Title :
Micro Fabrication of SiC Mesoscale Lean Direct Injector Array: Toward Active Combustion Control
Author :
Okojie, R.S. ; Tacina, R. ; Wey, C. ; Blaha, C.
Author_Institution :
NASA Glenn Res. Center, Cleveland
Abstract :
We report the first utilization of microelectromechanical systems (MEMS) fabrication technology to implement a mesoscale fuel injector array in silicon carbide (SiC) substrate material. A combination of deep reactive ion etching (DRIE), ultrasonic micromachining, silicon loss-molding, and diffusion bonding of multiple SiC substrates was applied to fabricate the first generation 7times7-4 array injector platform. Arrayed spray patterns were demonstrated in water to determine the degree of atomization prior to fuel spray and combustion analyses. The primary objectives of this effort are: a) develop the foundational SiC platform injector array technology for use in gas turbine engines, b) use such technology to decrease combustion instabilities by active control of combustion processes.
Keywords :
combustion; engines; fuel systems; gas turbines; micromachining; micromechanical devices; moulding; silicon compounds; sputter etching; ultrasonic machining; MEMS fabrication technology; SiC; active combustion control; combustion analyses; deep reactive ion etching; diffusion bonding; fuel spray; gas turbine engine; mesoscale fuel injector array; mesoscale lean direct injector array; microelectromechanical systems; silicon loss-molding; ultrasonic micromachining; Combustion; Diffusion bonding; Etching; Fabrication; Fuels; Microelectromechanical systems; Micromachining; Micromechanical devices; Silicon carbide; Spraying; Injectors; MEMS; Silicon Carbide;
Conference_Titel :
Solid-State Sensors, Actuators and Microsystems Conference, 2007. TRANSDUCERS 2007. International
Conference_Location :
Lyon
Print_ISBN :
1-4244-0842-3
Electronic_ISBN :
1-4244-0842-3
DOI :
10.1109/SENSOR.2007.4300662
