Author:
Drobzheva Ya V,Zikunkova D V,Krasnov V M
Abstract
Abstract
To assess the impact on human health of the sonic boom that occurs when an aircraft is flying at supersonic speed, and, accordingly, to solve the problem of noise reduction by optimizing the aircraft design, it is proposed to evaluate the shock wave energy using the TNT equivalent of a cylindrical explosion. An example of calculating the shock wave energy during flights of F4 and F18 aircraft at different altitudes is considered. To calculate the evolution of an acoustic pulse during its propagation from the boundary of the shock wave transition to the acoustic one, the wave equation and its solution are used, taking into account the inhomogenei-ty of the atmosphere, nonlinear effects, absorption and expansion of the wave front, as well as the results of ground-based measurements of acoustic pulses. The results of calculations of the dependence of the explosion energy on the flight altitude, as well as on the type of aircraft are explained on the basis of the formula for the atmospheric resistance force.
Subject
General Physics and Astronomy
Reference12 articles.
1. Estimation of the Power of the Chelyabinsk Meteoroid Blastfrom Optical, Seismic, and Infrasonic Observation Data;Krasnov;Acoustical Physics,2014
2. The Research of Supersonic Aircraft Low Sonic Boom Configuration Design and Optimizations;Xuan;Journal of Aeronaut Aerospace Engineering,2016
3. Impact of multipole matching resolution on supersonic aircraft sonic boom assessment;Salah;Progress in Flight Physics,2013
4. The flow pattern of a supersonic projectile;Whitham;Communications on Pure and Applied Mathtmatics,1952
5. The Propagation of Sound in an Inhomogeneous and Moving Medium. Part 1;Blokliintzev;Journal of the Acoustical Society of America,1946