Thermodynamic Efficiency using Work Required Calculator

✖Ideal Work is defined as the maximum work obtained when the processes are mechanically reversible.ⓘ Ideal Work [W_ideal]			+10% -10%
✖Actual Work Done in Thermodynamic Process is defined as the work done by the system or on the system considering all conditions.ⓘ Actual Work Done in Thermodynamic Process [W_Actual]			+10% -10%

✖Thermodynamic Efficiency using Work Required is defined as the ratio of desired output to required input.ⓘ Thermodynamic Efficiency using Work Required [η_{tworkrequired}]

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Formula

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Thermodynamic Efficiency using Work Required

Formula

`"η"_{"tworkrequired"} = "W"_{"ideal"}/"W"_{"Actual"}`

Example

`"0.5"="105J"/"210J"`

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Thermodynamic Efficiency using Work Required Solution

STEP 0: Pre-Calculation Summary

Formula Used

Thermodynamic Efficiency using Work Required = Ideal Work/Actual Work Done in Thermodynamic Process
η_{tworkrequired} = W_ideal/W_Actual
This formula uses 3 Variables

Variables Used

Thermodynamic Efficiency using Work Required - Thermodynamic Efficiency using Work Required is defined as the ratio of desired output to required input.
Ideal Work - (Measured in Joule) - Ideal Work is defined as the maximum work obtained when the processes are mechanically reversible.
Actual Work Done in Thermodynamic Process - (Measured in Joule) - Actual Work Done in Thermodynamic Process is defined as the work done by the system or on the system considering all conditions.

STEP 1: Convert Input(s) to Base Unit

Ideal Work: 105 Joule --> 105 Joule No Conversion Required
Actual Work Done in Thermodynamic Process: 210 Joule --> 210 Joule No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

η_{tworkrequired} = W_ideal/W_Actual --> 105/210

Evaluating ... ...

η_{tworkrequired} = 0.5

STEP 3: Convert Result to Output's Unit

0.5 --> No Conversion Required

FINAL ANSWER

0.5 <-- Thermodynamic Efficiency using Work Required

(Calculation completed in 00.004 seconds)

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Created by Shivam Sinha

National Institute Of Technology (NIT), Surathkal

Shivam Sinha has created this Calculator and 300+ more calculators!

Verified by Pragati Jaju

College Of Engineering (COEP), Pune

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< 16 Laws of Thermodynamics their Applications and other Basic Concepts Calculators

Thermodynamic Efficiency using Work Produced

Go Thermodynamic Efficiency using Work Produced = Actual Work Done Condition Work is Produced/Ideal Work for Produced

Ideal Work using Thermodynamic Efficiency and Condition is Work is Required

Go Ideal Work Condition Work is Required = Thermodynamic Efficiency*Actual Work Done in Thermodynamic Process

Ideal Work using Thermodynamic Efficiency and Condition is Work is Produced

Go Ideal Work Condition Work is Produced = Actual Work Done in Thermodynamic Process/Thermodynamic Efficiency

Internal Energy using First Law of Thermodynamics

Go Change in Internal Energy = Heat Transferred in Thermodynamic Process+Work done in Thermodynamic Process

Work using First Law of Thermodynamics

Go Work done in Thermodynamic Process = Change in Internal Energy-Heat Transferred in Thermodynamic Process

Heat using First Law of Thermodynamics

Go Heat Transferred in Thermodynamic Process = Change in Internal Energy-Work done in Thermodynamic Process

Thermodynamic Efficiency using Work Required

Go Thermodynamic Efficiency using Work Required = Ideal Work/Actual Work Done in Thermodynamic Process

Turbine Efficiency using Actual and Isentropic Change in Enthalpy

Go Turbine Efficiency = Change in Enthalpy in a Thermodynamic Process/Change in Enthalpy (Isentropic)

Actual Work Produced by Utilizing Thermodynamic Efficiency and Conditions

Go Actual Work Done Condition Work is Produced = Thermodynamic Efficiency*Ideal Work for Produced

Actual Work using Thermodynamic Efficiency and Condition is Work is Required

Go Actual Work Done Condition Work is Required = Ideal Work/Thermodynamic Efficiency

Lost Work using Ideal and Actual Work

Go Lost Work = Actual Work Done in Thermodynamic Process-Ideal Work

Ideal Work using Lost and Actual Work

Go Ideal Work = Actual Work Done in Thermodynamic Process-Lost Work

Actual Work using Ideal and Lost Work

Go Actual Work Done in Thermodynamic Process = Ideal Work+Lost Work

Rate of Ideal Work using Rates of Lost and Actual Work

Go Rate of Ideal Work = Rate of Actual Work-Rate of Lost Work

Rate of Actual Work using Rates of Ideal and Lost Work

Go Rate of Actual Work = Rate of Ideal Work+Rate of Lost Work

Rate of Lost Work using Rates of Ideal and Actual Work

Go Rate of Lost Work = Rate of Actual Work-Rate of Ideal Work

Thermodynamic Efficiency using Work Required Formula

Thermodynamic Efficiency using Work Required = Ideal Work/Actual Work Done in Thermodynamic Process
η_{tworkrequired} = W_ideal/W_Actual

Define Thermodynamic Efficiency.

Thermodynamic efficiency is defined as the ratio of work output to heat-energy input in a heat-engine cycle or of heat energy removal to work input in a refrigeration cycle. In thermodynamics, thermal efficiency is a dimensionless performance measure of a device that uses thermal energy, such as an internal combustion engine, a steam turbine or a steam engine, a boiler, furnace, or a refrigerator for example. For a heat engine, thermal efficiency is the fraction of the energy added by heat (primary energy) that is converted to net work output (secondary energy). In the case of a refrigeration or heat pump cycle, thermal efficiency is the ratio of net heat output for heating, or removal for cooling, to energy input (the coefficient of performance).

What is First Law of Thermodynamics?

In a closed system undergoing a thermodynamic cycle, cyclic integral of heat and cyclic integral of work are proportional to each other when expressed in their own units and are equal to each other when expressed in the consistent(same) units.

How to Calculate Thermodynamic Efficiency using Work Required?

Thermodynamic Efficiency using Work Required calculator uses Thermodynamic Efficiency using Work Required = Ideal Work/Actual Work Done in Thermodynamic Process to calculate the Thermodynamic Efficiency using Work Required, The Thermodynamic Efficiency using Work Required formula is defined as the ratio of the ideal work to the actual work when ideal work is positive meaning the work is required. Thermodynamic Efficiency using Work Required is denoted by η_{tworkrequired} symbol.

How to calculate Thermodynamic Efficiency using Work Required using this online calculator? To use this online calculator for Thermodynamic Efficiency using Work Required, enter Ideal Work (W_ideal) & Actual Work Done in Thermodynamic Process (W_Actual) and hit the calculate button. Here is how the Thermodynamic Efficiency using Work Required calculation can be explained with given input values -> 0.5 = 105/210.

FAQ

What is Thermodynamic Efficiency using Work Required?

The Thermodynamic Efficiency using Work Required formula is defined as the ratio of the ideal work to the actual work when ideal work is positive meaning the work is required and is represented as η_{tworkrequired} = W_ideal/W_Actual or Thermodynamic Efficiency using Work Required = Ideal Work/Actual Work Done in Thermodynamic Process. Ideal Work is defined as the maximum work obtained when the processes are mechanically reversible & Actual Work Done in Thermodynamic Process is defined as the work done by the system or on the system considering all conditions.

How to calculate Thermodynamic Efficiency using Work Required?

The Thermodynamic Efficiency using Work Required formula is defined as the ratio of the ideal work to the actual work when ideal work is positive meaning the work is required is calculated using Thermodynamic Efficiency using Work Required = Ideal Work/Actual Work Done in Thermodynamic Process. To calculate Thermodynamic Efficiency using Work Required, you need Ideal Work (W_ideal) & Actual Work Done in Thermodynamic Process (W_Actual). With our tool, you need to enter the respective value for Ideal Work & Actual Work Done in Thermodynamic Process 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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