Engineering Aerodynamics Homework
DBlaylock1979Aerodynamics homework assistance.
- a year ago
- 100
AERO_309_Module_6_HW.docx_safe.pdf
AERO_309_Module_6_HW.docx_safe.pdf
College of Aeronautics | worldwide.erau.edu
All rights are reserved. The material contained herein is the copyright property of Embry-Riddle Aeronautical University, Daytona Beach, Florida, 32114. No part of this material may be reproduced, stored in a retrieval system or transmitted in any form, electronic, mechanical, photocopying, recording or otherwise without the prior written consent of the University.
AERO 309 - Module 6 Homework 1. Say that you have an engine that is rated at 1300 hp and a propeller with a diameter of 7
ft. Use momentum theory to calculate the maximum thrust possible (in lb) from your engine at sea level. Explain why a real engine and propeller produce less thrust than the value you calculated.
2. Use the attached propeller charts for this problem. The propeller diameter is 10 ft and assume that the rotational speed of the propeller is constant at 1200 rpm. Assume that you are at standard sea level conditions.
a. For each of the seven pitch angles, what is the maximum propeller efficiency? What is the advance ratio and velocity for each of the maximum propeller efficiencies?
b. For each pitch angle, what is the thrust coefficient and thrust produced (in lb) at maximum propeller efficiency?
c. For each pitch angle, what is the power coefficient and power needed (in ft*lb/s and hp) at maximum propeller efficiency?
d. What is the velocity and Mach number at the tip of the propeller? The velocity at the tip will include both the forward velocity and rotational velocity.
3. A propeller-engine combination produces 600 hp of power. If the total displacement is 20,000 cm3, the engine efficiency is 0.93, the propeller efficiency is 0.84, and the rotational speed is 2600 rpm, calculate the mean effective pressure of the engine.
4. A turbojet is at an altitude of 33,000 ft traveling at a Mach number of 0.64. It has an inlet area of 8 ft2 and an exit area of 5 ft2. The exit velocity is 1700 ft/s and the exit pressure is 700 lb/ft2. The fuel-to-air ratio (by mass) is 0.05.
a. Ignoring the mass of the fuel, calculate the thrust produced by the turbojet. b. Recalculate the thrust of the turbojet but do not ignore the mass of the fuel. c. What is the percent error in ignoring the mass of the fuel when calculating the
thrust? d. The turbojet has a diffuser after the engine inlet. At the end of the diffuser, the
Mach number is 0.2. Calculate the pressure at the end of the diffuser. (Hint: the flow is isentropic so the total pressure will be constant)
e. Estimate the thrust of this turbojet engine at sea level. 5. A turbofan has a static thrust at sea level of 60,000 lb. Estimate the thrust available at
the conditions in question 4.
Page 2 of 3
Page 3 of 3