Shivam Sinha
National Institute Of Technology (NIT), Surathkal
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Pragati Jaju
College Of Engineering (COEP), Pune
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8 Other formulas that you can solve using the same Inputs

Volume expansivity for pumps when enthalpy is given
Volume expansivity=((((Specific Heat Capacity*Overall difference in temperature)-Change in enthalpy)/(Volume*Difference in pressure))+1)/Temperature GO
Actual change in enthalpy when Compressor efficiency and change in enthalpy (isentropic) is given
Change in enthalpy=Change in enthalpy (isentropic)/Compressor efficiency GO
Change in enthalpy (isentropic) when Compressor efficiency and actual change in enthalpy is given
Change in enthalpy (isentropic)=Compressor efficiency*Change in enthalpy GO
change in enthalpy (isentropic) when Turbine efficiency and actual change in enthalpy is given
Change in enthalpy (isentropic)=Change in enthalpy/turbine efficiency GO
Change in enthalpy when Turbine efficiency and actual change in enthalpy (isentropic) is given
Change in enthalpy=turbine efficiency*Change in enthalpy (isentropic) GO
Turbine efficiency when actual and isentropic change in enthalpy is given
turbine efficiency=Change in enthalpy/Change in enthalpy (isentropic) GO
Mass flow rate of a stream in the turbine (expanders)
Mass Flow Rate=Work done rate/Change in enthalpy GO
Work done rate by a turbine (expanders)
Work done rate=Change in enthalpy*Mass Flow Rate GO

1 Other formulas that calculate the same Output

Compressor efficiency when actual and shaft work (isentropic) is given
Compressor efficiency=Shaft work (Isentropic)/Actual shaft work GO

Compressor efficiency when actual and isentropic change in enthalpy is given Formula

Compressor efficiency=Change in enthalpy (isentropic)/Change in enthalpy
η<sub>c</sub>=ΔH<sub>S</sub>/ΔH
More formulas
Overall Efficiency GO
Nozzle Efficiency GO
Shaft power GO
Work done rate by a turbine (expanders) GO
Change in enthalpy in the turbine (expanders) GO
Mass flow rate of a stream in the turbine (expanders) GO
Turbine efficiency when actual and shaft work (isentropic) is given GO
Compressor efficiency when actual and shaft work (isentropic) is given GO
Actual work done when Turbine efficiency and isentropic shaft work is given GO
Work done (isentropic condition) when Turbine efficiency and actual shaft work is given GO
Actual work done when Compressor efficiency and isentropic shaft work is given GO
Work done (isentropic condition) when Compressor efficiency and actual shaft work is given GO
Work done rate (isentropic condition) for adiabatic compression process when Cp is given GO
Work done rate (isentropic condition) for adiabatic compression process when γ is given GO
Enthalpy for pumps when volume expansivity is given for a pump GO
Entropy for pumps when volume expansivity is given for a pump GO
Volume expansivity for pumps when enthalpy is given GO
Volume expansivity for pumps when entropy is given GO
change in enthalpy (isentropic) when Turbine efficiency and actual change in enthalpy is given GO
Change in enthalpy when Turbine efficiency and actual change in enthalpy (isentropic) is given GO
Actual change in enthalpy when Compressor efficiency and change in enthalpy (isentropic) is given GO
Change in enthalpy (isentropic) when Compressor efficiency and actual change in enthalpy is given GO

Working of compressor

The compression of gases may be accomplished in equipment with rotating blades (like a turbine operating in reverse) or in cylinders with reciprocating pistons. Rotary equipment is used for high-volume flow where the discharge pressure is not too high. For high pressures, reciprocating compressors are often required. The energy equations are independent of the type of equipment; indeed, they are the same as for turbines or expanders because here, too, potential and kinetic energy changes are presumed negligible.

How to Calculate Compressor efficiency when actual and isentropic change in enthalpy is given?

Compressor efficiency when actual and isentropic change in enthalpy is given calculator uses Compressor efficiency=Change in enthalpy (isentropic)/Change in enthalpy to calculate the Compressor efficiency, The Compressor efficiency when actual and isentropic change in enthalpy is given formula is defined as the ratio of the change in enthalpy done by the compressor under reversible and adiabatic conditions (which is isentropic condition) to actual change in enthalpy done by the compressor. Compressor efficiency and is denoted by ηc symbol.

How to calculate Compressor efficiency when actual and isentropic change in enthalpy is given using this online calculator? To use this online calculator for Compressor efficiency when actual and isentropic change in enthalpy is given, enter Change in enthalpy (isentropic) (ΔHS) and Change in enthalpy (ΔH) and hit the calculate button. Here is how the Compressor efficiency when actual and isentropic change in enthalpy is given calculation can be explained with given input values -> 1 = 200/200.

FAQ

What is Compressor efficiency when actual and isentropic change in enthalpy is given?
The Compressor efficiency when actual and isentropic change in enthalpy is given formula is defined as the ratio of the change in enthalpy done by the compressor under reversible and adiabatic conditions (which is isentropic condition) to actual change in enthalpy done by the compressor and is represented as ηc=ΔHS/ΔH or Compressor efficiency=Change in enthalpy (isentropic)/Change in enthalpy. Change in enthalpy (isentropic) is the thermodynamic quantity equivalent to the total difference between the heat content of a system under reversible and adiabatic conditions and Change in enthalpy is the thermodynamic quantity equivalent to the total difference between the heat content of a system.
How to calculate Compressor efficiency when actual and isentropic change in enthalpy is given?
The Compressor efficiency when actual and isentropic change in enthalpy is given formula is defined as the ratio of the change in enthalpy done by the compressor under reversible and adiabatic conditions (which is isentropic condition) to actual change in enthalpy done by the compressor is calculated using Compressor efficiency=Change in enthalpy (isentropic)/Change in enthalpy. To calculate Compressor efficiency when actual and isentropic change in enthalpy is given, you need Change in enthalpy (isentropic) (ΔHS) and Change in enthalpy (ΔH). With our tool, you need to enter the respective value for Change in enthalpy (isentropic) and Change in enthalpy 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 Compressor efficiency?
In this formula, Compressor efficiency uses Change in enthalpy (isentropic) and Change in enthalpy. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Compressor efficiency=Shaft work (Isentropic)/Actual shaft work
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