A research project is currently underway to develop small-scale internal combustion engines fueled by liquid hydrocarbons. The ultimate goal of the MEMS Rotary Internal Combustion Engine Project is to develop a liquid hydrocarbon fueled MEMS-size rotary internal combustion micro-engine capable of delivering power on the order of milli-watts. This research is part of a larger effort to develop a portable, autonomous power generation system with an order of magnitude improvement in energy density over alkaline or lithium-ion batteries. The rotary (Wankel-type) engine is well suited for the fabrication techniques developed in the integrated chip (IC) community and refined by the MicroElectroMechanical Systems (MEMS) field. Features of the rotary engine that lend itself to MEMS fabrication are its planar construction, high specific power, and self-valving operation. The project aims at developing a "micro-rotary" engine with an 3 epitrochoidal-shaped housing under 1 mm in size and with a rotor swept volume of 0.08 mm 3. To investigate engine behavior and design issues, larger-scale "mini-rotary" engines have been fabricated from steel. Mini-rotary engine chambers are approximately 1000 mm 3 to 1700 mm 3 in size and their displacements range from 78 mm 3 to 348 mm 3. A test bench for the mini-rotary engine has been developed and experiments have been conducted with gaseous-fueled mini-rotary engines to examine the effects of sealing, ignition, design, and thermal management on efficiency. Preliminary testing has shown net power output of up to 2.7 W at 9300 RPM. Testing has been performed using hydrogen-air mixtures and a range of spark and glow plug designs as the ignition source. Iterative design and testing of the miniengine has lead to improved sealing designs. These particular designs are such that they can be incorporated into the fabrication of the micro-engine. Design and fabrication of a first generation meso-scale rotary engine has been completed using a SiC molding process developed at Case Western Reserve University. The fabrication of the micro-rotary engine is being conducted in U.C. Berkeley's Microfabrication Laboratory. Testing of the mini-engine has lead to the conclusion that there are no fundamental phenomena that would prevent the operation of the micro-engine. However, heat loss and sealing issues are key for efficient operation of the micro-engine, and they must be taken into account in the design and fabrication of the micro-rotary engine. The mini-rotary engine design, testing, results and applications will be discussed in this paper. NOMENCLATURE
[1]
Y. Çengel,et al.
Thermodynamics : An Engineering Approach
,
1989
.
[2]
G. Gauba,et al.
Combustors for micro-gas turbine engines
,
1998
.
[3]
Mehran Mehregany,et al.
SiC MEMS: Opportunities and challenges for applications in harsh environments
,
1999
.
[4]
E. M. Bulewicz.
Combustion
,
1964,
Nature.
[5]
V. V. Zamashchikov.
Experimental investigation of gas combustion regimes in narrow tubes
,
1997
.
[6]
G. Kovacs.
Micromachined Transducers Sourcebook
,
1998
.
[7]
R. E. Sonntag,et al.
Fundamentals of classical thermodynamics
,
1973
.
[8]
M. Mehregany,et al.
Fabrication and testing of micromachined silicon carbide and nickel fuel atomizers for gas turbine engines
,
1999
.
[9]
D. Liepmann,et al.
Microscale Combustion Research for Applications to MEMS Rotary IC Engine
,
2001
.
[10]
R. J. Crookes,et al.
Combustion in engineering
,
1983
.
[11]
Roger T. Howe,et al.
A low-temperature CVD process for silicon carbide MEMS
,
2002
.
[12]
M. Madou.
Fundamentals of microfabrication
,
1997
.
[13]
Jan P. Norbye.
The Wankel engine: design, development, applications,
,
1972
.