Work done by Compressor given Load on Condenser Calculator

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Heat Transfer

Air Conditioning Systems

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Enthalpy of Saturated Air

Psychrometry

Refrigerant Compressors

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Heat Transfer in Condenser

✖The Load on condenser is the amount of heat that must be removed from the inlet stream to attain the specified removal efficiency.ⓘ Load on Condenser [Q_C]			+10% -10%
✖Refrigeration capacity is a measure of the effective cooling capacity of a refrigerator.ⓘ Refrigeration Capacity [R_E]			+10% -10%

✖Compressor work done is the work done by the compressor.ⓘ Work done by Compressor given Load on Condenser [W]

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Formula

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Work done by Compressor given Load on Condenser

Formula

`"W" = "Q"_{"C"}-"R"_{"E"}`

Example

`"600J/min"="1600J/min"-"1000J/min"`

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Work done by Compressor given Load on Condenser Solution

STEP 0: Pre-Calculation Summary

Formula Used

Compressor work done = Load on Condenser-Refrigeration Capacity
W = Q_C-R_E
This formula uses 3 Variables

Variables Used

Compressor work done - (Measured in Joule per Second) - Compressor work done is the work done by the compressor.
Load on Condenser - (Measured in Joule per Second) - The Load on condenser is the amount of heat that must be removed from the inlet stream to attain the specified removal efficiency.
Refrigeration Capacity - (Measured in Joule per Second) - Refrigeration capacity is a measure of the effective cooling capacity of a refrigerator.

STEP 1: Convert Input(s) to Base Unit

Load on Condenser: 1600 Joule per Minute --> 26.6666666666667 Joule per Second (Check conversion here)
Refrigeration Capacity: 1000 Joule per Minute --> 16.6666666666667 Joule per Second (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

W = Q_C-R_E --> 26.6666666666667-16.6666666666667

Evaluating ... ...

W = 10

STEP 3: Convert Result to Output's Unit

10 Joule per Second -->600 Joule per Minute (Check conversion here)

FINAL ANSWER

600 Joule per Minute <-- Compressor work done

(Calculation completed in 00.004 seconds)

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Created by Abhishek Dharmendra Bansile

Vishwakarma Institute of Information Technology, Pune (VIIT Pune), Pune

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< 21 Heat Transfer Calculators

Average Coefficient of heat transfer for vapour condensing outside of horizontal tubes of diameter D

Go Average Heat Transfer Coefficient = 0.725*(((Thermal Conductivity^3)*(Density of Liquid Condensate^2)*Acceleration due to Gravity*Latent Heat of Vaporization)/(Number of Tubes*Diameter of Tube*Viscosity of Film*Temperature Difference))^(1/4)

Overall Coefficient of Heat Transfer for Condensation on Vertical Surface

Go Overall Heat Transfer Coefficient = 0.943*(((Thermal Conductivity^3)*(Density of Liquid Condensate-Density)*Acceleration due to Gravity*Latent Heat of Vaporization)/(Viscosity of Film*Height Of Surface*Temperature Difference))^(1/4)

Mean Surface area of Tube when Heat transfer takes place from outside to inside surface of tube

Go Surface Area = (Heat Transfer*Tube Thickness)/(Thermal Conductivity*(Outside Surface Temperature-Inside Surface temperature))

Temperature at Outside Surface of Tube given Heat Transfer

Go Outside Surface Temperature = ((Heat Transfer*Tube Thickness)/(Thermal Conductivity*Surface Area))+Inside Surface temperature

Temperature at Inside Surface of Tube given Heat Transfer

Go Inside Surface temperature = Outside Surface Temperature+((Heat Transfer*Tube Thickness)/(Thermal Conductivity*Surface Area))

Thickness of Tube when Heat transfer takes places from outside to inside surface of tube

Go Tube Thickness = (Thermal Conductivity*Surface Area*(Outside Surface Temperature-Inside Surface temperature))/Heat Transfer

Heat transfer takes place from outside surface to inside surface of tube

Go Heat Transfer = (Thermal Conductivity*Surface Area*(Outside Surface Temperature-Inside Surface temperature))/Tube Thickness

Temperature of Refrigerant Vapour condensing Film given Heat Transfer

Go Vapour condensing film temperature = (Heat Transfer/(Heat Transfer Coefficient*Area))+Outside Surface Temperature

Temperature at Outside Surface of Tube provided Heat Transfer

Go Outside Surface Temperature = Vapour condensing film temperature-(Heat Transfer/(Heat Transfer Coefficient*Area))

Heat Transfer takes place from vapour refrigerant to outside of tube

Go Heat Transfer = Heat Transfer Coefficient*Area*(Vapour condensing film temperature-Outside Surface Temperature)

Overall Temperature difference when Heat transfer takes place from outside to inside surface of tube

Go Overall Temperature Difference = (Heat Transfer*Tube Thickness)/(Thermal Conductivity*Surface Area)

Heat Rejection Factor

Go Heat Rejection Factor = (Refrigeration Capacity+Compressor work done)/Refrigeration Capacity

Heat Transfer in Condenser given Overall Heat Transfer Coefficient

Go Heat Transfer = Overall Heat Transfer Coefficient*Surface Area*Temperature Difference

Overall Temperature difference when Heat Transfer from vapour refrigerant to outside of tube

Go Overall Temperature Difference = Heat Transfer/(Heat Transfer Coefficient*Area)

Overall Temperature difference given Heat Transfer

Go Overall Temperature Difference = Heat Transfer*Thermal Resistance

Overall thermal resistance in condenser

Go Thermal Resistance = Overall Temperature Difference/Heat Transfer

Work done by Compressor given Load on Condenser

Go Compressor work done = Load on Condenser-Refrigeration Capacity

Refrigeration Capacity given Load on Condenser

Go Refrigeration Capacity = Load on Condenser-Compressor work done

Load on Condenser

Go Load on Condenser = Refrigeration Capacity+Compressor work done

Heat Transfer in Condenser given Overall Thermal Resistance

Go Heat Transfer = Temperature Difference/Thermal Resistance

Heat Rejection Factor given COP

Go Heat Rejection Factor = 1+(1/Coefficient of Performance of Refrigerator)

Work done by Compressor given Load on Condenser Formula

Compressor work done = Load on Condenser-Refrigeration Capacity
W = Q_C-R_E

What is the function of a condenser?

There are three very important functions the condenser performs in keeping your air conditioner performing its best. These include rejecting superheated refrigerant gas, condensation, and subcooling refrigerant once it is transformed back into a liquid state.

How to Calculate Work done by Compressor given Load on Condenser?

Work done by Compressor given Load on Condenser calculator uses Compressor work done = Load on Condenser-Refrigeration Capacity to calculate the Compressor work done, The Work done by Compressor given Load on Condenser formula is defined as the work done by the compressor and it is obtained by subtracting refrigeration capacity from the load on the condenser. Compressor work done is denoted by W symbol.

How to calculate Work done by Compressor given Load on Condenser using this online calculator? To use this online calculator for Work done by Compressor given Load on Condenser, enter Load on Condenser (Q_C) & Refrigeration Capacity (R_E) and hit the calculate button. Here is how the Work done by Compressor given Load on Condenser calculation can be explained with given input values -> 36000 = 26.6666666666667-16.6666666666667.

FAQ

What is Work done by Compressor given Load on Condenser?

The Work done by Compressor given Load on Condenser formula is defined as the work done by the compressor and it is obtained by subtracting refrigeration capacity from the load on the condenser and is represented as W = Q_C-R_E or Compressor work done = Load on Condenser-Refrigeration Capacity. The Load on condenser is the amount of heat that must be removed from the inlet stream to attain the specified removal efficiency & Refrigeration capacity is a measure of the effective cooling capacity of a refrigerator.

How to calculate Work done by Compressor given Load on Condenser?

The Work done by Compressor given Load on Condenser formula is defined as the work done by the compressor and it is obtained by subtracting refrigeration capacity from the load on the condenser is calculated using Compressor work done = Load on Condenser-Refrigeration Capacity. To calculate Work done by Compressor given Load on Condenser, you need Load on Condenser (Q_C) & Refrigeration Capacity (R_E). With our tool, you need to enter the respective value for Load on Condenser & Refrigeration Capacity 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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