According to various embodiments, a heating system for heating a building and/or for preparing hot water is provided. The heating system can comprise a heat distributing device; and a computer, which is coupled to the heat distributing device in such a way that the heat produced by the computer is distributed in the building by means of the heat distributing device; wherein the computer is designed in such a way that the computer produces a message for a computing load distribution computer, wherein the message contains a piece of information about the heat demand of the heating system and/or of the building.

An air conditioning system includes a heat pump unit including a radiator usable with a refrigerant, a gas furnace unit including a heating section arranged to heat passing air, a blower arranged to generate an air flow that passes through the radiator and the heating section, and a controller configured to control each action of the heat pump unit, the gas furnace unit, and the blower. The controller operates either the heat pump unit or the gas furnace unit as a heat source unit, generates a capacity command used to variably adjust operating capacity of the heat source unit, and executes switch control in order to switch the heat source unit from either one of the heat pump unit or the gas furnace unit to the other when an operating capacity level designated in the capacity command is within a predetermined numerical range for a predetermined time.

An air conditioning system includes a heat pump section performing indoor air-warming by using a vapor-compression refrigeration cycle, a separate heat source section performing indoor air-warming by using a heat source separate from the heat pump section, and a control unit configured to control actions of the heat pump section and the separate heat source section. When a heat pump air-warming operation is being performed, and when a first switching condition is met, the control unit switches from the heat pump air-warming operation to a separate heat source air-warming operation. The first switching condition is that an outside air temperature reaches a first switching outside air temperature and an air-warming capability of the heat pump section reaches an upper limit.

The present invention relates to a combined fuel cell and boiler system, and comprising: a fuel cell portion for receiving supplied outside air and raw material gas and generating electricity through a catalyst reaction; and a boiler portion comprising a latent heat exchanger, which is connected to an exhaust gas pipe of the fuel cell portion, for collecting the latent heat of self-generated exhaust gas with the latent heat of exhaust gas from the fuel cell portion. The present invention can effectively increase the efficiency of a boiler by supplying the exhaust gas from the fuel cell to the latent heat exchanger in the boiler, so as to be heat-exchanged in the latent heat exchanger with the exhaust gas from the boiler and then discharged, and can simplify the composition by unifying exhaust gas pipes.

A heat source system includes a plurality of heat source units provided in parallel, a plurality of pumps provided in parallel, a collective pipe that collects flow paths between the plurality of heat source units and the plurality of pumps into one, and a control unit. The control unit determines a requested flow rate, based on at least a minimum required flow rate set for each heat source unit and an operation state of each heat source unit, determines a current water supply amount or a maximum water supply amount, based on a flow rate set for each pump and an operation state of each pump, makes a comparison between the requested flow rate and the current water supply amount or the maximum water supply amount, and controls operation of the plurality of heat source units or the plurality of pumps according to a result of the comparison.

A combined heating system comprising a first heating subsystem including a first fluid conductor, a first heating unit adapted to heat a first fluid and output the first fluid at the outlet of the first fluid conductor, and a fluid mover adapted to move the first fluid through the first heating unit, a second heating subsystem including a second fluid conductor adapted to receive a second fluid, a third fluid conductor, a second heating unit adapted to heat the second fluid and output the heated second fluid in the third fluid conductor, a fluid mover adapted to move the second fluid from the outlet of the third fluid conductor to the inlet of the second fluid conductor, at least one heat exchanger operably connected to a downstream location of the first heating unit and a fourth fluid conductor connecting the second fluid conductor and the third fluid conductor.

A multi-heater heating system including a first heater configured for expelling air through a first side surface of the first heater; and a second heater configured to be disposed and stacked above the first heater.

Appliances, such as hot water heaters, hot water heater controllers, and methods of operating such hot water heaters, that take into consideration the availability and capacity of alternative energy sources so that additional efficiencies can be realized by sensing the availability of an alternative energy source and adjusting the control algorithms used to control the use of the available electric power is provided.

A water heater is provided that heats water in a storage tank and discharges the heated water. The water heater includes a storage tank configured to store water, at least one first temperature sensor configured to sense a temperature of the water stored in the storage tank, a second temperature sensor configured to sense a temperature related to an outside of the water heater, a first heat exchanger comprising at least one heating element configured to heat the water, a second heat exchanger comprising a heat pump system and configured to heat the water, and a controller configured to control at least one of the first heat exchanger and the second heat exchanger based on a temperature sensed by the second temperature sensor and a set water temperature.

The invention relates to a thermal supply network (1000) for a process plant, in particular for a painting plant, comprising a fluid connection for supplying consumers (200, 220; 300, 302, 304, 306; 320, 322, 324) arranged therein with heat and/or cold via a heat transfer fluid in the fluid connection, in which at least two consumers (200, 300, 320; 220, 302, 304, 306, 322, 324) are connected fluidically in series, wherein the first consumer (200, 300, 320) is fluidically connected at least temporarily, by means of its first outlet (205, 305, 325) for the heat transfer fluid, to a second consumer (220, 302, 304, 306, 322, 324) via the second inlet (223) thereof.