A system (1) for heating liquids includes an hydrosonic pump (2) for the heating of the mentioned liquid; a primary circuit (3) in turn comprising, at least: a storage (30) of the above-mentioned liquid or a heat exchanger (45); a plurality of pipes (31, 32), in order to get a mutual connection with the mentioned storage (30) or heat exchanger (45) with the said hydrosonic pump (20), at least one solenoid valve (34), to open and/or close the liquid circulation within the mentioned primary circuit (3), at least one sectioning valve (8), in order to adjust the flow rate of the mentioned liquid output from the said hydrosonic pump (2). The system (1) further comprises an optimizer (5) connected to and placed downstream of said hydrosonic pump (2), the optimizer cooperating with at least said primary circuit (3) to which it gives and transfers the thermal energy produced by said hydrosonic pump (2), said optimizer (5) comprising a low-capacity storage tank (52), operating at high pressure and thermally insulated.

A system (1) for heating liquids includes an hydrosonic pump (2) for the heating of the mentioned liquid; a primary circuit (3) in turn comprising, at least: a storage (30) of the above-mentioned liquid or a heat exchanger (45); a plurality of pipes (31, 32), in order to get a mutual connection with the mentioned storage (30) or heat exchanger (45) with the said hydrosonic pump (20), at least one solenoid valve (34), to open and/or close the liquid circulation within the mentioned primary circuit (3), at least one sectioning valve (8), in order to adjust the flow rate of the mentioned liquid output from the said hydrosonic pump (2). The system (1) further comprises an optimizer (5) connected to and placed downstream of said hydrosonic pump (2), the optimizer cooperating with at least said primary circuit (3) to which it gives and transfers the thermal energy produced by said hydrosonic pump (2), said optimizer (5) comprising a low-capacity storage tank (52), operating at high pressure and thermally insulated.

A fluid cavitation apparatus includes a housing, an external rotor with cavitation bores in an outer surface thereof, and a motor for rotating the external rotor. An inner surface of the housing is spaced from the outer surface of the external rotor to create a fluid cavitation zone. The inner surface of the housing is configured with a spiral shape and tunnel zone to enhance the thermal transfer characterisitics of the fluid for heating, cooling, and purification. A control system to facilitate proper motor speed, and fluid behavior to enhance the cavition process.

A fluid cavitation apparatus includes a housing, an external rotor with cavitation bores in an outer surface thereof, and a motor for rotating the external rotor. An inner surface of the housing is spaced from the outer surface of the external rotor to create a fluid cavitation zone. The inner surface of the housing is configured with a spiral shape and tunnel zone to enhance the thermal transfer characterisitics of the fluid for heating, cooling, and purification. A control system to facilitate proper motor speed, and fluid behavior to enhance the cavition process.

A fluid cavitation apparatus includes a housing, an external rotor with cavitation bores in an outer surface thereof, and a motor for rotating the external rotor. An inner surface of the housing is spaced from the outer surface of the external rotor to create a fluid cavitation zone. The inner surface of the housing is configured with a spiral shape and tunnel zone to enhance the thermal transfer characterisitics of the fluid for heating, cooling, and purification. A control system to facilitate proper motor speed, and fluid behavior to enhance the cavitation process.

A fluid cavitation apparatus includes a housing, an external rotor with cavitation bores in an outer surface thereof, and a motor for rotating the external rotor. An inner surface of the housing is spaced from the outer surface of the external rotor to create a fluid cavitation zone. The inner surface of the housing is configured with a spiral shape and tunnel zone to enhance the thermal transfer characterisitics of the fluid for heating, cooling, and purification. A control system to facilitate proper motor speed, and fluid behavior to enhance the cavitation process.

A system for generating steam for industrial heat. The system may include a plurality of heat pump cycles in thermal communication with each other and in thermal communication with a steam generation cycle. The plurality of heat pump cycles may include first and second heat pump cycles. The first heat pump circulates a first a working fluid and includes a first heat exchanger. The second heat pump cycle circulates a second working fluid and includes a second heat exchanger. The first heat exchanger transfers heat from the first to the second working fluid. The second heat exchanger transfers heat to a third working fluid in the steam generation cycle.

A system for generating steam for industrial heat. The system may include a plurality of heat pump cycles in thermal communication with each other and in thermal communication with a steam generation cycle. The plurality of heat pump cycles may include first and second heat pump cycles. The first heat pump circulates a first a working fluid and includes a first heat exchanger. The second heat pump cycle circulates a second working fluid and includes a second heat exchanger. The first heat exchanger transfers heat from the first to the second working fluid. The second heat exchanger transfers heat to a third working fluid in the steam generation cycle.