Chiller:Absorption:Indirect
Used in:
- Chilled water loop, supply side
Available in v5.1 and later only
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Used in:
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The Absorption Indirect Chiller is an enhanced version of the absorption chiller model found in the Building Loads and System Thermodynamics (BLAST) program. This enhanced model is nearly identical to the Absorption Chiller model with the exceptions that:
Since these absorption chiller models are nearly identical (i.e., the performance curves of the enhanced model can be manipulated to produce similar results to the Absorption Chiller model), it is quite probable that the Absorption Chiller model will be deprecated in a future release of EnergyPlus.
Note: Absorption Indirect Chillers and their associated performance curve objects are developed using performance information for a specific chiller and should normally be used together for an EnergyPlus simulation. Changing the object input values, or swapping performance curves between chillers, should be done with caution.
The auto-generated name of the chiller can be edited.
Use this browse option to select a chiller from the EnergyPlus chiller database whose performance data you wish to copy to your chiller.
The type of chiller can be one of these options:
Note: The Chiller type cannot be edited directly. To help you to ensure that appropriate performance curves are used, you must either load a new chiller template of the type required or add a new chiller, selecting the appropriate type from the drop list.
This numeric field contains the nominal cooling capability of the chiller (in W or Btu/h).
This numeric field contains the nominal pumping power of the absorber (in W or Btu/h).
This choice field determines how the chiller operates with respect to the intended fluid flow through the device’s evaporator. There are three choices for specifying operating modes for the intended flow behaviour:
In all cases the operation of the external plant system can also impact the flow through the chiller - for example if the relative sizes and operation are such that flow is restricted and the requests cannot be met.
For variable flow chilled water loops these options are available: 2-Leaving setpoint modulated and 3-Not modulated.
For constant flow chilled water loops these options are available: 1-Constant flow and 3-Not modulated.
The type of loop (variable/constant flow) can be changed by modifying the Plant loop flow type on the Chilled water plant loop dialog.
Note: When the 2-Leaving setpoint modulated option is selected then you must add an extra Setpoint manager immediately downstream of the chiller chilled water outlet to define the temperature of the water supplied.
This optional numeric field allows the user to specify a sizing factor for this component. The sizing factor is used when the component design inputs are autosized: the autosizing calculations are performed as usual and the results are multiplied by the sizing factor. For this component the inputs that would be altered by the sizing factor are: Nominal Capacity, Nominal Pumping Power, Design Chilled Water Flow Rate, Design Condenser Water Flow Rate and Design Generator Fluid Flow Rate. Sizing factor allows the user to size a component to meet part of the design load while continuing to use the autosizing feature.
The condenser type determines what type of condenser will be included with this chiller. Valid condenser types are:
The default is 2-Water cooled which requires the full specification of the Condenser loop and its associated equipment. 1-Air cooled and 3-Evaporatively cooled do not require a Condenser loop to be specified.
Note: Condenser type cannot be edited directly. To help you to ensure that appropriate performance curves are used, load a chiller of the correct type from the Chiller template.
This numeric field contains the chiller’s condenser inlet design temperature (in °C or °F). The default value for this field is 30º C and is only used when the Design chilled water flow rate is autosized.
This numeric field contains the chiller’s lower limit for the condenser entering water temperature (in °C or °F). The default value for this field is 15º C. If this limit is exceeded, a warning message will report the incident. No correction to chiller capacity is made for low condenser entering water temperatures.
This numeric field contains the chiller’s lower limit for the evaporator leaving water temperature (in °C or °F). The default value for this field is 5º C. If this limit is exceeded, a warning message will report the incident. No correction to chiller capacity is made for low evaporator leaving water temperatures.
This numeric field specifies the lower limit of the generator’s entering water temperature (in °C or °F).
For variable volume chiller this is the maximum flow and for constant flow chiller this is the design flow rate. The units are m3/s or gal/min.
This numeric field contains the absorption chiller’s design condenser water flow rate (in m3/s or gal/min).
This numeric field contains the absorption chiller’s minimum part load ratio. The expected range is between 0 and 1. The minimum part load is not the load where the machine shuts off, but where the amount of power remains constant to produce smaller loads than this fraction.
This numeric field contains the absorption chiller’s maximum part load ratio. This value may exceed 1, but the normal range is between 0 and 1.1.
This numeric field contains the absorption chiller’s optimum part load ratio. This is the part load ratio at which the chiller performs at its maximum COP.
Select the quadratic or cubic curve which characterizes the heat input as a function of chiller part-load ratio. The curve output is multiplied by the chiller’s nominal capacity and operating part-load ratio or minimum part-load ratio, whichever is greater, to determine the amount of heat input required for the given operating conditons.
Select the quadratic or cubic curve which characterizes the pump electrical power as a function of chiller part-load ratio. The curve output is multiplied by the chiller’s nominal pumping power and operating part-load ratio or minimum part-load ratio, whichever is greater, to determine the amount of pumping power required for the given operating conditions.
Check this option if you would to model the chiller’s evaporator capacity as a function of condenser entering water temperature.
Capacity correction function of condenser temperature curve
Select the quadratic or cubic curve which correlates the chiller’s evaporator capacity as a function of condenser entering water temperature. This curve is used to correct nominal capacity at off-design condensing temperatures.
Check this option if you would like to correlate the chiller’s evaporator capacity as a function of evaporator leaving water temperature.
Capacity correction function of chilled water temperature curve
Select the quadratic or cubic curve which correlates the chiller’s evaporator capacity as a function of evaporator leaving water temperature. This curve is used to correct nominal capacity at off-design evaporator temperatures.
Check this option if you would like to correlate the chiller’s heat input as a function of condenser entering water temperature.
Generator heat input correction function of condenser temperature
Select the quadratic or cubic curve which correlates the chiller’s heat input as a function of condenser entering water temperature. This curve is used to correct generator heat input at off-design condensing temperatures.
Check this option if you would like to correlate the chiller’s heat input as a function of evaporator leaving water temperature.
Generator heat input correction function of chilled water temperature
Select the quadratic or cubic curve which correlates the chiller’s heat input as a function of evaporator leaving water temperature. This curve is used to correct generator heat input at off-design evaporator temperatures.
Check this checkbox if there is a hot water plant connection.
This numeric field contains the absorption chiller’s design condenser fluid flow rate (m3/s or gal/min).
Checking this option allows you to correlate the chiller’s evaporator capacity as a function of generator entering water temperature.
Capacity correction function of generator temperature curve
Select the quadratic or cubic curve which correlates the chiller’s evaporator capacity as a function of generator entering water temperature. This curve is used to correct nominal capacity at off-design evaporator temperatures.