Ch 10. Vibrations     Multimedia Engineering Dynamics
Free Vibs. Undamped Free Vibs. Damped Forced Vibration Energy Method        
Dynamics
 Free Vibrations- Damped Case Intro Theory Case Solution Example
 Chapter
- Particle -
 1. General Motion
 2. Force & Accel.
 3. Energy
 4. Momentum
- Rigid Body -
 5. General Motion
 6. Force & Accel.
 7. Energy
 8. Momentum
 9. 3-D Motion
 10. Vibrations
 
 Appendix
 Basic Math
 Units
 Basic Equations
 Sections
 
Search
 
 eBooks
 Dynamics
 Fluids
 Math
 Mechanics
 Statics
 Thermodynamics
 
Author(s):
Kurt Gramoll
 
©Kurt Gramoll
DYNAMICS - THEORY

 

  

In most mechanical systems, there is some type of damping effect when vibrations occur. It could be air or fluid resistance, shock absorber, or even molecule interactions. This damping effect can be effectively modeled as a force that is proportional to the objects velocity. This type of device is usually called a damper.
     


Spring-Mass-Damper System

 

 


Development of the Equation of Motion

  

Similar to the simple mass-spring system (undamped) presented in the previous section, the equations of motion of an mass-spring-damper system (damped) can be developed by summing forces. Gravity effects will cancel out similar to the damped system, and are not included in this derivation.

    FS + Fd = -may

substituting FS = ky and Fd = cv = c(dy/dt) gives,

 
m d2y/dt2 + c dy/dt + ky = 0
 

Recall, solving any differential equation requires that a general solution is first assumed and then initial conditions are used to find the constants.

For an undamped system, both sin and cos functions were used in the solution. For the damped system, it is more convenient to use an exponential form as,

     y(t) = Dest

where A is an arbitrary constant, and s is a characteristic parameter. Substituting this into the equation of motion will give

     (ms2 + cs + k ) Dest = 0
     
   

For nontrivial solutions (D ≠ 0), the two possible roots, s1 and s2, are

 
 

and the general solution is

     

where A and B are constants that are determined from initial or boundary conditions. When the square root term is equal to zero, the two roots are equal which gives critical damping, cc, as

     
     
   

To help simplify the equations another constant is used, the damping ratio or damping factor, ζ. This term denotes the severity of the damping.

     

Now, the roots can be simplified to

     

Depending on the term within the radical, the system is said to be overdamped, underdamped or critically damped.

     ζ = 1       Critically Damped
     ζ > 1       Overdamped
     ζ < 1       Underdamped

     
    Critically Damped (ζ = 1)


Critically Damped

 

For ζ = 1, the roots s1 and s2 are equal,

     s1 = s2 = -ωn

The general solution to the differential equation is

     

The coefficients A and B are

     
     
    Overdamped (ζ > 1) (Non-Oscillatory)

Overdamped 		 

For an overdamped system, general solution is

     

The constants A and B are determined from the initial conditions,

     
     
    Underdamped (ζ < 1) (Oscillatory)


Underdamped

 

When ζ < 1, underdamped system, the roots are

     

Here, ωd is referred to as the damped frequency,

     

Combining with the general solution gives

       

This can be simplified to give

      

where the constants C and D are

     
     
   
 
Practice Homework and Test problems now available in the 'Eng Dynamics' mobile app
Includes over 400 free problems with complete detailed solutions.
Available at the Google Play Store and Apple App Store.