Pressure Drop over Piston Solution

STEP 0: Pre-Calculation Summary
Formula Used
Pressure Drop due to Friction = (6*Dynamic Viscosity*Velocity of Piston*Piston Length/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance)
ΔPf = (6*μviscosity*vpiston*LP/(CR^3))*(0.5*D+CR)
This formula uses 6 Variables
Variables Used
Pressure Drop due to Friction - (Measured in Pascal) - Pressure Drop due to Friction is the decrease in the value of the pressure due to the influence of friction.
Dynamic Viscosity - (Measured in Pascal Second) - The Dynamic Viscosity of a fluid is the measure of its resistance to flow when an external force is applied.
Velocity of Piston - (Measured in Meter per Second) - Velocity of piston in reciprocating pump is defined as the product of sin of angular velocity and time, radius of crank and angular velocity.
Piston Length - (Measured in Meter) - Piston Length is how far the piston travels in the cylinder, which is determined by the cranks on the crankshaft. length.
Radial Clearance - (Measured in Meter) - Radial Clearance or gap is the distance between two surfaces adjacent to each other.
Diameter of Piston - (Measured in Meter) - Diameter of Piston is the actual diameter of the piston while the bore is the size of the cylinder and will always be larger than the piston.
STEP 1: Convert Input(s) to Base Unit
Dynamic Viscosity: 10.2 Poise --> 1.02 Pascal Second (Check conversion here)
Velocity of Piston: 0.045 Meter per Second --> 0.045 Meter per Second No Conversion Required
Piston Length: 5 Meter --> 5 Meter No Conversion Required
Radial Clearance: 0.45 Meter --> 0.45 Meter No Conversion Required
Diameter of Piston: 3.5 Meter --> 3.5 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
ΔPf = (6*μviscosity*vpiston*LP/(CR^3))*(0.5*D+CR) --> (6*1.02*0.045*5/(0.45^3))*(0.5*3.5+0.45)
Evaluating ... ...
ΔPf = 33.2444444444444
STEP 3: Convert Result to Output's Unit
33.2444444444444 Pascal --> No Conversion Required
FINAL ANSWER
33.2444444444444 33.24444 Pascal <-- Pressure Drop due to Friction
(Calculation completed in 00.020 seconds)

Credits

Created by Rithik Agrawal
National Institute of Technology Karnataka (NITK), Surathkal
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12 Dash-Pot Mechanism Calculators

Velocity of Flow in Oil Tank
Go Fluid Velocity in Oil Tank = (Pressure Gradient*0.5*(Horizontal Distance*Horizontal Distance-Hydraulic Clearance*Horizontal Distance)/Dynamic Viscosity)-(Velocity of Piston*Horizontal Distance/Hydraulic Clearance)
Pressure Gradient given Velocity of Flow in Oil Tank
Go Pressure Gradient = (Dynamic Viscosity*2*(Fluid Velocity in Oil Tank-(Velocity of Piston*Horizontal Distance/Hydraulic Clearance)))/(Horizontal Distance*Horizontal Distance-Hydraulic Clearance*Horizontal Distance)
Length of Piston for Vertical Upward Force on Piston
Go Piston Length = Vertical Component of Force/(Velocity of Piston*pi*Dynamic Viscosity*(0.75*((Diameter of Piston/Radial Clearance)^3)+1.5*((Diameter of Piston/Radial Clearance)^2)))
Vertical Upward Force on Piston given Piston Velocity
Go Vertical Component of Force = Piston Length*pi*Dynamic Viscosity*Velocity of Piston*(0.75*((Diameter of Piston/Radial Clearance)^3)+1.5*((Diameter of Piston/Radial Clearance)^2))
Length of Piston for Shear Force Resisting Motion of Piston
Go Piston Length = Shear Force/(pi*Dynamic Viscosity*Velocity of Piston*(1.5*(Diameter of Piston/Radial Clearance)^2+4*(Diameter of Piston/Radial Clearance)))
Shear Force Resisting Motion of Piston
Go Shear Force = pi*Piston Length*Dynamic Viscosity*Velocity of Piston*(1.5*(Diameter of Piston/Radial Clearance)^2+4*(Diameter of Piston/Radial Clearance))
Pressure Gradient given Rate of Flow
Go Pressure Gradient = (12*Dynamic Viscosity/(Radial Clearance^3))*((Discharge in Laminar Flow/pi*Diameter of Piston)+Velocity of Piston*0.5*Radial Clearance)
Length of Piston for Pressure Drop over Piston
Go Piston Length = Pressure Drop due to Friction/((6*Dynamic Viscosity*Velocity of Piston/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance))
Pressure Drop over Piston
Go Pressure Drop due to Friction = (6*Dynamic Viscosity*Velocity of Piston*Piston Length/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance)
Pressure Drop over Length of Piston given Vertical Upward Force on Piston
Go Pressure Drop due to Friction = Vertical Component of Force/(0.25*pi*Diameter of Piston*Diameter of Piston)
Vertical Force given Total Force
Go Vertical Component of Force = Shear Force-Total Force in Piston
Total Forces
Go Total Force = Vertical Component of Force+Shear Force

Pressure Drop over Piston Formula

Pressure Drop due to Friction = (6*Dynamic Viscosity*Velocity of Piston*Piston Length/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance)
ΔPf = (6*μviscosity*vpiston*LP/(CR^3))*(0.5*D+CR)

What is Pressure Drop?

Pressure drop is defined as the difference in total pressure between two points of a fluid carrying network. A pressure drop occurs when frictional forces, caused by the resistance to flow, act on a fluid as it flows through the tube.

How to Calculate Pressure Drop over Piston?

Pressure Drop over Piston calculator uses Pressure Drop due to Friction = (6*Dynamic Viscosity*Velocity of Piston*Piston Length/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance) to calculate the Pressure Drop due to Friction, The Pressure Drop over Piston is defined as change or drop in pressure due to friction between the piston and tank. Pressure Drop due to Friction is denoted by ΔPf symbol.

How to calculate Pressure Drop over Piston using this online calculator? To use this online calculator for Pressure Drop over Piston, enter Dynamic Viscosity viscosity), Velocity of Piston (vpiston), Piston Length (LP), Radial Clearance (CR) & Diameter of Piston (D) and hit the calculate button. Here is how the Pressure Drop over Piston calculation can be explained with given input values -> 33.24444 = (6*1.02*0.045*5/(0.45^3))*(0.5*3.5+0.45).

FAQ

What is Pressure Drop over Piston?
The Pressure Drop over Piston is defined as change or drop in pressure due to friction between the piston and tank and is represented as ΔPf = (6*μviscosity*vpiston*LP/(CR^3))*(0.5*D+CR) or Pressure Drop due to Friction = (6*Dynamic Viscosity*Velocity of Piston*Piston Length/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance). The Dynamic Viscosity of a fluid is the measure of its resistance to flow when an external force is applied, Velocity of piston in reciprocating pump is defined as the product of sin of angular velocity and time, radius of crank and angular velocity, Piston Length is how far the piston travels in the cylinder, which is determined by the cranks on the crankshaft. length, Radial Clearance or gap is the distance between two surfaces adjacent to each other & Diameter of Piston is the actual diameter of the piston while the bore is the size of the cylinder and will always be larger than the piston.
How to calculate Pressure Drop over Piston?
The Pressure Drop over Piston is defined as change or drop in pressure due to friction between the piston and tank is calculated using Pressure Drop due to Friction = (6*Dynamic Viscosity*Velocity of Piston*Piston Length/(Radial Clearance^3))*(0.5*Diameter of Piston+Radial Clearance). To calculate Pressure Drop over Piston, you need Dynamic Viscosity viscosity), Velocity of Piston (vpiston), Piston Length (LP), Radial Clearance (CR) & Diameter of Piston (D). With our tool, you need to enter the respective value for Dynamic Viscosity, Velocity of Piston, Piston Length, Radial Clearance & Diameter of Piston 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 Pressure Drop due to Friction?
In this formula, Pressure Drop due to Friction uses Dynamic Viscosity, Velocity of Piston, Piston Length, Radial Clearance & Diameter of Piston. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Pressure Drop due to Friction = Vertical Component of Force/(0.25*pi*Diameter of Piston*Diameter of Piston)
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