A method of processing electrical data and signals which comprises locating a site with a geothermal hot water resource which feeds hot water to an on-site heat engine that drives an on-site electricity generator which provides electrical power to an array of microprocessors, located in an enclosure structure, that processes data transmitted from a remote location at high speeds. The processed data is transmitted back to the remote locations at high speeds.

A domestic water heating group includes a heat source; storage tank. A heat exchanger includes inlet and outlet sections, the the inlet and outlet being in fluid communication with: a water supply system, a water usage system and the tank. The water is heated to, towards the tank, a storage temperature TAC and/or towards the usage system at a supply temperature TER, mixer group is upstream of the inlet of the exchanger group and has first and second inlet ports connected to the supply system, tank, exchanger group The mixer receives the domestic water, at a low temperature TIN, the heated domestic water at the second inlet port, and mixes the water thus received and provides at the outlet port, in fluid connection with the exchanger group, the mixed domestic water having an intermediate temperature TINT included between the temperature TIN and the temperature TAC.

The present invention relates to an electrically driven, vapour compression heat pump device. The heat pump device comprises a variable speed or variable capacity refrigerant compressor, a compression stage having a first condenser, an expansion stage having a first evaporator, a DC to AC variable speed compressor drive inverter unit, a grid AC to DC power supply unit and an electronic control unit. The control unit varies the thermal capacity, and the power consumed by the device, in response to an input from at least one of: a renewable electricity generation input, a premises net consumption monitor, a utility grid frequency monitor, and a third party control input.

A thermally enhanced heating system and a method for thermally enhancing a HVAC system are provided. The thermally enhanced heating system preferably includes an outdoor HVAC unit and an indoor HVAC unit. The indoor HVAC unit includes a first heat exchanger for transferring heat from a refrigerant, a second heat exchanger for transferring heat from a fuel source, and a third heat exchanger for transferring heat to the refrigerant. The outdoor HVAC unit includes an outdoor heat exchanger for transferring heat from an outdoor air to the refrigerant, a pump configured to circulate the refrigerant, and an ejector configured to combine the refrigerant from the outdoor heat exchanger and the third heat exchanger. Preferably the outdoor HVAC unit is operated to circulate the refrigerant through a first refrigerant circuit and a second refrigerant circuit, and combine refrigerant in the first refrigerant circuit and the second refrigerant circuit.

A heat recuperating system is adapted for recuperating heat generated by mining devices, s.g. cryptocurrency miners, and for using the recuperating heat in agri-food industry applications. The heat recuperating system comprises a technical room comprising an air supply area, an exhausted air area and a computation area dividing the air supply area from the exhausted air area, wherein the computation area houses the mining devices. The heat recuperating system also comprises a heat exchanger system recuperating heat from the exhausted air area of the technical room and transmitting the recuperated heat to the agri-food industry applications. An associated method comprises supplying a technical room comprising a computation area wherein the mining devices are operating; supplying a heat exchanger system recuperating heat generated by the mining devices when operating; and transmitting the recuperated heat to the agri-food industry applications.

Building heating and/or cooling methods are provided that can include: distributing fluid from within conduits within a concrete floor of a building to conduits within grounds surrounding and/or supporting the building; diverting at least some of the fluid exiting the conduits within the grounds surrounding and/or supporting the building to a dehumidifier operably associated with the interior of the building; and returning the at least some of the fluid from the dehumidifier to the conduits within the grounds surrounding and/or supporting the building.

An energy transfer system that includes a tank comprising an outer wall having a circumference. A first fluid pathway surrounds a portion of the circumference of the tank. A second fluid pathway seals the portion of the circumference of the tank and the first fluid pathway from the environment.

A geothermal heat exchanger, a geothermal heat arrangement and to a method in connection with a geothermal heat arrangement. The geothermal heat exchanger includes a piping arrangement having a rise pipe and a drain pipe, and a first pump arranged to the piping arrangement. The rise pipe and drain pipe are arranged in fluid communication with each other for circulating the primary working fluid. The rise pipe is provided with a first thermal insulation surrounding the rise pipe along at least part of the length of the rise pipe and the first pump is arranged to circulate the primary working fluid in a direction towards a lower end of the rise pump.

There is disclosed an electric water heating apparatus (10) comprising a water reservoir (12) having a closable aperture for receiving water therein; a heat pump assembly (14) including at least a portion of a condenser coil (16) located inside the water reservoir (12), operatively enabling a compressed refrigerant to flow through the condenser coil (16) for heat exchange to take place between the condenser coil (16) and the water inside the reservoir (12) to heat the water inside the reservoir (12); a water heating conduit (18) extending at least partly through the water in the water reservoir (12), operatively conveying water there through between an inlet (20) and an outlet (24) and being in fluid communication with a water reticulation network, for water passing though the water heating conduit (18) to be indirectly heated via heat transfer from heated water inside the water reservoir (16).

An electronic signals processing facility which includes a site with a geothermal hot water resource which feeds hot water to an on-site heat engine that drives an on-site electricity generator which provides electrical power to an array of microprocessors, located in an enclosure structure, that processes data transmitted from a remote location at high speeds. The processed data is transmitted back to the remote locations at high speeds.