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Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering PDF Download

Introduction

The most basic system that is used as a model for vibrational analysis is a block of mass m connected to a linear spring (with spring constant K and unstretched length ℓ0) and a viscous damper (with damping coefficient c). In addition, an external force P(t) is applied to the block and the displacement of the block is measured from the inertially fixed point O, where O is the point where the spring is unstretched. Finally, the spring and damper are both attached at the inertially fixed point Q. This system is shown in Fig. 1–1 Denoting unit vector in the direction from O to Q as Eand the inertial reference frame of the ground by F, the inertial acceleration of the block is given as

 F= x¨Ex                                                                                                 (1–1)

Next, the forces exerted by the spring and damper are given, respectively, as

F = −K(ℓ − ℓ0)u                                                                                     (1–2)
Ff = −cvrel                                                                                                 (1–3)

First, because the spring is attached at point Q, we have

ℓ = ║  r − r║                                                                                          (1–4)

 

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

Figure 1–1 Block of mass m sliding without friction along a horizontal surface connected to a linear spring and a linear viscous damper.

where r and rQ are the positions of the block and the attachment points of the spring, respectively. Using a coordinate system with its origin at point O at Ex as the first principal direction, we have

r = xE                                                                                                                       (1–5)
rQ = ℓ0Ex                                                                                                                     (1–6)

Therefore,

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

Then, because x < ℓ0 we have

|x − ℓ0| = ℓ0 − x                                                                                                          (1–8)

Finally, the unit vector in the direction from the attachment point of the spring to the position of the block is

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

The force in the linear spring is then given as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering 

Next, because the ground is already assumed to be inertial, the relative velocity between the block and the ground is simply the velocity of the block, i.e.,

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering                                                                                                      (1–11)

Therefore, the force exerted by the viscous damper is obtained as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering                                                                                                        (1–12)

The resultant external force acting on the particle is then obtained as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering                      (1–13)
Applying Newton’s second law to the particle, we obtain
Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering                                                                     (1–14)

Dropping Ex from Eq. (1–14) and rearranging, we obtain the differential equation of motion as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering                                                                                  (1–15)

Now historically it has been the case that the differential equation has been written in a form that is normalized by the mass, i.e., we divide Eq. (1–15) by m to obtain

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

where p(t) = P (t)/m. Furthermore, it is common practice to define the quantities K/m and c/m as follows:

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering
The quantities ωn and ζ are called the natural frequency and damping ratio of the system, respectively. In terms of the natural frequency and damping ratio, the differential equation of motion for the mass-spring-damper system can be written in the so-called standard form as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

 

It is seen that Eq. (1–17) is a second-order linear constant coefficient ordinary differential equation. Often, the term “constant coefficient” is replaced with the term time-invariant, i.e., we say that Eq. (1–17) is called a second-order linear time-invariant (LTI) ordinary differential equation. The terminology “time-invariant” stems from the fact that for a given input p(t) and a given set of initial conditions Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering at the initial time t = t0 is the same as the solution to the input p(t + τ) for the initial conditions Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering at the (shifted) initial time t = t0 + τ. Because of this fact associated with an LTI system, without loss of generality, we can assume that the initial time is zero, i.e., t0 = 0. Thus, when studying the zero input response of an LTI system we can restrict our attention to initial conditions Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering.

General Solution of a Second-Order LTI Differential Equation

Eq. (1–17) can be written as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

which can be further written as

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

Now let

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

Then we can view the system of Eq. (1–17) as a system of the form

Lx = f                                                                                                                  (1–21)

It is seen that the operator L defined in Eq. (1–20) is linear because

L(αx1 + βx2) = αL(x1) + βL(x2)                                                                           (1–22)

for all constants α and β. Then it is seen that Eq. (1–21) is a linear system whose general solution is of then form Eq. (1–17) is given as

x(t) = xh(t) + xp(t)                                                                                               (1–23)

here xh(t) is the homogeneous solution (i.e., the solution for a particular set of initial conditions Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering with a zero input function p(t) ≡ 0) while xp(t) is the particular solution (i.e., the solution for zero initial conditions (x(t0), x(t0) = (0, 0) and an arbitrary input function p(t) ≠ 0). The homogeneous solution and particular solutions are also called the zero input response and zero initial condition response, respectively. The general solution x(t) to a second-order LTI system is then given as the sum of the zero input response and the zero initial condition response. Because the zero input response satisfies Eq. (1–17) when p(t) ≡ 0, we have

 

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

 

Contrariwise, because the zero initial condition response satisfies Eq. (1–17) when p(t) ≠ 0 and the initial conditions are zero, we have

Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering

 

From the preceding discussion, it is seen that studying the general response of a second-order LTI system amounts to studying independently the zero input response and the zero initial condition response. Consequently, the study of single-degree-of-freedom vibrations amounts to quantifying the zero input response and the zero initial condition response. In the remainder of this chapter, we study in detail the zero input response of a second-order LTI system that arises in the study of mechanical vibrations.

The document Mass Spring Damper System | Theory of Machines (TOM) - Mechanical Engineering is a part of the Mechanical Engineering Course Theory of Machines (TOM).
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FAQs on Mass Spring Damper System - Theory of Machines (TOM) - Mechanical Engineering

1. What is a second-order LTI differential equation?
Ans. A second-order LTI (Linear Time-Invariant) differential equation is a mathematical equation that describes the behavior of a dynamic system involving a second derivative of a variable with respect to time. It is linear, meaning that the variable and its derivatives appear only with a power of 1, and time-invariant, meaning the coefficients in the equation do not change with time.
2. What is a mass spring damper system?
Ans. A mass spring damper system is a mechanical system that consists of a mass (m) connected to a spring (k) and a damper (c). It is commonly used to model the behavior of various physical systems, such as mechanical vibrations, vehicle suspensions, and buildings subjected to seismic forces. The spring provides the restoring force, the damper dissipates energy, and the mass represents the object being moved.
3. How is the general solution of a second-order LTI differential equation derived for a mass spring damper system?
Ans. The general solution of a second-order LTI differential equation for a mass spring damper system can be derived using the characteristic equation method. By substituting a trial solution of the form x(t) = Ae^(st), where x(t) represents the displacement of the mass and s is a complex variable, into the differential equation, we can obtain the characteristic equation. Solving this equation yields the roots, which are used to determine the general solution in terms of exponential functions.
4. What are the physical interpretations of the parameters in a mass spring damper system?
Ans. In a mass spring damper system, the parameters have the following physical interpretations: - Mass (m): Represents the inertia of the system and determines how the mass responds to external forces. - Spring constant (k): Represents the stiffness of the spring and determines how much force is required to deform or compress the spring. - Damping coefficient (c): Represents the amount of damping or resistance to the motion of the mass. It determines how quickly the system returns to equilibrium after being displaced.
5. How does the behavior of a mass spring damper system change with different parameter values?
Ans. The behavior of a mass spring damper system depends on the values of the mass (m), spring constant (k), and damping coefficient (c). - Increasing the mass increases the inertia and slows down the system's response. - Increasing the spring constant increases the stiffness, making the system oscillate at a higher frequency. - Increasing the damping coefficient increases the amount of damping, resulting in faster dissipation of energy and faster convergence to equilibrium.
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