Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal Solution

STEP 0: Pre-Calculation Summary
Formula Used
Thickness of Fluid between Members = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Power loss for seal)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4)
t = (pi*ν*w^2)/(13200*Ploss)*(r2^4-r1^4)
This formula uses 1 Constants, 6 Variables
Constants Used
pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288
Variables Used
Thickness of Fluid between Members - (Measured in Meter) - The Thickness of Fluid between Members refers to how resistant a fluid is to moving through it. For example, Water has a low or "thin" viscosity, while honey has a "thick" or high viscosity.
Kinematic viscosity of bush seal fluid - (Measured in Square Meter per Second) - Kinematic viscosity of bush seal fluid is an atmospheric variable defined as the ratio between the dynamic viscosity μ and the density ρ of the fluid.
Nominal Packing Cross-section of Bush Seal - (Measured in Meter) - The Nominal Packing Cross-section of Bush Seal is a surface or shape exposed by making a straight cut through something, especially at right angles to an axis.
Power loss for seal - (Measured in Watt) - Power loss for seal is the loss of power consumed due to leakage of fluid through face seal.
Outer Radius of rotating member inside bush seal - (Measured in Meter) - Outer Radius of rotating member inside bush seal is the radius of the outer surface of the shaft rotating inside a bushed packing seal.
Inner Radius of Rotating Member inside Bush Seal - (Measured in Meter) - Inner Radius of rotating member inside bush seal is the radius of the inner surface of the shaft rotating inside a bushed packing seal.
STEP 1: Convert Input(s) to Base Unit
Kinematic viscosity of bush seal fluid: 7.25 Stokes --> 0.000725 Square Meter per Second (Check conversion here)
Nominal Packing Cross-section of Bush Seal: 8.5 Millimeter --> 0.0085 Meter (Check conversion here)
Power loss for seal: 15.7 Watt --> 15.7 Watt No Conversion Required
Outer Radius of rotating member inside bush seal: 20 Millimeter --> 0.02 Meter (Check conversion here)
Inner Radius of Rotating Member inside Bush Seal: 14 Millimeter --> 0.014 Meter (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
t = (pi*ν*w^2)/(13200*Ploss)*(r2^4-r1^4) --> (pi*0.000725*0.0085^2)/(13200*15.7)*(0.02^4-0.014^4)
Evaluating ... ...
t = 9.65447304275064E-20
STEP 3: Convert Result to Output's Unit
9.65447304275064E-20 Meter -->9.65447304275064E-17 Millimeter (Check conversion here)
FINAL ANSWER
9.65447304275064E-17 9.7E-17 Millimeter <-- Thickness of Fluid between Members
(Calculation completed in 00.004 seconds)

Credits

Created by sanjay shiva
national institute of technology hamirpur (NITH ), hamirpur , himachal pradesh
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17 Leakage through Bush Seals Calculators

Amount of Leakage of Fluid through Face Seal
Go Oil Flow from Bush Seal = (pi*Thickness of Fluid between Members^3)/(6*Kinematic viscosity of bush seal fluid*ln(Outer Radius of rotating member inside bush seal/Inner Radius of Rotating Member inside Bush Seal))*((3*Seal Fluid Density*Rotational speed of shaft inside seal^2)/(20*[g])*(Outer Radius of rotating member inside bush seal^2-Inner Radius of Rotating Member inside Bush Seal^2)-Internal Hydraulic Pressure-Pressure at Seal Inside Radius)
Radial Pressure Distribution for Laminar Flow
Go Pressure at Radial Position for Bush Seal = Pressure at Seal Inside Radius+(3*Seal Fluid Density*Rotational speed of shaft inside seal^2)/(20*[g])*(Radial Position in Bush Seal^2-Inner Radius of Rotating Member inside Bush Seal^2)-(6*Kinematic viscosity of bush seal fluid)/(pi*Thickness of Fluid between Members^3)*ln(Radial Position in Bush Seal/Radius of rotating member inside bush seal)
Volumetric Flow Rate under Laminar Flow Condition for Radial Bush Seal for Incompressible Fluid
Go Volumetric Flow Rate per Unit Pressure = (Radial Clearance for Seals^3)/(12*Absolute Viscosity of Oil in Seals)*(Outer Radius of Plain Bush Seal-Inner Radius of Plain Bush Seal)/(Outer Radius of Plain Bush Seal*ln(Outer Radius of Plain Bush Seal/Inner Radius of Plain Bush Seal))
Volumetric Flow Rate under Laminar Flow Condition for Radial Bush Seal for Compressible Fluid
Go Volumetric Flow Rate per Unit Pressure = (Radial Clearance for Seals^3)/(24*Absolute Viscosity of Oil in Seals)*((Outer Radius of Plain Bush Seal-Inner Radius of Plain Bush Seal)/(Outer Radius of Plain Bush Seal))*((Minimum Percentage Compression+Exit Pressure)/(Exit Pressure))
Outside Radius of Rotating Member given Power Loss due to Leakage of Fluid through Face Seal
Go Outer Radius of rotating member inside bush seal = (Power loss for seal/(((pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Thickness of Fluid between Members)))+Inner Radius of Rotating Member inside Bush Seal^4)^(1/4)
Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal
Go Thickness of Fluid between Members = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Power loss for seal)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4)
Kinematic Viscosity given Power Loss due to Leakage of Fluid through Face Seal
Go Kinematic viscosity of bush seal fluid = (13200*Power loss for seal*Thickness of Fluid between Members)/(pi*Nominal Packing Cross-section of Bush Seal^2*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4))
Power Loss or Consumption due to Leakage of Fluid through Face Seal
Go Power loss for seal = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Thickness of Fluid between Members)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4)
Oil Flow through Plain Radial Bush Seal due to Leakage under Laminar Flow Condition
Go Oil Flow from Bush Seal = (2*pi*Outer Radius of Plain Bush Seal*(Minimum Percentage Compression-Exit Pressure/10^6))/(Outer Radius of Plain Bush Seal-Inner Radius of Plain Bush Seal)*Volumetric Flow Rate per Unit Pressure
Internal Hydraulic Pressure given Zero Leakage of Fluid through Face Seal
Go Internal Hydraulic Pressure = Pressure at Seal Inside Radius+(3*Seal Fluid Density*Rotational speed of shaft inside seal^2)/20*(Outer Radius of rotating member inside bush seal^2-Inner Radius of Rotating Member inside Bush Seal^2)*1000
Oil Flow through Plain Axial Bush Seal due to Leakage under Laminar Flow Condition
Go Oil Flow from Bush Seal = (2*pi*Outer Radius of Plain Bush Seal*(Minimum Percentage Compression-Exit Pressure/10^6))/(Depth of U Collar)*Volumetric Flow Rate per Unit Pressure
Volumetric Flow Rate under Laminar Flow Condition for Axial Bush Seal for Compressible Fluid
Go Volumetric Flow Rate per Unit Pressure = (Radial Clearance for Seals^3)/(12*Absolute Viscosity of Oil in Seals)*(Minimum Percentage Compression+Exit Pressure)/(Exit Pressure)
Thickness of Fluid between Members given Shape Factor
Go Thickness of Fluid between Members = (Outside Diameter of Packing Gasket-Inside Diameter of Packing Gasket)/(4*Shape Factor for Circular Gasket)
Shape Factor for Circular or Annular Gasket
Go Shape Factor for Circular Gasket = (Outside Diameter of Packing Gasket-Inside Diameter of Packing Gasket)/(4*Thickness of Fluid between Members)
Outside Diameter of Gasket given Shape Factor
Go Outside Diameter of Packing Gasket = Inside Diameter of Packing Gasket+4*Thickness of Fluid between Members*Shape Factor for Circular Gasket
Inside Diameter of Gasket given Shape Factor
Go Inside Diameter of Packing Gasket = Outside Diameter of Packing Gasket-4*Thickness of Fluid between Members*Shape Factor for Circular Gasket
Volumetric Efficiency of Reciprocating Compressor
Go Volumetric Efficiency = Actual volume/Piston Swept Volume

Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal Formula

Thickness of Fluid between Members = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Power loss for seal)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4)
t = (pi*ν*w^2)/(13200*Ploss)*(r2^4-r1^4)

What is thickness of fluid?

Thickness of fluid refers to how resistant a fluid is to movement through it. Water has a low or "thin" viscosity, for example, while honey has a "thick" or high viscosity.

How to Calculate Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal?

Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal calculator uses Thickness of Fluid between Members = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Power loss for seal)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4) to calculate the Thickness of Fluid between Members, The Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal formula is defined as how resistant a fluid is to move through it. Thickness of Fluid between Members is denoted by t symbol.

How to calculate Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal using this online calculator? To use this online calculator for Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal, enter Kinematic viscosity of bush seal fluid (ν), Nominal Packing Cross-section of Bush Seal (w), Power loss for seal (Ploss), Outer Radius of rotating member inside bush seal (r2) & Inner Radius of Rotating Member inside Bush Seal (r1) and hit the calculate button. Here is how the Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal calculation can be explained with given input values -> 9.7E-14 = (pi*0.000725*0.0085^2)/(13200*15.7)*(0.02^4-0.014^4).

FAQ

What is Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal?
The Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal formula is defined as how resistant a fluid is to move through it and is represented as t = (pi*ν*w^2)/(13200*Ploss)*(r2^4-r1^4) or Thickness of Fluid between Members = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Power loss for seal)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4). Kinematic viscosity of bush seal fluid is an atmospheric variable defined as the ratio between the dynamic viscosity μ and the density ρ of the fluid, The Nominal Packing Cross-section of Bush Seal is a surface or shape exposed by making a straight cut through something, especially at right angles to an axis, Power loss for seal is the loss of power consumed due to leakage of fluid through face seal, Outer Radius of rotating member inside bush seal is the radius of the outer surface of the shaft rotating inside a bushed packing seal & Inner Radius of rotating member inside bush seal is the radius of the inner surface of the shaft rotating inside a bushed packing seal.
How to calculate Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal?
The Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal formula is defined as how resistant a fluid is to move through it is calculated using Thickness of Fluid between Members = (pi*Kinematic viscosity of bush seal fluid*Nominal Packing Cross-section of Bush Seal^2)/(13200*Power loss for seal)*(Outer Radius of rotating member inside bush seal^4-Inner Radius of Rotating Member inside Bush Seal^4). To calculate Thickness of Fluid between Members given Power Loss due to Leakage of Fluid through Face Seal, you need Kinematic viscosity of bush seal fluid (ν), Nominal Packing Cross-section of Bush Seal (w), Power loss for seal (Ploss), Outer Radius of rotating member inside bush seal (r2) & Inner Radius of Rotating Member inside Bush Seal (r1). With our tool, you need to enter the respective value for Kinematic viscosity of bush seal fluid, Nominal Packing Cross-section of Bush Seal, Power loss for seal, Outer Radius of rotating member inside bush seal & Inner Radius of Rotating Member inside Bush Seal 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 Thickness of Fluid between Members?
In this formula, Thickness of Fluid between Members uses Kinematic viscosity of bush seal fluid, Nominal Packing Cross-section of Bush Seal, Power loss for seal, Outer Radius of rotating member inside bush seal & Inner Radius of Rotating Member inside Bush Seal. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Thickness of Fluid between Members = (Outside Diameter of Packing Gasket-Inside Diameter of Packing Gasket)/(4*Shape Factor for Circular Gasket)
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