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Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given Calculator

Category Engineering
Engineering Civil
Civil Hydraulics and Waterworks
Hydraulics-And-Waterworks Equations Of Motion And Energy Equation
Equations-Of-Motion-And-Energy-Equation Forces Acting on Fluid in Motion
Gravity Force is force due to gravitational pull.Gravity Force [Fg]
+10%
-10%
Pressure Force is force due to fluid load.Pressure Force [Fp]
+10%
-10%
Compressibility Force is force due liquid compressionCompressibility Force [Fc]
+10%
-10%
Surface Tension Force is force due property of layer of fluid.Surface Tension Force [Fs]
+10%
-10%
Viscous Force is force due to viscosityViscous Force [Fv]
+10%
-10%
Turbulent Force is force due to turbulencyTurbulent Force [Ft]
+10%
-10%
Mass is the quantity of matter in a body regardless of its volume or of any forces acting on it.Mass [m]
+10%
-10%
Acceleration is the rate of change in velocity to the change in time.Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given [a]
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Rithik Agrawal
National Institute of Technology Karnataka (NITK), Surathkal
Rithik Agrawal has created this Calculator and 400+ more calculators!
M Naveen
National Institute of Technology (NIT), Warangal
M Naveen has verified this Calculator and 100+ more calculators!

11 Other formulas that you can solve using the same Inputs

Impulsive Force
Impulsive Force=(Mass*(Final Velocity-Initial Velocity))/Time Taken to Travel GO
Specific Heat Capacity
Specific Heat Capacity=Energy Required/(Mass*Rise in Temperature) GO
Centripetal Force or Centrifugal Force when angular velocity, mass and radius of curvature are given
Centripetal Force=Mass*(Angular velocity^2)*Radius of Curvature GO
Potential Energy
Potential Energy=Mass*Acceleration Due To Gravity*Height GO
Moment of Inertia of a rod about an axis through its center of mass and perpendicular to rod
Moment of Inertia=(Mass*(Length of rod^2))/12 GO
Centripetal Force
Centripetal Force=(Mass*(Velocity)^2)/Radius GO
Moment of inertia of a circular disc about an axis through its center and perpendicular to its plane
Moment of Inertia=(Mass*(Radius 1^2))/2 GO
Moment of inertia of a circular ring about an axis through its center and perpendicular to its plane
Moment of Inertia=Mass*(Radius 1^2) GO
Kinetic Energy
Kinetic Energy=(Mass*Velocity^2)/2 GO
Force
Force=Mass*Acceleration GO
Density
Density=Mass/Volume GO

11 Other formulas that calculate the same Output

Acceleration of the follower of tangent cam with roller follower(contact with nose)
Acceleration=((Angular velocity of the cam^2)*Distance b/w cam center and nose center)*((cos(Angle turned by cam when roller is at nose top))+((((Distance b/w roller centre and nose centre^2)*Distance b/w cam center and nose center*cos((2*pi/180)*Angle turned by cam when roller is at nose top))+((Distance b/w cam center and nose center^3)*((sin((4*pi/180)*Angle turned by cam when roller is at nose top))^4)))/sqrt((Distance b/w roller centre and nose centre^2)-((Distance b/w cam center and nose center^2)*((sin(Angle turned by cam when roller is at nose top))^2))))) GO
Acceleration of the follower after time t (Cycloidal motion)
Acceleration=((2*pi*(Angular velocity of the cam^2)*Stroke of the follower)/(Angular displacement of the cam during out stroke^2))*sin((2*pi*Angle through which the cam rotates)/(Angular displacement of the cam during out stroke)) GO
Acceleration of the follower for tangent cam with roller follower(contact with straight flanks)
Acceleration=(Angular velocity of the cam^2)*(Radius of the base circle+Radius of the roller)*((2-((cos(Angle turned by cam from beginning of roller))^2))/((cos(Angle turned by cam from beginning of roller))^3)) GO
Minimum acceleration of the follower for circular arc cam(contact on the circular flank)
Acceleration=(Angular velocity of the cam^2)*(Radius of circular flank-Radius of the base circle)*cos(Total angle of action of cam) GO
Acceleration of the follower for circular arc cam(contact on the circular flank)
Acceleration=(Angular velocity of the cam^2)*(Radius of circular flank-Radius of the base circle)*cos(Angle turned by cam) GO
Acceleration of body in terms of stiffness of the constraint
Acceleration=(-Stiffness of the constraint*Displacement of Body)/Load attached to the free end of constraint GO
Acceleration of body in terms of stiffness of shaft
Acceleration=(-Stiffness of shaft*Displacement of Body)/Load attached to the free end of constraint GO
Min acceleration of follower for tangent cam with roller follower(contact with straight flanks)
Acceleration=(Angular velocity of the cam^2)*(Radius of the base circle+Radius of the roller) GO
Acceleration in SHM (when angular frequency is given)
Acceleration=-(Angular Frequency^2)*Distance Traveled GO
Accelaration( K and x given)
Acceleration=(-Constant K*Distance Traveled)/Mass GO
Acceleration
Acceleration=Change in Velocity/Total Time Taken GO

Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given Formula

Acceleration=(Gravity Force+Pressure Force+Compressibility Force+Surface Tension Force+Viscous Force+Turbulent Force)/Mass
a=(F<sub>g</sub>+F<sub>p</sub>+F<sub>c</sub>+F<sub>s</sub>+F<sub>v</sub>+F<sub>t</sub>)/m
More formulas
Sum of Total Forces Influencing Motion of Fluid GO
Gravity Force when Sum of Total Forces Influencing Motion of Fluid is Given GO
Pressure Force when Sum of Total Forces influencing Motion of Fluid is Given GO
Viscous Force when Sum of Total Forces Influencing Motion of Fluid is Given GO
Surface Tension Force when Sum of Total Forces influencing Motion of Fluid is Given GO
Compressibility Force when Sum of Total Forces influencing Motion of Fluid is Given GO
Turbulent Force when Sum of Total Forces influencing Motion of Fluid is Given GO
Mass of Fluid when Sum of Total Forces influencing Motion of Fluid is Given GO

What is Acceleration ?

In mechanics, acceleration is the rate of change of the velocity of an object with respect to time. Accelerations are vector quantities. The orientation of an object's acceleration is given by the orientation of the net force acting on that object.

How to Calculate Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given?

Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given calculator uses Acceleration=(Gravity Force+Pressure Force+Compressibility Force+Surface Tension Force+Viscous Force+Turbulent Force)/Mass to calculate the Acceleration, The Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given is defined as acceleration that forces generate on the flow. Acceleration and is denoted by a symbol.

How to calculate Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given using this online calculator? To use this online calculator for Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given, enter Gravity Force (Fg), Pressure Force (Fp), Compressibility Force (Fc), Surface Tension Force (Fs), Viscous Force (Fv), Turbulent Force (Ft) and Mass (m) and hit the calculate button. Here is how the Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given calculation can be explained with given input values -> 1692.525 = (10000+10000+10000+10000+10000+10000)/35.45.

FAQ

What is Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given?
The Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given is defined as acceleration that forces generate on the flow and is represented as a=(Fg+Fp+Fc+Fs+Fv+Ft)/m or Acceleration=(Gravity Force+Pressure Force+Compressibility Force+Surface Tension Force+Viscous Force+Turbulent Force)/Mass. Gravity Force is force due to gravitational pull, Pressure Force is force due to fluid load, Compressibility Force is force due liquid compression, Surface Tension Force is force due property of layer of fluid, Viscous Force is force due to viscosity, Turbulent Force is force due to turbulency and Mass is the quantity of matter in a body regardless of its volume or of any forces acting on it.
How to calculate Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given?
The Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given is defined as acceleration that forces generate on the flow is calculated using Acceleration=(Gravity Force+Pressure Force+Compressibility Force+Surface Tension Force+Viscous Force+Turbulent Force)/Mass. To calculate Acceleration of Fluid when Sum of Total Forces influencing Motion of Fluid is Given, you need Gravity Force (Fg), Pressure Force (Fp), Compressibility Force (Fc), Surface Tension Force (Fs), Viscous Force (Fv), Turbulent Force (Ft) and Mass (m). With our tool, you need to enter the respective value for Gravity Force, Pressure Force, Compressibility Force, Surface Tension Force, Viscous Force, Turbulent Force and Mass and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Acceleration?
In this formula, Acceleration uses Gravity Force, Pressure Force, Compressibility Force, Surface Tension Force, Viscous Force, Turbulent Force and Mass. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Acceleration=Change in Velocity/Total Time Taken
  • Acceleration=((2*pi*(Angular velocity of the cam^2)*Stroke of the follower)/(Angular displacement of the cam during out stroke^2))*sin((2*pi*Angle through which the cam rotates)/(Angular displacement of the cam during out stroke))
  • Acceleration=(Angular velocity of the cam^2)*(Radius of the base circle+Radius of the roller)*((2-((cos(Angle turned by cam from beginning of roller))^2))/((cos(Angle turned by cam from beginning of roller))^3))
  • Acceleration=(Angular velocity of the cam^2)*(Radius of the base circle+Radius of the roller)
  • Acceleration=((Angular velocity of the cam^2)*Distance b/w cam center and nose center)*((cos(Angle turned by cam when roller is at nose top))+((((Distance b/w roller centre and nose centre^2)*Distance b/w cam center and nose center*cos((2*pi/180)*Angle turned by cam when roller is at nose top))+((Distance b/w cam center and nose center^3)*((sin((4*pi/180)*Angle turned by cam when roller is at nose top))^4)))/sqrt((Distance b/w roller centre and nose centre^2)-((Distance b/w cam center and nose center^2)*((sin(Angle turned by cam when roller is at nose top))^2)))))
  • Acceleration=(Angular velocity of the cam^2)*(Radius of circular flank-Radius of the base circle)*cos(Total angle of action of cam)
  • Acceleration=(Angular velocity of the cam^2)*(Radius of circular flank-Radius of the base circle)*cos(Angle turned by cam)
  • Acceleration=(-Stiffness of the constraint*Displacement of Body)/Load attached to the free end of constraint
  • Acceleration=(-Stiffness of shaft*Displacement of Body)/Load attached to the free end of constraint
  • Acceleration=(-Constant K*Distance Traveled)/Mass
  • Acceleration=-(Angular Frequency^2)*Distance Traveled
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