A method of managing a combi radiator (1), the method comprising the following steps that are repeated for each current day, and for each current period taken from a predetermined set constituted by at least one successive period defined in the current day:

acquiring a predetermined indication from a predefined table (30), said predetermined indication being associated with said current period and being taken from a list comprising a first indication for which only the electrical radiator system (2) is to be activated, and/or a second indication for which only the hot-water radiator system (3) is to be activated, and/or a third indication for which both the electrical radiator system and the hot-water radiator system are to be activated;

controlling the radiator as a function of the predetermined indication.

A system and method for improving the responsiveness of forced hot water heat exchangers placed around the baseboards of conditioned living spaces and improving the efficiently of centralized hot water heating systems. The control system may comprise a convector baseboard heat exchanger or a replacement heat exchanger cover, and a blower, a diffuser and sensors which are mounted to one or more of the baseboard heat exchangers, the heating system influent and effluent loops, the fuel supply and the recirculation pump. When the heating system and forced hot water loop reaches its operating temperature, the blower activates to rapidly transfer energy from the-forced hot water loop into the air and disperse treated, heated air into the conditioned spaces. After the centralized heating system turns off, the system continues to transfer energy from the forced hot water into the air of the conditioned spaces until the latent heat of the centralized heating system has been extracted and the return loop temperatures are at levels consistent with optimal boiler performance.

A system and method for improving the responsiveness of forced hot water heat exchangers placed around the baseboards of conditioned living spaces and improving the efficiently of centralized hot water heating systems. The control system may comprise a convector baseboard heat exchanger or a replacement heat exchanger cover, and a blower, a diffuser and sensors which are mounted to one or more of the baseboard heat exchangers, the heating system influent and effluent loops, the fuel supply and the recirculation pump. When the heating system and forced hot water loop reaches its operating temperature, the blower activates to rapidly transfer energy from the-forced hot water loop into the air and disperse treated, heated air into the conditioned spaces. After the centralized heating system turns off, the system continues to transfer energy from the forced hot water into the air of the conditioned spaces until the latent heat of the centralized heating system has been extracted and the return loop temperatures are at levels consistent with optimal boiler performance.

A combined space conditioning or heating and fluid heating system includes a main fluid conductor having an inlet and an outlet; a single heating source configured for producing low and high temperature fluid outputs of a fluid input received at the main fluid conductor inlet; a coil comprising an inlet and an outlet; and a supplementary fluid conductor comprising a fluid mover and a directional valve, an inlet and an outlet. The inlet of the main fluid conductor is adapted for connection with the coil outlet. The high temperature fluid output is adapted for connection with the supplementary fluid conductor inlet, the supplementary fluid conductor outlet is adapted for connection with the coil inlet. The low temperature water output is adapted for connection with a fluid delivery point. The water coil inlet is adapted for connection with a raw fluid supply.

A combined space conditioning or heating and fluid heating system includes a main fluid conductor having an inlet and an outlet; a single heating source configured for producing low and high temperature fluid outputs of a fluid input received at the main fluid conductor inlet; a coil comprising an inlet and an outlet; and a supplementary fluid conductor comprising a fluid mover and a directional valve, an inlet and an outlet. The inlet of the main fluid conductor is adapted for connection with the coil outlet. The high temperature fluid output is adapted for connection with the supplementary fluid conductor inlet, the supplementary fluid conductor outlet is adapted for connection with the coil inlet. The low temperature water output is adapted for connection with a fluid delivery point. The water coil inlet is adapted for connection with a raw fluid supply.

A closed loop heating system for heating air of a given space includes a vacuum pump, a boiler, a heat exchanger, a blower, and a piping network. The vacuum pump maintains a low pressure in the piping network. The boiler is in fluid communication with the vacuum pump via the pumping network for heating a working fluid. The boiler heats the working fluid to a heated vapor. The heat exchanger is in fluid communication with the boiler for receiving the heated vapor via the piping network. The blower is positioned proximal to the heat exchanger for receiving air from the given space. The blower blows the received air over the heat exchanger for heating the air of the given space.

A closed loop heating system for heating air of a given space includes a vacuum pump, a boiler, a heat exchanger, a blower, and a piping network. The vacuum pump maintains a low pressure in the piping network. The boiler is in fluid communication with the vacuum pump via the pumping network for heating a working fluid. The boiler heats the working fluid to a heated vapor. The heat exchanger is in fluid communication with the boiler for receiving the heated vapor via the piping network. The blower is positioned proximal to the heat exchanger for receiving air from the given space. The blower blows the received air over the heat exchanger for heating the air of the given space.

A rooftop air conditioning unit to provide conditioned air to a conditioned space within a building is provided and includes a housing, disposed on a roof of the building roof, defining a pathway from an inlet fed by exterior and/or interior air to an outlet leading to the conditioned space and a hydronic heating system disposed within the housing to heat the air traveling along the pathway.

A rooftop air conditioning unit to provide conditioned air to a conditioned space within a building is provided and includes a housing, disposed on a roof of the building roof, defining a pathway from an inlet fed by exterior and/or interior air to an outlet leading to the conditioned space and a hydronic heating system disposed within the housing to heat the air traveling along the pathway.

Disclosed is an air heating apparatus including a burner configured to cause a combustion reaction, a main passage, through which water flows while circulating, a heat exchanging device configured to receive heat from combustion gas generated by the combustion reaction and heat the water flowing along the main passage, a heating heat exchanger configured to receive the water heated by the heat exchanging device and exchange heat with the air for heating, a fan configured to send the air to the heating heat exchanger, and a hot water discharge port connected to the main passage such that the water heated by the heat exchanging device is discharged to an outside of the main passage.