A hot water supply system according to the present invention includes: a hot water supply unit configured to supply hot water; an opening and closing valve configured to connect a hot water supply pipe, which is configured to supply hot water to a user from the hot water supply unit, and a cold water supply pipe, which is configured to supply cold water introduced from a cold water inflow pipe to the user, to allow water to flow or configured to disconnect the hot water supply pipe from the cold water supply pipe to block the water from flowing; a circulation pump configured to circulate water supplied from the hot water supply unit through the hot water supply pipe, the opening and closing valve, the cold water supply pipe, and the hot water supply unit; and a control unit configured to, when a water-preheating signal of the user is input, open the opening and closing valve, and operate the circulation pump to preheat water which is to be supplied to the user.

A fluid discharge event detection apparatus measures a change in capacitance to detect the presence of a fluid in a sensing conduit where the presence of fluid indicates a discharge event. The apparatus includes a first conduit, the sensing conduit and a control valve, coupled between the first conduit and the sensing conduit. The control valve is configured to activate and fluidly couple the first conduit and the sensing conduit to one another when the control valve detects at least one predetermined condition of a fluid within the first conduit. A sensor, configured to measure a capacitance value, is disposed about the sensing conduit. A controller, coupled to the sensor, is configured to detect a change in the sensing conduit capacitance value and assert an alarm condition upon detection of the change in the sensing conduit capacitance value.

The present disclosure provides a control device of a water heating apparatus, a water heating apparatus and a control method thereof. The control device comprises a storage, a processor and a heater, the storage stores a usage state value of the water heating apparatus during a first period and provides the usage state value to the processor connected thereto, the usage state value includes a mean value of outlet water temperature T.sub.H, a mean value of outlet water amount L.sub.U and a mean value of inlet water temperature T.sub.L, the processor determines an output value in accordance with the usage state value and provides the output value to the heater connected thereto, the output value includes a water amount L.sub.X to be heated and a water temperature T to be reached, the heater performs heating during a second period in accordance with the output value from the processor.

A hot-water supply device includes a hot-water dispenser supplying hot-water, a hot-water supply path supplying the hot-water to a hot-water supply tap, a circulation path carrying out instant hot-water operation which circulates and heats the hot-water remaining in the hot-water supply path, a first clock repeatedly measuring unit times in which a pattern of hot-water usage of a user makes a round, and a flow rate sensor detecting the supply of the hot-water from the hot-water supply tap. The control portion detects, for each of the unit times and based on detection signals of the flow rate sensor, a time zone in which hot-water supply operation is carried out, and reserves, based on a time zone in a first unit time in which the hot-water supply operation is carried out, a time zone in a second unit time following the first unit time for carrying out the instant hot-water operation.

A method for operating and/or monitoring an HVAC system (10), in which a medium circulating in a primary circuit (26) flows through at least one energy consumer (11, 12, 13), the medium entering with a volume flow () through a supply line (14) into the energy consumer (11, 12, 13) at a supply temperature (T.sub.v) and leaving the energy consumer (11, 12, 13) at a return temperature (T.sub.R) via a return line (15), and transferring heat or cooling energy to the energy consumer (11, 12, 13) in an energy flow (E). A control unit (21) adaptively operates the system by empirically determining the dependence of the energy flow (F) and/or the temperature difference T between supply temperature (T.sub.v) and return temperature (T.sub.R) on the volume flow () for the energy consumers (11, 12, 13) in a first step, and by operating and/or monitoring the HVAC system (10) according to the determined dependency or dependencies in a second step.

Refilling device (11) for a hydronic heating system, having a monolithic housing (21) providing an inlet port (22), an outlet port (23), a middle section (24) providing a flow channel for water extending between the inlet port (22) and the outlet port (23) and a connection socket (25) for a softening and/or demineralization cartridge (26), having an inlet shut-off-valve (27) accommodated within said monolithic housing (21) downstream of said inlet port (22), having an automatically actuated outlet shut-off-valve (28) accommodated within said monolithic housing (21) upstream of said outlet port (23), having a system separator (29) with backflow preventers (30, 31) accommodated within said monolithic housing (21), having a conductivity or TDS sensor (32, 33) accommodated within said monolithic housing (21), having a flow meter (35) accommodated within said monolithic housing (21), and having a controller (37) mounted to said monolithic housing (21), wherein the controller (37) receives signals from the conductivity or TDS sensor (32, 33) and from the flow meter (35), wherein the controller (37) processes said signals received from said sensors to automatically control the operation of the refilling device (11).

Refilling device for a hydronic heating system, having a monolithic housing providing an inlet port, an outlet port, a middle section providing a flow channel for water extending between the inlet port and the outlet port and a connection socket for a softening and/or demineralization cartridge, having an inlet shut-off-valve accommodated within said monolithic housing downstream of said inlet port, having an automatically actuated outlet shut-off-valve accommodated within said monolithic housing upstream of said outlet port, having a system separator with backflow preventers, a conductivity or TDS sensor and a flow meter accommodated within said monolithic housing, and having a controller mounted to said monolithic housing, wherein the controller receives signals from the conductivity or TDS sensor and from the flow meter, wherein the controller processes said signals received from said sensors to automatically control the operation of the refilling device.

A controller assembly allows an adjusted flow of water through a hydronic emitter in order to heat or cool an environmental entity. The controller assembly operates in two phases: a calibration phase and an operational phase. During the calibration phase, the controller assembly discovers a valve position where water starts to flow through the hydronic emitter based on signals from a temperature sensor and/or a sound sensor. The temperature sensor may be mounted in close proximity of the emitter inlet so that the controller assembly can detect when the temperature starts to change. The sound sensor may be mounted on the valve body to detect a rushing water sound that is associated with a start of the water flow. The discovered valve position is subsequently used by the controller assembly to adjust water flow between a minimum flow and a maximum flow.

This invention relates to a domestic hot water installation (1, 51, 61, 71) comprising a hot water cylinder (3), an external heating circuit (4) such as a boiler (5) in combination with a heat exchanger (7), a pump (9), and a control circuit (11). The control circuit comprises a pair of sensors (15, 17), at least one of which is a temperature sensor, and a programmable controller (13) in communication with the sensors. The programmable controller has a processor (19), an accessible memory (21), and means (23) to operate the pump. The programmable controller monitors the data from the sensors and accurately calculates the amount of hot water that has been delivered to the hot water cylinder. When the correct amount of water, according to a domestic hot water profile, has been delivered to the hot water cylinder, the programmable controller stops hot water from being delivered into the tank by shutting off the pump. By providing such an installation, the amount of hot water delivered can be accurately controlled and waste of energy is minimized.

A heating system is configured to optimize the speed and accuracy of the system in achieving various ambient air temperature setpoints, by modulating the heated water supply water setpoint to optimize the slope of the system's response curve. Optimized response curves are automatically determined by analyzing differences between ambient air temperatures over time in response to modulated supply water temperatures as they are reset upward or downward to achieve response times prioritized for improved occupant comfort. The controller of the heating system calculates a temperature slope, and adjusts the supply water setpoint to increase/decrease the speed of ambient temperature rise to achieve a desired slope.