Ishan Gupta
Birla Institute of Technology & Science (BITS), Pilani
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Saiju Shah
Jayawant Shikshan Prasarak Mandal (JSPM), Pune
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11 Other formulas that you can solve using the same Inputs

Radial Heat flowing through a cylinder
Heat=(Thermal Conductivity*2*pi*(outer radius-inner radius)*Temperature Difference*length of cylinder)/((ln(outer radius/inner radius))*(outer radius-inner radius)) Go
Heat Transfer According to Fourier's Law
Heat Rate=-(conductivity*Area Perpendicular to Heat Flow*(Temperature Difference/Thickness of Solid Body)) Go
Change in Internal Energy of the system
Internal Energy=Number of Moles*Molar Specific Heat Capacity at Constant Volume*Temperature Difference Go
Enthalpy of the system
Enthalpy=Number of Moles*Molar Specific Heat Capacity at Constant Pressure*Temperature Difference Go
Heat Transfer in an Isobaric Process
Heat=Number of Moles*Molar Specific Heat Capacity at Constant Pressure*Temperature Difference Go
Isothermal Work Done by the gas
Isothermal Work=Number of Moles*[R]*Temperature*2.303*log10(Volume of gas 2/Volume of gas 1) Go
Heat Transfer in an Isochoric Process
Heat=Number of Moles*Molar Specific Heat Capacity at Constant Volume*Temperature Difference Go
Partial pressure of Water Vapour
partial pressure=Pressure of Gas*1.8*Atmospheric Pressure*Temperature Difference/2700 Go
Molar internal energy of an ideal gas
Internal Energy=(Degree of Freedom*Number of Moles*[BoltZ]*Temperature of Gas)/2 Go
Heat Rate
Heat Rate=Steam Flow*Specific Heat Capacity*Temperature Difference Go
Specific heat
Specific heat=Heat*(Mass*Temperature Difference) Go

11 Other formulas that calculate the same Output

Work done in adiabatic process
Work =(Initial Pressure of System*Initial Volume of System-Final Pressure of System*Final Volume of System)/(Molar Specific Heat Capacity at Constant Pressure/Molar Specific Heat Capacity at Constant Volume-1) Go
Expansion Work
Work =Mass of air*Specific Heat Capacity at Constant Pressure*(Temperature at the end of cooling process-Actual temperature at end of isentropic expansion) Go
Compression Work
Work =Mass of air*Specific Heat Capacity at Constant Pressure*(Actual end temp of isentropic compression-Actual temperature of Rammed Air) Go
Work done in one revolution for belt transmission dynamometer
Work =(Tensions in the tight side of belt-Tensions in the slack side of belt)*pi*Diameter of the driving pulley Go
Work done per revolution for rope brake dynamometer
Work =(Dead load-Spring balance reading)*pi*(Diameter of the wheel+diameter of rope) Go
Work done in isothermal process (using pressure)
Work =[R]*Temperature of Gas*ln(Initial Pressure of System/Final Pressure of System) Go
Work done in isothermal process (using volume)
Work =[R]*Temperature of Gas*ln(Final Volume of System/Initial Volume of System) Go
Work done in adiabatic process
Work =(Mass of Gas*[R]*(Initial Temp.-Final Temp.))/(Heat Capacity Ratio-1) Go
Work Done for Punching a Hole
Work =Shear Force*Thickness of the material to be punched Go
Work
Work =Force*Displacement*cos(Angle A) Go
Work done in one revolution for prony brake dynamometer
Work =Torque*2*pi Go

Work done in an isobaric process Formula

Work =Number of Moles*[R]*Temperature Difference
W=n*[R]*dT
More formulas
Heat Transfer in an Isochoric Process Go
Change in Internal Energy of the system Go
Enthalpy of the system Go
Specific Heat Capacity at Constant Pressure Go
Specific Heat Capacity at Constant Volume Go
Heat Transfer in an Isobaric Process Go
Work done in isothermal process (using pressure) Go
Work done in isothermal process (using volume) Go
Heat transferred in isothermal process (using pressure) Go
Heat transferred in isothermal process (using volume) Go
Work done in adiabatic process Go
Adiabatic Index Go
Final Temperature in Adiabatic Process (using volume) Go
Final Temperature in Adiabatic Process (using pressure) Go
Ideal Gas Law for Calculating Volume Go
Ideal Gas Law for Calculating Pressure Go
Relative Humidity Go
Mole fraction of a dissolved gas using Henry Law Go
Henry law constant when mole fraction and partial pressure of gas is given in Henry Law Go
Partial pressure using Henry Law Go

What is Work done in an isobaric process?

Work done in an isobaric process is the amount of work done in bringing the thermodynamic system from its initial to final state using an isobaric process.

How to Calculate Work done in an isobaric process?

Work done in an isobaric process calculator uses Work =Number of Moles*[R]*Temperature Difference to calculate the Work , Work done in an isobaric process is the amount of work done in bringing the thermodynamic system from its initial to final state using an isobaric process. Work and is denoted by W symbol.

How to calculate Work done in an isobaric process using this online calculator? To use this online calculator for Work done in an isobaric process, enter Number of Moles (n) and Temperature Difference (dT) and hit the calculate button. Here is how the Work done in an isobaric process calculation can be explained with given input values -> 166.2893 = 1*[R]*20.

FAQ

What is Work done in an isobaric process?
Work done in an isobaric process is the amount of work done in bringing the thermodynamic system from its initial to final state using an isobaric process and is represented as W=n*[R]*dT or Work =Number of Moles*[R]*Temperature Difference. Number of Moles is the amount of gas present in moles. 1 mole of gas weighs as much as its molecular weight and Temperature Difference is the measure of the hotness or the coldness of an object.
How to calculate Work done in an isobaric process?
Work done in an isobaric process is the amount of work done in bringing the thermodynamic system from its initial to final state using an isobaric process is calculated using Work =Number of Moles*[R]*Temperature Difference. To calculate Work done in an isobaric process, you need Number of Moles (n) and Temperature Difference (dT). With our tool, you need to enter the respective value for Number of Moles and Temperature Difference 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 ?
In this formula, Work uses Number of Moles and Temperature Difference. We can use 11 other way(s) to calculate the same, which is/are as follows -
  • Work =Force*Displacement*cos(Angle A)
  • Work =[R]*Temperature of Gas*ln(Initial Pressure of System/Final Pressure of System)
  • Work =[R]*Temperature of Gas*ln(Final Volume of System/Initial Volume of System)
  • Work =(Initial Pressure of System*Initial Volume of System-Final Pressure of System*Final Volume of System)/(Molar Specific Heat Capacity at Constant Pressure/Molar Specific Heat Capacity at Constant Volume-1)
  • Work =Shear Force*Thickness of the material to be punched
  • Work =(Mass of Gas*[R]*(Initial Temp.-Final Temp.))/(Heat Capacity Ratio-1)
  • Work =Torque*2*pi
  • Work =(Dead load-Spring balance reading)*pi*(Diameter of the wheel+diameter of rope)
  • Work =(Tensions in the tight side of belt-Tensions in the slack side of belt)*pi*Diameter of the driving pulley
  • Work =Mass of air*Specific Heat Capacity at Constant Pressure*(Actual end temp of isentropic compression-Actual temperature of Rammed Air)
  • Work =Mass of air*Specific Heat Capacity at Constant Pressure*(Temperature at the end of cooling process-Actual temperature at end of isentropic expansion)
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