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Semelhante a Mathematical Modeling of Mechanical Systems
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Mathematical Modeling of Mechanical Systems
- 1. MATHEMATICAL MODELING OF MECHANICAL SYSTEMS 1
- 2. Basic Types of Mechanical Systems • Translational – Linear Motion • Rotational – Rotational Motion 2
- 3. Basic Elements of Translational Mechanical Systems Translational Spring i) Translational Mass ii) Translational Damper iii)
- 4. Translational Spring i) Circuit Symbols Translational Spring • A translational spring is a mechanical element that can be deformed by an external force such that the deformation is directly proportional to the force applied to it. Translational Spring
- 5. Translational Spring • If F is the applied force • Then is the deformation if • Or is the deformation. • The equation of motion is given as • Where is stiffness of spring expressed in N/m 2 x 1 x 0 2 x 1 x ) ( 2 1 x x ) ( 2 1 x x k F k F F
- 6. Translational Mass Translational Mass ii) • Translational Mass is an inertia element. • A mechanical system without mass does not exist. • If a force F is applied to a mass and it is displaced to x meters then the relation b/w force and displacements is given by Newton’s law. M ) (t F ) (t x x M F
- 7. Translational Damper Translational Damper iii) • Damper opposes the rate of change of motion. • All the materials exhibit the property of damping to some extent. • If damping in the system is not enough then extra elements (e.g. Dashpot) are added to increase damping.
- 8. Common Uses of Dashpots Door Stoppers Vehicle Suspension Bridge Suspension Flyover Suspension
- 9. Translational Damper x C F • Where C is damping coefficient (N/ms-1). ) ( 2 1 x x C F
- 10. Example-1 • Consider the following system (friction is negligible) 10 • Free Body Diagram M F k f M f k F x M • Where and are force applied by the spring and inertial force respectively. k f M f
- 11. Example-1 11 • Then the differential equation of the system is: x M kx F • Taking the Laplace Transform of both sides and ignoring initial conditions we get M F k f M f M k f f F ) ( ) ( ) ( s kX s X Ms s F 2
- 12. 12 ) ( ) ( ) ( s kX s X Ms s F 2 • The transfer function of the system is k Ms s F s X 2 1 ) ( ) ( • if 1 2000 1000 Nm k kg M 2 001 0 2 s s F s X . ) ( ) ( Example-1
- 13. 13 • The pole-zero map of the system is 2 001 0 2 s s F s X . ) ( ) ( Example-2 -1 -0.5 0 0.5 1 0 𝑗 2 Pole-Zero Map Real Axis Imaginary Axis −𝑗 2
- 14. Example-2 • Consider the following system 14 • Free Body Diagram k F x M C M F k f M f C f C M k f f f F
- 15. Example-3 15 Differential equation of the system is: kx x C x M F Taking the Laplace Transform of both sides and ignoring Initial conditions we get ) ( ) ( ) ( ) ( s kX s CsX s X Ms s F 2 k Cs Ms s F s X 2 1 ) ( ) (
- 16. Example-4 • Consider the following system 16 • Mechanical Network k F 2 x M 1 x B ↑ M k B F 1 x 2 x
- 17. Example-4 17 • Mechanical Network ↑ M k B F 1 x 2 x ) ( 2 1 x x k F At node 1 x At node 2 x 2 2 1 2 0 x B x M x x k ) (
- 18. Example-6 18 k ) (t f 2 x 1 M 4 B 3 B 2 M 1 x 1 B 2 B ↑ M1 k 1 B ) (t f 1 x 2 x 3 B 2 B M2 4 B
- 19. Example-7 • Find the transfer function of the mechanical translational system given in Figure-1. 19 Free Body Diagram Figure-1 M ) (t f k f M f B f B M k f f f t f ) ( k Bs Ms s F s X 2 1 ) ( ) (
- 21. Basic Elements of Rotational Mechanical Systems Rotational Spring ) ( 2 1 k T 2 1
- 22. Basic Elements of Rotational Mechanical Systems Rotational Damper 2 1 ) ( 2 1 C T T C
- 23. Basic Elements of Rotational Mechanical Systems Moment of Inertia J T T J
- 24. Example-11 1 T 1 J 1 k 1 B 2 k 2 J 2 3 ↑ J1 1 k T 1 3 1 B J2 2 2 k
- 25. Example-12 ↑ J1 1 k 1 B T 1 3 2 B 3 B J2 4 B 2 1 T 1 J 1 k 3 B 2 B 4 B 1 B 2 J 2 3