Pipe with heat loss using the time delay based heat losses and transport of the fluid using a plug flow model, applicable for simulation of long pipes such as in district heating and cooling systems.
This model takes into account transport delay along the pipe length idealized as a plug flow. The model also includes thermal inertia of the pipe wall.
Heat losses are implemented by IBPSA.Fluid.FixedResistances.BaseClasses.PlugFlowHeatLoss at each end of the pipe (see IBPSA.Obsolete.Fluid.FixedResistances.BaseClasses.PlugFlowCore). Depending on the flow direction, the temperature difference due to heat losses is subtracted at the right fluid port.
The pressure drop is implemented using IBPSA.Fluid.FixedResistances.HydraulicDiameter.
The thermal capacity of the pipe wall is implemented as a mixing volume
of the fluid in the pipe, of which the thermal capacity
is equal to that of the pipe wall material.
In addition, this mixing volume allows the hydraulic separation of subsequent pipes.
Thanks to the vectorized implementation of the (design) outlet port,
splits and junctions of pipes can be handled in a numerically efficient way.
This mixing volume is not present in the
PlugFlowCore model,
which can be used in cases where mixing volumes at pipe junctions need to
be added manually.
ports_b
.
Full details on the model implementation and experimental validation can be found in:
van der Heijde, B., Fuchs, M., Ribas Tugores, C., Schweiger, G., Sartor, K.,
Basciotti, D., Müller, D., Nytsch-Geusen, C., Wetter, M. and Helsen, L.
(2017).
Dynamic equation-based thermo-hydraulic pipe model for district heating and
cooling systems.
Energy Conversion and Management, vol. 151, p. 158-169.
doi:
10.1016/j.enconman.2017.08.072.
homotopyInitialization
to a constant.R
by using correct radiuses.
See #1310.
pipVol
.