Height of Liquid given its Absolute Pressure Solution

STEP 0: Pre-Calculation Summary
Formula Used
Height Absolute = (Absolute pressure-Atmospheric pressure)/Specific Weight
habsolute = (Pabs-Patm)/γ
This formula uses 4 Variables
Variables Used
Height Absolute - (Measured in Meter) - Height Absolute is the distance between the lowest and highest points of a person/ shape/ object standing upright.
Absolute pressure - (Measured in Pascal) - Absolute pressure is the sum of gauge pressure and atmospheric pressure.
Atmospheric pressure - (Measured in Pascal) - Atmospheric pressure also known as barometric pressure (after the barometer), is the pressure within the atmosphere of Earth.
Specific Weight - (Measured in Newton per Cubic Meter) - Specific Weight is defined as weight per unit volume.
STEP 1: Convert Input(s) to Base Unit
Absolute pressure: 534000 Pascal --> 534000 Pascal No Conversion Required
Atmospheric pressure: 101000 Pascal --> 101000 Pascal No Conversion Required
Specific Weight: 123.3 Newton per Cubic Meter --> 123.3 Newton per Cubic Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
habsolute = (Pabs-Patm)/γ --> (534000-101000)/123.3
Evaluating ... ...
habsolute = 3511.7599351176
STEP 3: Convert Result to Output's Unit
3511.7599351176 Meter -->351175.99351176 Centimeter (Check conversion here)
FINAL ANSWER
351175.99351176 351176 Centimeter <-- Height Absolute
(Calculation completed in 00.004 seconds)

Credits

Created by Kethavath Srinath
Osmania University (OU), Hyderabad
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Vishwakarma Government Engineering College (VGEC), Ahmedabad
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25 Pressure Relations Calculators

Depth of Centroid given Center of Pressure
Go Depth of Centroid = (Center of Pressure*Surface area+sqrt((Center of Pressure*Surface area)^2+4*Surface area*Moment of Inertia))/(2*Surface area)
Center of Pressure on Inclined Plane
Go Center of Pressure = Depth of Centroid+(Moment of Inertia*sin(Angle)*sin(Angle))/(Wet Surface Area*Depth of Centroid)
Differential Pressure-Differential Manometer
Go Pressure Changes = Specific weight 2*Height of Column 2+Specific Weight of Manometer liquid*Height of Manometer Liquid-Specific Weight 1*Height of Column 1
Area of Surface Wetted given Center of Pressure
Go Wet Surface Area = Moment of Inertia/((Center of Pressure-Depth of Centroid)*Depth of Centroid)
Height of Fluid 1 given Differential Pressure between Two Points
Go Height of Column 1 = (Pressure Changes+Specific weight 2*Height of Column 2)/Specific Weight 1
Height of Fluid 2 given Differential Pressure between Two Points
Go Height of Column 2 = (Specific Weight 1*Height of Column 1-Pressure Changes)/Specific weight 2
Moment of Inertia of Centroid given Center of Pressure
Go Moment of Inertia = (Center of Pressure-Depth of Centroid)*Wet Surface Area*Depth of Centroid
Center of Pressure
Go Center of Pressure = Depth of Centroid+Moment of Inertia/(Wet Surface Area*Depth of Centroid)
Differential Pressure between Two Points
Go Pressure Changes = Specific Weight 1*Height of Column 1-Specific weight 2*Height of Column 2
Angle of Inclined Manometer given Pressure at Point
Go Angle = asin(Pressure on Point/Specific Weight 1*Length of Inclined Manometer)
Length of Inclined Manometer
Go Length of Inclined Manometer = Pressure a/(Specific Weight 1*sin(Angle))
Pressure using Inclined Manometer
Go Pressure a = Specific Weight 1*Length of Inclined Manometer*sin(Angle)
Absolute Pressure at Height h
Go Absolute pressure = Atmospheric pressure+Specific weight of liquids*Height Absolute
Height of Liquid given its Absolute Pressure
Go Height Absolute = (Absolute pressure-Atmospheric pressure)/Specific Weight
Pressure Wave Velocity in Fluids
Go Velocity of pressure wave = sqrt(Bulk Modulus/Mass Density)
Velocity of Fluid given Dynamic Pressure
Go Fluid Velocity = sqrt(Dynamic Pressure*2/Liquid Density)
Dynamic Pressure Head-Pitot Tube
Go Dynamic Pressure Head = (Fluid Velocity^(2))/(2*Acceleration Due To Gravity)
Diameter of Soap Bubble
Go Diameter of Droplet = (8*Surface Tensions)/Pressure Changes
Surface Tension of Liquid Drop given Change in Pressure
Go Surface Tensions = Pressure Changes*Diameter of Droplet/4
Diameter of Droplet given Change in Pressure
Go Diameter of Droplet = 4*Surface Tensions/Pressure Changes
Mass Density given Velocity of Pressure Wave
Go Mass Density = Bulk Modulus/(Velocity of pressure wave^2)
Surface Tension of Soap Bubble
Go Surface Tensions = Pressure Changes*Diameter of Droplet/8
Dynamic Pressure of Fluid
Go Dynamic Pressure = (Liquid Density*Fluid Velocity^(2))/2
Bulk Modulus given Velocity of Pressure Wave
Go Bulk Modulus = Velocity of pressure wave^2*Mass Density
Density of Liquid given Dynamic Pressure
Go Liquid Density = 2*Dynamic Pressure/(Fluid Velocity^2)

Height of Liquid given its Absolute Pressure Formula

Height Absolute = (Absolute pressure-Atmospheric pressure)/Specific Weight
habsolute = (Pabs-Patm)/γ

Define Absolute Pressure?

Absolute pressure is measured relative to a full vacuum. In contrast, the pressure that is measured against atmospheric pressure (also known as barometric pressure) is called gauge pressure. A full vacuum has an absolute pressure reading of 0 PSIA and average barometric pressure at sea level is ~14.7 PSIA.

How to Calculate Height of Liquid given its Absolute Pressure?

Height of Liquid given its Absolute Pressure calculator uses Height Absolute = (Absolute pressure-Atmospheric pressure)/Specific Weight to calculate the Height Absolute, The Height of Liquid given its Absolute Pressure formula is defined as the height of the liquid from the mean sea level. Height Absolute is denoted by habsolute symbol.

How to calculate Height of Liquid given its Absolute Pressure using this online calculator? To use this online calculator for Height of Liquid given its Absolute Pressure, enter Absolute pressure (Pabs), Atmospheric pressure (Patm) & Specific Weight (γ) and hit the calculate button. Here is how the Height of Liquid given its Absolute Pressure calculation can be explained with given input values -> 3.5E+7 = (534000-101000)/123.3.

FAQ

What is Height of Liquid given its Absolute Pressure?
The Height of Liquid given its Absolute Pressure formula is defined as the height of the liquid from the mean sea level and is represented as habsolute = (Pabs-Patm)/γ or Height Absolute = (Absolute pressure-Atmospheric pressure)/Specific Weight. Absolute pressure is the sum of gauge pressure and atmospheric pressure, Atmospheric pressure also known as barometric pressure (after the barometer), is the pressure within the atmosphere of Earth & Specific Weight is defined as weight per unit volume.
How to calculate Height of Liquid given its Absolute Pressure?
The Height of Liquid given its Absolute Pressure formula is defined as the height of the liquid from the mean sea level is calculated using Height Absolute = (Absolute pressure-Atmospheric pressure)/Specific Weight. To calculate Height of Liquid given its Absolute Pressure, you need Absolute pressure (Pabs), Atmospheric pressure (Patm) & Specific Weight (γ). With our tool, you need to enter the respective value for Absolute pressure, Atmospheric pressure & Specific Weight 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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