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IPSYS: Demonstration cases
The modelled system (Fig. 1) consists of four subsystems, corresponding to four
physical domains, and is centered around an electrical minigrid of three
busbars (electrical subsystem, light red)
Fig. 1: Schematic view of the demonstration system.
Busbar 1 is connected to a mechanical subsystem (orange) through two induction
generators, each of which receives mechanical power from a wind turbine.
Three sets of diesel generators feed into busbar 2, where a dump load is
connected as well. The diesels’ speed governors are set to operate in droop
mode, controlling the system frequency together with the dump load, which
has frequency dependent characteristics. The droop curves
determine the ratio of active power sharing between the diesel units. Each
generator provides a regulated output voltage as a function of active and
reactive power output, which facilitates reactive power sharing. The third busbar
feeds a time-variable consumer load and the pump of a reverse osmosis
desalination plant. Busbars 1-2 and 2-3 are interconnected through non-ideal
transmission lines.
Surplus heat from diesel engines and dump load is collected in a heat
subsystem (yellow) and exchanged with a cooling unit and a second
desalination plant which works after the evaporation principle. Combined
freshwater production of both desalinators is balanced against a
time-variable water demand in a water subsystem (light blue).
The thermal and freshwater circuits operate on a policy that attempts to
maximize the utilisation of waste heat from diesel gensets and dumpload: The
cooler only dissipates excess heat which can not be used for desalination,
and the heat-driven desalination unit gets priority over the
electricity-driven (reverse osmosis) one. This establishes a weak feedback
loop across the thermal, water and electrical domains, as a decrease in
diesel loading will reduce the amount of heat available for desalination. To
meet water demand, the throughput of the electric desalination unit will
have to be raised, resulting in higher electricity demand and thus higher
diesel loading.
Dispatching of the diesel generators is handled by a system controller,
implemented in a controller module.
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Strategy A |
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If any diesel genset's load factor
is higher than threshold A1, start another diesel.
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If any diesel genset's load factor
is lower than threshold A2, stop one diesel.
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Minimum runtime
policy: Every generator has to run for at least 300s after having
been started (to prevent on/off cycling)
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Strategy B |
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Calculate the amount of desired
spinning reserve:
Pspinres=a×Pload
+b×Pwind
+g×Pdump
+d*Pdesal
where a, b, g, d=user-selectable constants,
Pload=total consumer load, Pwind=total wind production, Pdump=total
power dumped, Pdesal=total desalination load.
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Calculate the required genset
capacity:
Pcap=Pload+Pdesal+Pdump+Pspinres-Pwind
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blah
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Minimum runtime
policy: Every generator has to run for at least 300s after having
been started (to prevent on/off cycling)
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