Rithik Agrawal
National Institute of Technology Karnataka (NITK), Surathkal
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Mridul Sharma
Indian Institute of Information Technology (IIIT), Bhopal
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11 Other formulas that you can solve using the same Inputs

Capillarity Through a Circular Tube if inserted in liquid of S1 above a liquid of S2
Capillarity height=(2*Surface Tension*cos(x))/(specific weight of liquid*Radius*(specific gravity of liquid -specific gravity of liquid )) Go
Angular Displacement if initial angular velocity, angular acceleration and time are given
Angular Displacement=(Angular Velocity*Time Taken to Travel)+((Angular Acceleration*(Time Taken to Travel)^2)/2) Go
Capillarity Through Parallel Plates
Capillarity height=(2*Surface Tension*cos(x))/(specific weight of liquid*Uniform Gap Between Vertical Plates) Go
Capillarity Through an Annular Space
Capillarity height=(2*Surface Tension*cos(x))/(specific weight of liquid*(outer radius-Inner radius )) Go
Minimum Distance Between Parallel Lines in 2D
Distance Between Line=modulus(Y intercept of line 1-Y intercept of line 2)/sqrt(1+Slope of Line^2) Go
Angular Displacement of body when initial and final angular velocity and angular acceleration are given
Angular Displacement=((Final Angular Velocity)^2-(Angular Velocity)^2)/(2*Angular Acceleration) Go
Height of Capillary Rise
Capillarity height=(4*Surface Tension*cos(x))/(specific weight of liquid*Diameter of tube) Go
Angular Displacement if initial angular velocity, final angular velocity and time are given
Angular Displacement=((Angular Velocity+Final Angular Velocity)*Time Taken to Travel)/2 Go
Final Angular Velocity if initial angular velocity, angular acceleration and time is given
Final Angular Velocity=Angular Velocity+(Angular Acceleration*Time Taken to Travel) Go
angle traced in nth second( accelerated rotatory motion)
Angular Displacement=Angular Velocity+((Angular Acceleration*(2*Nth Second -1))/2) Go
Angular Momentum
Angular Momentum=Moment of Inertia*Angular Velocity Go

6 Other formulas that calculate the same Output

Pressure at any point with origin at free surface
Absolute Pressure=Atmospheric Pressure+(specific weight of liquid/[g])*(0.5*(Angular Velocity*radial distance)^2)-Angular Velocity*Height Go
Pressure at any point in liquid
Absolute Pressure=Atmospheric Pressure+specific weight of liquid*Height*(1+Constant Vertical Acceleration/[g]) Go
Absolute Pressure using Equation of State when Specific Weight is known
Absolute Pressure=Gas Constant*Specific Weight*Absolute Temperature of Gas Go
Absolute Pressure using Equation of State
Absolute Pressure=Absolute Temperature of Gas*Density of Gas*Gas Constant Go
Pressure at Any Point in Liquid
Absolute Pressure=Atmospheric Pressure+specific weight of liquid*Height Go
Absolute Pressure
Absolute Pressure=Atmospheric Pressure+Vacuum Pressure Go

Pressure Intensity at a radial distance r from axis Formula

Absolute Pressure=specific weight of liquid*((((Angular Velocity*radial distance)^2)/2*[g])-radial distance*cos(pi/180*Slope of Line)+Vertical distance)
Pabs=y*((((ω*r s)^2)/2*[g])-r s*cos(pi/180*m)+V)
More formulas
Liquid Column Height when Pressure Intensity at a radial distance r from axis is Given Go
Pressure Intensity at a Radial Distance r=0 from Axis is Given Go
Total Pressure Force on Each End of Cylinder Go
Specific Weight of Liquid when Total Pressure Force on Each End of Cylinder is Given Go

What is Pressure ?

Pressure is the force applied perpendicular to the surface of an object per unit area over which that force is distributed. Gauge pressure is the pressure relative to the ambient pressure. Various units are used to express pressure.

How to Calculate Pressure Intensity at a radial distance r from axis?

Pressure Intensity at a radial distance r from axis calculator uses Absolute Pressure=specific weight of liquid*((((Angular Velocity*radial distance)^2)/2*[g])-radial distance*cos(pi/180*Slope of Line)+Vertical distance) to calculate the Absolute Pressure, The Pressure Intensity at a radial distance r from axis is defined as distribution of pressure across the pipe. Absolute Pressure and is denoted by Pabs symbol.

How to calculate Pressure Intensity at a radial distance r from axis using this online calculator? To use this online calculator for Pressure Intensity at a radial distance r from axis, enter specific weight of liquid (y), Angular Velocity (ω), radial distance (r s), Slope of Line (m) and Vertical distance (V) and hit the calculate button. Here is how the Pressure Intensity at a radial distance r from axis calculation can be explained with given input values -> 1.961E+8 = 1000*((((20*10)^2)/2*[g])-10*cos(pi/180*4)+4).

FAQ

What is Pressure Intensity at a radial distance r from axis?
The Pressure Intensity at a radial distance r from axis is defined as distribution of pressure across the pipe and is represented as Pabs=y*((((ω*r s)^2)/2*[g])-r s*cos(pi/180*m)+V) or Absolute Pressure=specific weight of liquid*((((Angular Velocity*radial distance)^2)/2*[g])-radial distance*cos(pi/180*Slope of Line)+Vertical distance). The specific weight of liquid is also known as the unit weight, is the weight per unit volume of the liquid. A commonly used value is the specific weight of water on Earth at 4°C, which is 9.807 kN/m3 or 62.43 lbf/ft3, The angular velocity refers to how fast an object rotates or revolves relative to another point, i.e. how fast the angular position or orientation of an object changes with time, The radial distance is considered in the stagnation point, The slope of a line is a number that measures its "steepness", usually denoted by the letter m. It is the change in y for a unit change in x along the line and vertical distance between center of transit and point on rod inter￾sected by middle horizontal crosshair.
How to calculate Pressure Intensity at a radial distance r from axis?
The Pressure Intensity at a radial distance r from axis is defined as distribution of pressure across the pipe is calculated using Absolute Pressure=specific weight of liquid*((((Angular Velocity*radial distance)^2)/2*[g])-radial distance*cos(pi/180*Slope of Line)+Vertical distance). To calculate Pressure Intensity at a radial distance r from axis, you need specific weight of liquid (y), Angular Velocity (ω), radial distance (r s), Slope of Line (m) and Vertical distance (V). With our tool, you need to enter the respective value for specific weight of liquid, Angular Velocity, radial distance, Slope of Line and Vertical distance 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 Absolute Pressure?
In this formula, Absolute Pressure uses specific weight of liquid, Angular Velocity, radial distance, Slope of Line and Vertical distance. We can use 6 other way(s) to calculate the same, which is/are as follows -
  • Absolute Pressure=Atmospheric Pressure+Vacuum Pressure
  • Absolute Pressure=Atmospheric Pressure+specific weight of liquid*Height
  • Absolute Pressure=Atmospheric Pressure+specific weight of liquid*Height*(1+Constant Vertical Acceleration/[g])
  • Absolute Pressure=Absolute Temperature of Gas*Density of Gas*Gas Constant
  • Absolute Pressure=Atmospheric Pressure+(specific weight of liquid/[g])*(0.5*(Angular Velocity*radial distance)^2)-Angular Velocity*Height
  • Absolute Pressure=Gas Constant*Specific Weight*Absolute Temperature of Gas
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