Heat Mass Transf 37:2771–2780
Kundu P, Bhattacharyya TK, Das S (2012) Design, fabrication and performance evaluation of a vaporizing liquid microthruster. J Micromech Microeng 22:25001–25016
Lewis D, Janson S, Cohen R, Antonsson E (2000) Digital micropropulsion. Sens Actuators A 80:143–154
Lien KY, Lee SH, Tsai TJ (2009) A microfluidic-based system using reverse transcription polymerase chain reactions for rapid detection of aquaculture diseases. Microfluid Nanofluid 7:795–806
Maurya DK, Das S, Lahiri SK (2005a) Silicon MEMS vaporizing liquid microthruster with internal microheater. J Micromech Microeng 15:966–970
Maurya DK, Das S, Lahiri SK (2005b) An analytical model of a silicon MEMS vaporizing liquid microthruster and some experimental studies. Sens Actuators A 122:159–166
Mueller J, Tang W C, Wallace AP, Li W, Bame D, Chakraborty I, Lawton R (1997) Design analysis and fabrication of a vaporizing liquid microthruster, AIAA 97–3054:33rd Joint Propulsion Conf. (Seattle, WA)
Mukerjee EV, Wallace AP, Yan KY, Howard DW, Smith RL, Collins SD (2000) Vaporizing liquid microthruster. Sens Actuators A 83:231–236
Puigcorbe J, Vogel D, Michel B, Vila A, Gracia I, Cane C, Morante JR (2003) Thermal and mechanical analysis of micromachined gas sensors. J Micromech Microeng 13:548–556
Robert LB, Kenneth SB (2001) Analysis and testing of a silicon intrinsic-point heater in a micropropulsion application. Sens Actuators A 91:249–255
Rossi C, Scheid E, Esteve D (1997) Theoretical and experimental study of silicon micromachined microheater with dielectric stacked membranes. Sens Actuators A 63:183–189
Wang YH, Lee CY, Chiang CM (2007) A MEMS-based air flow sensor with a free-standing micro cantilever structure. Sensors 7:2389–2401
Wang YH, Chen CP, Chang CM, Lin CP, Lin CH, Fu LM, Lee CY (2009) MEMS-based gas flow sensors. Microfluid Nanofluid 6:333–346
Xua Y, Chiub CW, Jiangb F, Linc Q, Taid YC (2005) A MEMS multi-sensor chip for gas flow sensing. Sens Actuators A 121:253–261
Ye XY, Tang F, Ding HQ, Zhou ZY (2001) Study of a vaporizing water microthruster. Sens Actuators A 89:159–165
Zhang KL, Chou SK, Ang SS, Tang XS (2005) A MEMS-based solid propellant microthruster with Au/Ti microheater. Sens Actuators A 122:113–123
Acknowledgments
The work presented here is supported by Indian Space Research Organization, Govt. of India. The authors would like to express their gratitude to Professor S. K. Lahiri for his valuable suggestions. The authors acknowledge the staff members of the MEMS laboratory, IIT Kharagpur, for their help at various stages in realization of the microthruster.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Kundu, P., Bhattacharyya, T.K. & Das, S. Electro-thermal analysis of an embedded boron diffused microheater for thruster applications. Microsyst Technol 20, 23–33 (2014). https://doi.org/10.1007/s00542-013-1759-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00542-013-1759-2