3 Other formulas that you can solve using the same Inputs

Loss of Kinetic Energy during perfectly inelastic collision
Loss of kinetic energy during perfectly inelastic collision=((Mass of body A*Mass of body B)*(Initial Velocity of body A before collision-Initial Velocity of body B before collision)^2)/(2*(Mass of body A+Mass of body B)) GO
Coefficient of Restitution
Coefficient of restitution=(Final Velocity of body A after elastic collision-Final Velocity of body B after elastic collision)/(Initial Velocity of body B before collision-Initial Velocity of body A before collision) GO
Kinetic Energy of system after inelastic collision
Kinetic Energy of system after inelastic collision=((Mass of body A+Mass of body B)*(Final Velocity of body A and B after inelastic collision^2))/2 GO

Final Velocity of body A and B after inelastic collision Formula

Final Velocity of body A and B after inelastic collision=((Mass of body A*Initial Velocity of body A before collision)+(Mass of body B*Initial Velocity of body B before collision))/(Mass of body A+Mass of body B)
More formulas
Centripetal Force or Centrifugal Force when angular velocity, mass and radius of curvature are given GO
Impulse GO
Impulsive Force GO
Impulsive Torque GO
Gear Ratio when two shafts A and B are geared together GO
Angular Velocity when speed in R.P.M is given GO
Angular acceleration of shaft B if gear ratio and angular acceleration of shaft A is known GO
Torque required on shaft A to accelerate itself if M.I of A and angular acceleration of shaft A are given GO
Torque on Shaft B to Accelerate Itself when M.I and Angular Acceleration are Given GO
Torque on Shaft B to Accelerate Itself when Gear Ratio is Given GO
Torque on Shaft A to Accelerate Shaft B GO
Torque on Shaft A to Accelerate Shaft B When Gear Efficiency is Given GO
Total Torque applied to shaft A to accelerate the geared system GO
Total Torque applied to accelerate the geared system if Ta and Tab are known GO
Efficiency of Machine GO
Overall Efficiency from shaft A to X GO
Power Loss GO
Total Kinetic Energy of the geared system GO
Equivalent Mass Moment of Inertia of geared system with shaft A and shaft B GO
Speed of Guide Pulley GO
Loss of Kinetic Energy during perfectly inelastic collision GO
Coefficient of Restitution GO
Loss of Kinetic Energy during imperfect elastic impact GO
Kinetic Energy of system after inelastic collision GO

What Is Inelastic Collision?

An inelastic collision is a collision in which there is a loss of kinetic energy. While momentum of the system is conserved in an inelastic collision, kinetic energy is not.

How to Calculate Final Velocity of body A and B after inelastic collision?

Final Velocity of body A and B after inelastic collision calculator uses Final Velocity of body A and B after inelastic collision=((Mass of body A*Initial Velocity of body A before collision)+(Mass of body B*Initial Velocity of body B before collision))/(Mass of body A+Mass of body B) to calculate the Final Velocity of body A and B after inelastic collision, Final Velocity of body A and B after inelastic collision, is the last velocity of a given object after a period of time. Final Velocity of body A and B after inelastic collision and is denoted by v symbol.

How to calculate Final Velocity of body A and B after inelastic collision using this online calculator? To use this online calculator for Final Velocity of body A and B after inelastic collision, enter Initial Velocity of body A before collision (u1), Initial Velocity of body B before collision (u2), Mass of body A (m1) and Mass of body B (m2) and hit the calculate button. Here is how the Final Velocity of body A and B after inelastic collision calculation can be explained with given input values -> 6.264368 = ((65*5)+(22*10))/(65+22).

FAQ

What is Final Velocity of body A and B after inelastic collision?
Final Velocity of body A and B after inelastic collision, is the last velocity of a given object after a period of time and is represented as v=((m1*u1)+(m2*u2))/(m1+m2) or Final Velocity of body A and B after inelastic collision=((Mass of body A*Initial Velocity of body A before collision)+(Mass of body B*Initial Velocity of body B before collision))/(Mass of body A+Mass of body B). Initial Velocity of body A before collision, is the rate of change of its position with respect to a frame of reference, and is a function of time, Initial Velocity of body B before collision, is the rate of change of its position with respect to a frame of reference, and is a function of time, Mass of body A is the measure of the quantity of matter that a body or an object contains and Mass of body B is the measure of the quantity of matter that a body or an object contains.
How to calculate Final Velocity of body A and B after inelastic collision?
Final Velocity of body A and B after inelastic collision, is the last velocity of a given object after a period of time is calculated using Final Velocity of body A and B after inelastic collision=((Mass of body A*Initial Velocity of body A before collision)+(Mass of body B*Initial Velocity of body B before collision))/(Mass of body A+Mass of body B). To calculate Final Velocity of body A and B after inelastic collision, you need Initial Velocity of body A before collision (u1), Initial Velocity of body B before collision (u2), Mass of body A (m1) and Mass of body B (m2). With our tool, you need to enter the respective value for Initial Velocity of body A before collision, Initial Velocity of body B before collision, Mass of body A and Mass of body B and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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