.BuildSysPro.IBPSA.Fluid.HeatPumps.ScrollWaterToWater

Information

Model for a water to water heat pump with a scroll compressor, as described in Jin (2002). The thermodynamic heat pump cycle is represented below.

image

The rate of heat transferred to the evaporator is given by:

Eva = ṁref ( hVap(TEva) - hLiq(TCon) ).

The power consumed by the compressor is given by a linear efficiency relation:

P = PTheoretical / η + PLoss,constant.

Heat transfer in the evaporator and condenser is calculated using an ε-NTU method, assuming constant refrigerant temperature and constant heat transfer coefficient between fluid and refrigerant.

Variable speed is achieved by multiplying the full load suction volume flow rate by the normalized compressor speed. The power and heat transfer rates are forced to zero if the resulting heat pump state has higher evaporating pressure than condensing pressure.

The model parameters are obtained by calibration of the heat pump model to manufacturer performance data. Calibrated model parameters for various heat pumps from different manufacturers are found in IBPSA.Fluid.HeatPumps.Data.ScrollWaterToWater. The calibrated model is located in IBPSA.Fluid.HeatPumps.Calibration.ScrollWaterToWater.

Options

Parameters TConMax and TEvaMin may be used to set an upper or lower bound for the condenser and evaporator. The compressor is disabled when these conditions are not satisfied, or when the evaporator temperature is larger than the condenser temperature. This mimics the temperature protection of heat pumps and moreover it avoids non-converging algebraic loops of equations, or freezing of evaporator medium. This option can be disabled by setting enable_temperature_protection = false.

Assumptions and limitations

The compression process is assumed isentropic. The thermal energy of superheating is ignored in the evaluation of the heat transferred to the refrigerant in the evaporator. There is no supercooling.

References

H. Jin. Parameter estimation based models of water source heat pumps. PhD Thesis. Oklahoma State University. Stillwater, Oklahoma, USA. 2002.

Revisions


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