A propulsion system of the CRW (Canard rotor wing) type UAV (unmanned aerial vehicle) was composed of the turbojet engine, exhaust nozzles (including some tip jet nozzles and a main nozzle), and the duct system (including straight ducts, curved ducts, and master valve). The CRW-type UAV has three different flight modes, such as the rotary wing mode for takeoff and landing, the high-speed forward flight mode with the fixed wing, and the transition flight mode between the previously mentioned two flight modes. In order to evaluate transient performance characteristics of the CRW-type UAV propulsion system during flight mode transition, the propulsion system was modeled using SIMULINK®, which is a user-friendly graphical-user-interface-(GUI) type dynamic analysis tool provided by MATLAB, in this study. The transition flight mode between the rotary wing mode and the fixed wing mode was simulated by considering area variation of the master valve and the main exhaust nozzle. In order to verify acceptability of the main turbojet engine model, performance simulation results using SIMULINK were compared to results using the commercial program GSP. Through this simulation, proper operation of the master valve and the variable area main nozzle can be found for safe flight transition. Therefore, performance characteristics were investigated depending on various angle positions of the master valve.

1.
Tai
,
J. C. M.
, 1998, “
A Multidisciplinary Design Approach to Size Stopped Rotor/Wing Configurations Using Reaction Drive and Circulation Control
,” Georgia Institute of Technology, Ph.D. thesis.
2.
Changduk
,
K.
, 2004, “
Steady-State/Transient Performance Simulation of the Propulsion System for the Canard Rotor Wing UAV During Flight Mode Transient
,”
Proceedings of ASME TURBO EXPO 2004, ASME, NY
.
3.
Math Works
, 1997,
SIMULINK: Dynamic System Simulation for MATLAB, Ver.2
,
The Math Works, Inc
.
4.
Fawke
,
A. J.
, 1970, “
Digital Computer Simulation of Gas Turbine Dynamic Behavior
,” Ph.D. thesis, University of Bristol, UK.
5.
ESDU
, 1966,
Friction Losses for Fully-Developed Flow in Straight Pipes
, Engineering Sciences Data Item No. 66027.
6.
ESDU
, 1977,
Pressure Losses in Curved Ducts: Single Bends
, Engineering Sciences Data Item No. 83037.
7.
The Boeing Company
, 2000,
EASY5: Environmental Control System Library User Guide
.
You do not currently have access to this content.