A system for regulating a building energy supply and distribution installation, the installation including items of energy collection equipment, each of which is in an energy transfer relationship with a respective source; items of energy transformation equipment powered by the collection equipment; items of energy using equipment; the regulation system configured for defining, for the items of equipment, different respective activation states chosen according to parameters, for optimizing with regard to criteria. The system implements a method in the installation, with the following steps: regulation is performed by placing the items of equipment in respective activation states chosen according to demand and parameters, for the purpose of optimizing with regard to criteria; at an intervention instant of regulation, regulation takes forecasts relating to at least one of the parameters into account, the forecasts relating to a period after the intervention instant. A related installation includes the regulation system.

Disclosed herein is a heat recovery system, in accordance with some embodiments. Accordingly, the heat recovery system may include a chiller, primary heat exchangers, primary pumps, secondary heat exchangers, and secondary pumps. Further, the chiller is configured for providing primary fluid and secondary fluid. Further, the primary heat exchangers are configured for exchanging a first amount of heat between the primary fluid and primary mediums creating a heat deficit and/or a heat excess in the primary mediums. Further, the primary pumps are configured for circulating the primary fluid between the chiller and the primary heat exchangers. Further, the secondary heat exchangers are configured for exchanging a second amount of heat between the secondary fluid and secondary mediums. Further, the secondary pumps are configured for circulating the secondary fluid between the chiller and the secondary heat exchangers.

Disclosed herein is a heat recovery system, in accordance with some embodiments. Accordingly, the heat recovery system may include a chiller, primary heat exchangers, primary pumps, secondary heat exchangers, and secondary pumps. Further, the chiller is configured for providing primary fluid and secondary fluid. Further, the primary heat exchangers are configured for exchanging a first amount of heat between the primary fluid and primary mediums creating a heat deficit and/or a heat excess in the primary mediums. Further, the primary pumps are configured for circulating the primary fluid between the chiller and the primary heat exchangers. Further, the secondary heat exchangers are configured for exchanging a second amount of heat between the secondary fluid and secondary mediums. Further, the secondary pumps are configured for circulating the secondary fluid between the chiller and the secondary heat exchangers.

Heat pump system comprising a heat medium circuit (210, 220, 230, 240, 250, 310, 320, 410, 420, 430, 440, 450, 460) in turn comprising a compressor (211), an expansion valve (232, 242), at least one primary heat exchanging means (422, 433, 452) between a primary-side heat medium and a respective primary heat source or sink selected from outdoor air, a water body or the ground, at least one secondary heat exchanging means (314, 315, 316) between a secondary-side heat medium and a respective secondary heat source or sink selected from indoors air, pool water and tap water, and a control means (500). The invention is characterised in that the speed of the compressor can be controlled, in that an opening of the expansion valve is adjustable, in that the speed of the compressor is controlled, and in that an output temperature of heat medium flowing out from the expansion valve is controlled by controlling the opening of the expansion valve given the controlled speed of the compressor. The invention also relates to a method.

A multi-source ground-to-air heat transfer system is configured to store thermal energy during a cooling/dehumidifcation mode of operation for future use during a heating mode of operation. The multi-source ground-to-air heat transfer system utilizes a ground loop that is configured under an enclosure, such as a greenhouse, and is in thermal communication with a thermal reservoir medium to conduct and store heat. A thermal exchange fluid is pumped through the ground loop and ground heat exchanger and may receive heat from a condenser during a cooling/dehumidification mode of operation and may liberate heat to the evaporator during a heating mode. The enclosure air may receive heat from the heat pump during a heating mode and may liberate heat to the evaporator during a cooling/dehumidification mode. The heat exchange system may employ a heat pump having a reversing valve to change the mode of operation.

Method of operating a thermal energy system coupled to a building energy system which selectively provides heating and/or cooling to a building, the method comprising the steps of; (a) providing a thermal energy system comprising a heat pump system having an output side and an input side, a heat energy working fluid loop extending into the building, the output side being coupled to a building by the heat energy working fluid loop to provide heating to the building from the thermal energy system, a cooling demand working fluid loop extending into the building, a first geothermal system in which a working fluid is circulated and a second geothermal system in which a working fluid is circulated; (b) selectively thermally connecting the first geothermal system to the input side of the heat pump system, or to the heat energy working fluid loop to provide heating to the building; and (c) selectively thermally connecting the second geothermal system to the input side of the heat pump system, or to the cooling demand working fluid loop to provide cooling to the building.

There is herein described energy storage systems. More particularly, there is herein described thermal energy storage systems and use of energy storable material such as phase change material in the provision of heating and/or cooling systems in, for example, domestic dwellings.

A heating and cooling system for use with hot, cold and source fluid circuits. A conduit module couples a heating/cooling module with the fluid circuits. The conduit module includes four three-way valves to communicated fluid from and to the fluid circuits to first and second heat exchangers in the heating/cooling module. The first heat exchanger is used to heat a fluid flow and the second one chills a second fluid flow. The conduit module simultaneously supplies a hot fluid flow to a hot fluid circuit and a cold fluid to a cold fluid circuit. The source fluid is routed by the conduit module. A method of circulating fluid is also disclosed.

A geothermal system having a flow station connected to a heat pump that is connected to a heat pump that is connected to a flow vector assembly. The flow vector assembly is connected to a heating coil and a cooling coil disposed within the ductwork of a furnace. The flow vector assembly may also be connected to a flow helix heat exchanger assembly.

A geothermal district heating (DH) system includes a plurality of DH conduits each of the conduits extending to a corresponding heat consumer; means for delivering a DH-usable fluid through said plurality of DH conduits; a fluid circuit through which a geothermal fluid is flowable; and at least two heat exchangers, each of the heat exchangers configured to transfer heat directly or indirectly from the geothermal fluid to said DH-usable fluid with a total heat influx provided by the at least two heat exchangers to said DH-usable fluid that is sufficiently high to raise a temperature of the DH-usable fluid to a predetermined DH-usable temperature without need for any supplemental fossil fuel derived waste heat to be transferred to said DH-usable fluid.