Anirudh Singh
National Institute of Technology (NIT), Jamshedpur
Anirudh Singh has created this Calculator and 300+ more calculators!
Saiju Shah
Jayawant Shikshan Prasarak Mandal (JSPM), Pune
Saiju Shah has verified this Calculator and 1000+ more calculators!

11 Other formulas that you can solve using the same Inputs

Theoretical Coefficient of Performance of a refrigerator
Theoretical Coefficient of Performance=Heat Extracted from Refrigerator/Work GO
Cooled Compressor Efficiency
Cooled Compressor Efficiency=Kinetic Energy/Work GO
Specific heat
Specific heat=Heat*(Mass*Temperature Difference) GO
Thermal Efficiency of Heat Engine
thermal efficiency of heat engine=Work /Heat GO
Mean Effective Pressure
mean effective pressure=Work /Displacement GO
Compressor Efficiency
Compressor efficiency=Kinetic Energy/Work GO
Turbine Efficiency
turbine efficiency=Work /Kinetic Energy GO
Real Refrigerator
Real Refrigerator=heat lower /Work GO
Real Heat Engine
real heat engine=Work /Heat GO
Latent heat
latent heat=Heat/Mass GO
performance of heat pump
heat pump=Heat/Work GO

Real Heat Pump Formula

real heat pump=Heat/Work
RHP=Q/W
More formulas
Temperature After a Given Time GO
Mean Effective Pressure GO
Otto Cycle Efficiency GO
Degree of Saturation GO
Dew Point Depression GO
By Pass Factor GO
Carnot Cycle of Heat Engine GO
Absolute Humidity GO
Volumetric Efficiency GO
Partial pressure of Water Vapour GO
Diesel Efficiency GO
Indicated Thermal Efficiency GO
Brake Thermal Efficiency GO
Ranking Cycle Efficiency GO
Brayton Cycle Efficiency GO
Real Heat Engine GO
Thermal Efficiency of Heat Engine GO
performance of heat pump GO
work of heat pump GO
Carnot Cycle of Heat Pump GO
Overall Efficiency GO
Sensible Heat Factor GO
Coefficient of Performance of absorption system GO
Refrigerator Work GO
Coefficient of Performance of Refrigerator GO
Carnot Cycle of Refrigerator GO
Real Refrigerator GO
Absolute Temperature GO
Turbine Efficiency GO
Compressor Efficiency GO
Cooled Compressor Efficiency GO
Nozzle Efficiency GO
Work done in an isobaric process GO
Relative Density GO
Density Of Two Liquids GO
Entropy Balance Equation GO
Specific Entropy GO
Air Fuel Ratio GO
Compressibility Factor GO
Reduced Temperature GO
Reduced Pressure GO
Pseudo-Reduced Specific volume GO
Degree Of Freedom GO
Helmholtz free energy GO
RMS speed GO
Average speed of gases GO
Most probable speed GO
Equipartition energy GO
Equipartition energy for molecule having n degrees of freedom GO
Molar internal energy of an ideal gas GO
Thermal efficiency given Mechanical energy GO
Thermal efficiency given Waste energy GO
Thermal efficiency of a Carnot engine GO
Coefficient of Performance of Refrigerator given the heat in the cold and hot reservoir GO
Coefficient of Performance of Heat Pump given the heat in the cold and hot reservoir GO
Coefficient of Performance of Heat Pump given work and heat in the cold reservoir GO
Coefficient of Performance of Refrigerator given work and heat in the cold reservoir GO
Change in momentum GO
Change in kinetic energy GO
Change in potential energy GO
Stefan–Boltzmann law GO
Newton's law of cooling GO
Pressure GO
Specific heat GO
Ratio of specific heat GO
Entropy change at constant volume GO
Entropy change at constant pressure GO
Entropy change variable specific heat GO
Specific heat ratio GO
Specific Heat of Gas Mixture GO
Molar Internal Energy of an Ideal Gas GO
Work Done in Isobaric Process GO
Ideal Gas Law for Calculating Volume GO
Ideal Gas Law for Calculating Pressure GO
Specific Gas Constant GO
Pressure Ratio in Isentropic Process GO
Temperature Ratio When Isentropic Pressure is Given GO
Temperature Ratio when Isentropic Specific Volume is Given GO
Isentropic Pressure at point 2 GO
Isentropic Pressure at point 1 GO
Isentropic temperature 2 given pressure ratio GO
Isentropic temperature 1 given pressure ratio GO
Isentropic temperature 1 given specific volume GO
Isentropic temperature 2 given specific volume GO
Relative Humidity GO
Specific Humidity GO
Vapour Quality GO
Saturated Mixture Specific Enthalpy GO
Isobaric work GO
Polytropic work GO
Isothermal work given volume ratio GO
Isothermal work given pressure ratio GO
Isothermal work given temperature GO
Shaft power GO
Spring work GO
Van der Waals equation GO
Irreversibility GO
Isothermal Work Done by the gas GO
Latent heat GO
Specific heat at constant volume GO
Isothermal Compression Of An Ideal Gas GO
Thermal stress of a material GO
Thermal Expansion GO
Internal Energy When Helmholtz Free Energy Is Given GO
Temperature When Helmholtz free Energy is Given GO
Entropy When Helmholtz Free Energy is Given GO
Temperature Of The Gas When RMS Velocity Of The Gas Is Given GO
Molar Mass Of The Gas When RMS Velocity Of The Gas Is Given GO
Temperature Of The Gas When Average Speed Of Gas Is Given GO
Molar Mass of the Gas When Average Speed of the Gas is Given GO
Temperature of the Gas When Most Probable Speed of Gas is Given GO
Molar Mass of the Gas When Most Probable Speed of the Gas is Given GO
Temperature of the Gas When Equipartition energy is Given GO
Temperature Of The Gas When Equipartition energy for molecule is Given GO
Degree of Freedom When Equipartition Energy is Given GO
Temperature of Ideal Gas When Internal Energy of the Ideal Gas is Given GO
Number of Moles When Internal Energy of Ideal Gas is Given GO
Degree of Freedom When Molar Internal Energy Of An Ideal Gas is Given GO

How does a Heat pump work?

Heat pumps move thermal energy in the opposite direction of spontaneous heat transfer, by absorbing heat from a cold space and releasing it to a warmer one.

How to Calculate Real Heat Pump?

Real Heat Pump calculator uses real heat pump=Heat/Work to calculate the real heat pump, Real Heat Pump is ratio of heat supplied to work done by pump. real heat pump and is denoted by RHP symbol.

How to calculate Real Heat Pump using this online calculator? To use this online calculator for Real Heat Pump, enter Heat (Q) and Work (W) and hit the calculate button. Here is how the Real Heat Pump calculation can be explained with given input values -> 0.003333 = 1/300.

FAQ

What is Real Heat Pump?
Real Heat Pump is ratio of heat supplied to work done by pump and is represented as RHP=Q/W or real heat pump=Heat/Work . Heat is the form of energy that is transferred between systems or objects with different temperatures (flowing from the high-temperature system to the low-temperature system). Also referred to as heat energy or thermal energy. Heat is typically measured in Btu, calories or joules and Work is done when a force that is applied to an object moves that object.
How to calculate Real Heat Pump?
Real Heat Pump is ratio of heat supplied to work done by pump is calculated using real heat pump=Heat/Work . To calculate Real Heat Pump, you need Heat (Q) and Work (W). With our tool, you need to enter the respective value for Heat and Work 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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