.Buildings.Obsolete.ThermalZones.EnergyPlus_9_6_0.Examples.SingleFamilyHouse.RadiantHeatingCooling_TRoom .Buildings.Obsolete.ThermalZones.EnergyPlus_9_6_0.Examples.SingleFamilyHouse.RadiantHeatingCooling_TRoomModel that uses EnergyPlus for the simulation of a building with one thermal zone that has a radiant ceiling, used for cooling, and a radiant floor, used for heating. The EnergyPlus model has one conditioned zone that is above ground. This conditioned zone has an unconditioned attic. The model is constructed by extending Buildings.Obsolete.ThermalZones.EnergyPlus_9_6_0.Examples.SingleFamilyHouse.HeatPumpRadiantHeatingGroundHeatTransfer and adding the radiant ceiling. For simplicity, this model provide heating with an idealized heater.
The next section explains how the radiant ceiling is configured.
The radiant ceiling is modeled in the instance
slaCei at the top of the schematic model view, using
the model
Buildings.Fluid.HeatExchangers.RadiantSlabs.ParallelCircuitsSlab.
This instance models the heat transfer from the surface of the
attic floor to the ceiling of the living room. In this example, the
construction is defined by the instance layCei. (See
the
Buildings.Fluid.HeatExchangers.RadiantSlabs.UsersGuide for how
to configure a radiant slab.) In this example, the surfaces
slaCei.surf_a (upward-facing) and
slaCei.surf_a (downward-facing) are connected to the
instance attFlo. Because attFlo models
the floor of the attic, rather than the ceiling of the
living room, the heat port slaCei.surf_a is connected
to attFlo.heaPorFro, which is the front-facing
surface, e.g., the floor. Similarly, slaCei.surf_b is
connected to attFlo.heaPorBac, which is the
back-facing surface, e.g., the ceiling of the living room.
The mass flow rate of the slab is constant if the cooling is operating. A P controller computes the control signal to track a set point for the room temperature. The controller uses a hysteresis to switch the mass flow rate on or off. The control signal is also used to set the set point for the water supply temperature to the slab. This temperature is limited by the dew point of the zone air to avoid condensation.
See also the model Buildings.Obsolete.ThermalZones.EnergyPlus_9_6_0.Examples.SingleFamilyHouse.RadiantHeatingCooling_TSurface which is controlled to track a set point for the surface temperature.
The radiant floor is modeled in the instance slaFlo
at the bottom of the schematic model view, using the model
Buildings.Fluid.HeatExchangers.RadiantSlabs.ParallelCircuitsSlab.
This instance models the heat transfer from surface of the floor to
the lower surface of the slab. In this example, the construction is
defined by the instance layFloSoi. (See the
Buildings.Fluid.HeatExchangers.RadiantSlabs.UsersGuide for how
to configure a radiant slab.) In this example, the surfaces
slaFlo.surf_a and slaFlo.surf_b are
connected to the instance flo. In EnergyPlus, the
surface flo.heaPorBac is connected to the boundary
condition of the soil because this building has no basement.
Note that the floor construction is modeled with 2 m of soil because the soil temperature in EnergyPlus is assumed to be undisturbed.
| Name | Description |
|---|---|
 MediumW |
Water medium |
idf file to add insulation, and resized
system.