Aircraft Engineering Principles, 2nd ed
Aircraft Engineering Principles is the essential text for anyone studying for licensed A&P or Aircraft Maintenance Engineer status. The book is written to meet the requirements of JAR-66/ECAR-66, the Joint Aviation Requirement (to be replaced by European Civil Aviation Regulation) for all aircraft engineers within Europe, which is also being continuously harmonised with Federal Aviation Administration requirements in the USA.
The book covers modules 1, 2, 3, 4 and 8 of JAR-66/ECAR-66 in full and to a depth appropriate for Aircraft Maintenance Certifying Technicians, and will also be a valuable reference for those taking ab initio programmes in JAR-147/ECAR-147 and FAR-147. In addition, the necessary mathematics, aerodynamics and electrical principles have been included to meet the requirements of introductory Aerospace Engineering courses. Numerous written and multiple choice questions are provided at the end of each chapter, to aid learning.
Τι λένε οι χρήστες - Σύνταξη κριτικής
Δεν εντοπίσαμε κριτικές στις συνήθεις τοποθεσίες.
Chapter 1 Introduction
Chapter 2 Noncalculator mathematics
Chapter 3 Further mathematics
Chapter 4 Physics
Chapter 5 Electrical fundamentals
Chapter 6 Electronic fundamentals
Chapter 7 Basic aerodynamics
Opportunities for licence training education and career progression in the UK
National and international licensing and examination centres
Some national and international aircraft maintenance engineering training and education centres
System International and Imperial units
Multiplechoice revision paper questions
Answers to test your understanding and general questions
Answers to inchapter multiplechoice question sets and Appendix Es revision papers
Άλλες εκδόσεις - Προβολή όλων
acceleration aerofoil aileron aircraft maintenance airflow angle angle of attack applied atoms binary number calculator capacitance capacitor Category charge circuit component conductor connected constant convert current flowing decimal density determine device diagram digit diode distance drag EASA electrical electrons energy engine equation EXAMPLE factors fluid flux force formula fraction frequency function given graph heat hexadecimal increase induction inductor input integrated circuits KEY POINT lift lift force light linear load logarithm magnetic field mass material maximum motion motor moving multiply negative octal operational amplifier output voltage phasor positive pressure produce ratio reactance resistance resistor result rotating rotor shown in Figure simple SOLUTION specific heat capacity speed stator supply surface Table temperature TEST YOUR UNDERSTANDING torque transistor triangle units variable velocity voltage waveform waves weight wing Zener diode zero