Title :
A Riccati-transfer matrix method for shock response computation of rotor systems
Author :
Shaohua, He ; Pinghao, Zhang ; Xinyue, Wu
Author_Institution :
Dept. of Mech. Eng., Naval Univ. of Eng., Wuhan, China
Abstract :
The conventional Newmark method based on average acceleration concept cannot be directly applied to solve state-space first-order differential equations, which contains no explicit acceleration terms. Combining with a Newmark iteration algorithm based on average velocity concept, a Riccati-transfer matrix method was proposed to obtain transient response of rotor systems under base shock excitations. The derivation of system´s first-order differential equations and transient transfer matrixes was described in detail. Through numerical iteration, it has successfully obtained time-varying responses, including displacement, velocity and acceleration terms. The utility and validity of the proposed method was confirmed by an application example at last.
Keywords :
Riccati equations; damping; differential equations; iterative methods; rotors; shock waves; transfer function matrices; Newmark iteration algorithm; Riccati-transfer matrix method; acceleration; displacement; rotor systems; shock excitations; shock response computation; state-space first-order differential equation; transient response; velocity; Acceleration; Damping; Design engineering; Differential equations; Eigenvalues and eigenfunctions; Electric shock; Mechanical engineering; Riccati equations; Rotors; Transient response; Riccati-transfer matrix method; average velocity concept; rotor systems; transient response computation;
Conference_Titel :
Computer Design and Applications (ICCDA), 2010 International Conference on
Conference_Location :
Qinhuangdao
Print_ISBN :
978-1-4244-7164-5
Electronic_ISBN :
978-1-4244-7164-5
DOI :
10.1109/ICCDA.2010.5541224
