Abstract: A modular energy storage system including an enclosure having at least one thermally conductive sidewall; a battery module housed inside of the enclosure and including a plurality of battery submodules, each battery submodule including a plurality of battery cells, at least some of the plurality of battery cells being electrically interconnected to each other; at least one heat pipe thermally coupled to the plurality of battery cells of at least one of the plurality of battery submodules to channel heat from the plurality of battery cells thermally coupled thereto to the at least one thermally conductive sidewall of the enclosure; and a cooling mechanism thermally coupled to the at least one thermally conductive sidewall of the enclosure to cool the at least one heat pipe.

Abstract: According to some embodiments, system and method are provided comprising calculating an output power setpoint for a thermal generation system for a first calculation cycle of a time window having at least one calculation cycle; calculating a net demand for dispatchable power to satisfy a required load demand after calculating an available renewable power generation; determining, responsive to determining that the net demand for dispatchable power exceeds the output power setpoint for the thermal generation system, whether a discharge power of an energy storage device satisfies a power gap; generating, responsive to determining that the discharge power is not larger than a power rating, a discharge command to discharge the energy storage device at the discharge power; and increasing, responsive to determining that the discharge of the energy storage device fails to satisfy the power gap, the output power setpoint for the thermal generation system for the first calculation cycle.

Abstract: Heat dissipation system, a power converter using such a heat dissipation system, and an associated method of thermal management of the power converter are disclosed. The heat dissipation system includes a condenser, a first cooling loop, and a second cooling loop. The first cooling loop is coupled to the condenser and includes a first two-phase heat transfer device. The second cooling loop is coupled to the condenser and includes a second two-phase heat transfer device. The condenser is disposed above the first and second two-phase heat transfer devices.