External Work Done by Gas given Total Heat Supplied Solution

STEP 0: Pre-Calculation Summary
Formula Used
Work Done = Total Heat-Change in Internal Energy
w = H-ΔU
This formula uses 3 Variables
Variables Used
Work Done - (Measured in Joule) - Work Done refers to the amount of energy transferred or expended when a force acts on an object and causes displacement.
Total Heat - (Measured in Joule) - Total Heat is the heat contained in the same amount of dry air (known as sensible heat) plus the latent heat.
Change in Internal Energy - (Measured in Joule) - The Change in Internal Energy of a thermodynamic system is the energy contained within it. It is the energy necessary to create or prepare the system in any given internal state.
STEP 1: Convert Input(s) to Base Unit
Total Heat: 39.4 Kilojoule --> 39400 Joule (Check conversion here)
Change in Internal Energy: 9400 Joule --> 9400 Joule No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
w = H-ΔU --> 39400-9400
Evaluating ... ...
w = 30000
STEP 3: Convert Result to Output's Unit
30000 Joule -->30 Kilojoule (Check conversion here)
FINAL ANSWER
30 Kilojoule <-- Work Done
(Calculation completed in 00.004 seconds)

Credits

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National Institute of Technology (NIT), Warangal
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18 Basic Relationship of Thermodynamics Calculators

Pressure for External Work Done by Gas in Adiabatic Process Introducing Pressure
Go Pressure 2 = -((Work Done*(Heat Capacity Ratio-1))-(Pressure 1*Specific Volume for Point 1))/Specific Volume for Point 2
Specific Volume for External Work Done in Adiabatic Process Introducing Pressure
Go Specific Volume for Point 1 = ((Work Done*(Heat Capacity Ratio-1))+(Pressure 2*Specific Volume for Point 2))/Pressure 1
Constant for External Work Done in Adiabatic process Introducing Pressure
Go Heat Capacity Ratio = ((1/Work Done)*(Pressure 1*Specific Volume for Point 1-Pressure 2*Specific Volume for Point 2))+1
External Work Done by Gas in Adiabatic Process Introducing Pressure
Go Work Done = (1/(Heat Capacity Ratio-1))*(Pressure 1*Specific Volume for Point 1-Pressure 2*Specific Volume for Point 2)
Potential Energy given Total Energy in Compressible Fluids
Go Potential Energy = Total Energy in Compressible Fluids-(Kinetic Energy+Pressure Energy+Molecular Energy)
Molecular Energy given Total Energy in Compressible Fluids
Go Molecular Energy = Total Energy in Compressible Fluids-(Kinetic Energy+Potential Energy+Pressure Energy)
Pressure Energy given Total Energy in Compressible Fluids
Go Pressure Energy = Total Energy in Compressible Fluids-(Kinetic Energy+Potential Energy+Molecular Energy)
Kinetic Energy given Total Energy in Compressible Fluids
Go Kinetic Energy = Total Energy in Compressible Fluids-(Potential Energy+Pressure Energy+Molecular Energy)
Total Energy in Compressible Fluids
Go Total Energy in Compressible Fluids = Kinetic Energy+Potential Energy+Pressure Energy+Molecular Energy
Absolute Temperature given Absolute Pressure
Go Absolute Temperature of Compressible Fluid = Absolute Pressure by Fluid Density/(Mass Density of Gas*Ideal Gas Constant)
Mass Density given Absolute Pressure
Go Mass Density of Gas = Absolute Pressure by Fluid Density/(Ideal Gas Constant*Absolute Temperature of Compressible Fluid)
Gas Constant given Absolute Pressure
Go Ideal Gas Constant = Absolute Pressure by Fluid Density/(Mass Density of Gas*Absolute Temperature of Compressible Fluid)
Absolute Pressure given Absolute Temperature
Go Absolute Pressure by Fluid Density = Mass Density of Gas*Ideal Gas Constant*Absolute Temperature of Compressible Fluid
Continuity Equation for Compressible Fluids
Go Constant A1 = Mass Density of Fluid*Cross-Sectional Area of Flow Channel*Average Velocity
Pressure given Constant
Go Pressure of Compressible Flow = Gas Constant a/Specific Volume
Change in Internal Energy given Total Heat Supplied to Gas
Go Change in Internal Energy = Total Heat-Work Done
External Work Done by Gas given Total Heat Supplied
Go Work Done = Total Heat-Change in Internal Energy
Total Heat Supplied to Gas
Go Total Heat = Change in Internal Energy+Work Done

External Work Done by Gas given Total Heat Supplied Formula

Work Done = Total Heat-Change in Internal Energy
w = H-ΔU

What is meant by Total Heat?

The Total Heat supplied to gas is a thermodynamic quantity equal to the internal energy of a system plus the product of its volume and pressure; "enthalpy is the amount of energy in a system capable of doing mechanical work".

What is meant by External Work?

When work is done by external forces (non-conservative forces), the total mechanical energy of the object is altered. The work that is done can be positive work or negative work depending on whether the force doing the work is directed opposite the object's motion or in the same direction as the object's motion.

How to Calculate External Work Done by Gas given Total Heat Supplied?

External Work Done by Gas given Total Heat Supplied calculator uses Work Done = Total Heat-Change in Internal Energy to calculate the Work Done, External Work Done by Gas given Total Heat Supplied is transferring energy can be in method of force. This quantity of energy transferred by force to move object is termed as work done. Work Done is denoted by w symbol.

How to calculate External Work Done by Gas given Total Heat Supplied using this online calculator? To use this online calculator for External Work Done by Gas given Total Heat Supplied, enter Total Heat (H) & Change in Internal Energy (ΔU) and hit the calculate button. Here is how the External Work Done by Gas given Total Heat Supplied calculation can be explained with given input values -> 0.03 = 39400-9400.

FAQ

What is External Work Done by Gas given Total Heat Supplied?
External Work Done by Gas given Total Heat Supplied is transferring energy can be in method of force. This quantity of energy transferred by force to move object is termed as work done and is represented as w = H-ΔU or Work Done = Total Heat-Change in Internal Energy. Total Heat is the heat contained in the same amount of dry air (known as sensible heat) plus the latent heat & The Change in Internal Energy of a thermodynamic system is the energy contained within it. It is the energy necessary to create or prepare the system in any given internal state.
How to calculate External Work Done by Gas given Total Heat Supplied?
External Work Done by Gas given Total Heat Supplied is transferring energy can be in method of force. This quantity of energy transferred by force to move object is termed as work done is calculated using Work Done = Total Heat-Change in Internal Energy. To calculate External Work Done by Gas given Total Heat Supplied, you need Total Heat (H) & Change in Internal Energy (ΔU). With our tool, you need to enter the respective value for Total Heat & Change in Internal Energy 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 Work Done?
In this formula, Work Done uses Total Heat & Change in Internal Energy. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Work Done = (1/(Heat Capacity Ratio-1))*(Pressure 1*Specific Volume for Point 1-Pressure 2*Specific Volume for Point 2)
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