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 heat pump system is disclosed comprising a heat-exchanger extracting latent heat from liquid stored in a reservoir, thereby forming an ice slurry. The heat pump also includes a device for delivering the heat to a heat consumer. The heat pump system includes a random input of extrinsic liquid into the reservoir and a device for removing ice slurry stored in the reservoir outward the system.

A system for conditioning air of a building that comprises a conduit buried in a soil proximate the building at a given depth such that a temperature of the soil at the given depth is different from an air temperature of an environment of the building. The conduit has a breathable wall in fluid communication with the soil. The system further comprises a forced air system in fluid communication with the conduit. The forced air system is operable to draw air from the soil across the breathable wall and along the conduit. The system defines a fluid flow path extending from the breathable wall toward the forced air system. A method of operating the system is also disclosed.

A heat transfer medium liquid circulation flow channel having a first heat exchange unit exchanging heat to a second heat exchange unit is provided, and a fixed amount of first heat transfer medium liquid circulates therein. A feed pipe couples heat source holding second heat transfer medium liquid having temperature difference from the first medium liquid to the heat transfer medium liquid circulation flow channel. The feed pipe is coupled to an inlet end side of the first heat exchange unit and a discharge pipe is coupled to an outlet end side thereof. A necessary amount of second medium liquid is supplied to the inlet end side via the feed pipe so that a detected temperature of the first medium liquid in the outlet end maintains required set temperature. The same amount of the first medium liquid as the supplied second medium liquid is discharged out of the discharge pipe.

A system and method for providing useable source fluid from a thermal exchange unit and/or one or more thermal exchange and storage units is disclosed. Topologies described allow operation in an air source, a ground source, a preconditioning, a parallel and a simultaneous mode. In the air source mode conditioned source fluid is obtained exclusively from an air-to-liquid heat exchanger. In the ground source mode source fluid is obtained exclusively from a ground heat exchanger. In the preconditioning mode source fluid from the air-to-liquid heat exchanger is used to condition a ground heat exchanger. In the parallel mode source fluid is obtained from both the air-to-liquid heat exchanger and a ground heat exchangers. In the simultaneous mode, source fluid from the air-to-liquid heat exchanger is used to improve the thermal condition of a ground heat exchanger while source fluid for the heat pump is obtained from another ground heat exchanger.

A district energy distributing system comprising a geothermal power plant comprising a first and a second circuit. The first circuit comprises a feed conduit for an incoming flow of geothermally heated water from a geothermal heat source; a boiler comprising a heat exchanger configured to exchange heat from the incoming flow of geothermally heated water to superheat a working medium of a second circuit of the geothermal power plant; and a return conduit for a return flow of cooled water from the boiler to the geothermal heat source. The second circuit comprises the boiler configured to superheat the working medium of the second circuit; an expander configured to allow the superheated working medium to expand and to transform the expansion to mechanical work; and a condenser configured to transform the expanded working medium to liquid phase and to heat a heat transfer fluid of a district thermal energy circuit.

A thermodynamic boiler for exchanging (providing or drawing) heat with a heating circuit includes a thermal compressor. The thermal compressor acts on a compressible fluid and includes at least one compression stage, with an alternating bi-directional piston separating a first chamber and a second chamber, and a first fuel burner forming a heat source coupled to the first chamber. The thermal compressor uses the heating circuit as a cold source coupled to the second chamber and forms the compression function of a reversible heat pump type loop.

Heat pump system (100) comprising a heat medium circuit (210,220,230,240,250,310,320,410,420,430,440,450,460) in turn comprising at least three heat exchanging means (314,315,315,422,433,452) between the heat medium and a respective heat source or sink selected from outdoor air, a water body, the ground, indoor air, pool water or tap water, a valve means (311,312,313,421,431,451) arranged to selectively direct the heat medium to at least two of said heat exchanging means, and a control means (500). The invention is characterized in that the heat pump system comprises temperature sensors (314a,314b;315a,315b;316a,316b;423,424,425;432,434,435) both upstream and downstream of at least one of said heat exchanging means, in that the system determines, based upon temperature measurement values comprising at least one value read from said sensors, to what heat exchanging means the heat medium is to be directed, and in that when heat medium is not directed to a certain heat exchanging means a measured temperature value is read upstream and downstream of the certain heat exchanging means, and in that an alert is set off in case the values differ by more than a predetermined value. The invention also relates to a method.

Embodiments in the current disclosure relate to improving the efficiencies of geothermal heating and cooling systems, solar based energy production and other green-energy generators by linking them together for increasing the usable energy which is extractable from each generator and/or energy storage reservoir. In some embodiments, increased efficiencies of both geothermal solutions and systems exploiting solar energy or other energy generators are achieved by linking them together. Preferably but not necessarily the linking includes smart-contacts which automatically enhance the links according to temporal measurable values characterizing the connectable modules and devices. A geothermal reservoir may include an inlet with a large surface area between a shell of the reservoir and the ground.

A multi-source ground-to-air heat transfer system is configured to store thermal energy during a cooling/dehumidification 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.