Disclosed are system 100 and method of energy efficient hot and cold water management. The system 100 comprises: a control unit 101 for dynamically controlling the functioning of the system 100; at least a water storage tank 102 with at least one of a water level sensor, at least a heating element 1021, at least a temperature sensor 1022 or any combination thereof; at least an auxiliary water storage tank 103 with at least one of a water level sensor, at least a temperature sensor 1032; at least a water mixer unit 105 having at least a temperature sensor 1051; a user interface unit 1012 for controlling and monitoring different parameters including temperature, water level, opening and closing of valves 108 and 109; and a power supply with power backup unit 104 for providing basic power for proper functioning of the system 100.

Disclosed are system 100 and method of energy efficient hot and cold water management. The system 100 comprises: a control unit 101 for dynamically controlling the functioning of the system 100; at least a water storage tank 102 with at least one of a water level sensor, at least a heating element 1021, at least a temperature sensor 1022 or any combination thereof; at least an auxiliary water storage tank 103 with at least one of a water level sensor, at least a temperature sensor 1032; at least a water mixer unit 105 having at least a temperature sensor 1051; a user interface unit 1012 for controlling and monitoring different parameters including temperature, water level, opening and closing of valves 108 and 109; and a power supply with power backup unit 104 for providing basic power for proper functioning of the system 100.

A connected-type hot-water supply system includes hot-water supply apparatuses connected in parallel and a control means. The control means sets one main hot-water supply apparatus and sub-hot-water supply apparatuses, and performs leveling control of cumulative loads of the hot-water supply apparatuses by setting the main hot-water supply apparatus based on sequential rotation among the hot-water supply apparatuses. The control means includes a failure sign response mode in which it is determined whether there is a failure sign respectively for components of the hot-water supply apparatuses, and when a component of a part of hot-water supply apparatuses is a failure sign component determined to have a failure sign, a main use time of a hot-water supply apparatus having the failure sign component is increased, and the main use time is a main use time of serving as the main hot-water supply apparatus in the leveling control.

A connected-type hot-water supply system includes hot-water supply apparatuses connected in parallel and a control means. The control means sets one main hot-water supply apparatus and sub-hot-water supply apparatuses, and performs leveling control of cumulative loads of the hot-water supply apparatuses by setting the main hot-water supply apparatus based on sequential rotation among the hot-water supply apparatuses. The control means includes a failure sign response mode in which it is determined whether there is a failure sign respectively for components of the hot-water supply apparatuses, and when a component of a part of hot-water supply apparatuses is a failure sign component determined to have a failure sign, a main use time of a hot-water supply apparatus having the failure sign component is increased, and the main use time is a main use time of serving as the main hot-water supply apparatus in the leveling control.

A steam cooking system includes a steam cooking chamber and a steam generator plumbed to deliver steam to the steam cooking chamber. The steam generator includes a tank structure providing a heating chamber for holding water, a heater associated with the tank structure for heating water within the heating chamber so as to generate steam, at least one water level sensor associated with the tank, a fill line for selectively adding water to the tank, and a controller configured to control the heater and the fill line. The controller is configured to control a power level of the heater based at least in part upon a water level in the tank as indicated by the at least one water level sensor, so as to increase steam generator temperature prior to water add.

A steam cooking system includes a steam cooking chamber and a steam generator plumbed to deliver steam to the steam cooking chamber. The steam generator includes a tank structure providing a heating chamber for holding water, a heater associated with the tank structure for heating water within the heating chamber so as to generate steam, at least one water level sensor associated with the tank, a fill line for selectively adding water to the tank, and a controller configured to control the heater and the fill line. The controller is configured to control a power level of the heater based at least in part upon a water level in the tank as indicated by the at least one water level sensor, so as to increase steam generator temperature prior to water add.

A hydronic heating pad includes a control unit and a blanket pad connected to the control unit. The blanket pad includes a warm water region. The control unit includes a water reservoir tank, a heating pipe, an outlet pipe, and at least one return pipe. The heating pipe, the outlet pipe, and at least one return pipe are disposed on the water reservoir tank. The outlet pipe and the at least one return pipe extend into the warm water region, whereby the outlet pipe, the at least one return pipe, and the warm water region form a circulating water channel. The outlet pipe is provided with a water pump. The at least one return pipe is provided with a temperature-sensitive solenoid valve. The blanket pad includes at least two layers of waterproof fabrics. The warm water region is a hermetic region and includes a plurality of first polygon patterns.

A heat distribution system, method and computer program product, including an unpressurized tank configured for holding a heat transfer fluid; and one or more submersible heat transfer fluid pumps configured to pump the heat transfer fluid to one or more heat load loops respectively connected to the one or more heat transfer fluid pumps.

Some aspects of the present disclosure relate to a sensor probe kit that has an electrical connection that ensures a sensor probe has been properly positioned in a boiler well. In some embodiments, the sensor probe kit has a seating mechanism that positively positions a sensor probe at a predetermined position within a boiler well. In many instances, the seating mechanism provides tactile feedback to an installer when the sensor probe is properly positioned within the boiler well. These features can help ensure the sensor probe is properly installed, and helps keep the sensor probe electrically connected to the well at all times after installation.

A water heater comprising: an inner container (2) capable of storing fluid; a mixture device used for gas-liquid mixing of a gas and a liquid, the mixture device being provided with a mixing space (1) used for gas-liquid mixture, the mixing space (1) being arranged within the inner container (2); and a driver device (3) capable of being in communication with the inner container (2) and the mixture device, the driver device (3) being capable of guiding the fluid in the inner container (2) into the mixing space (1) for gas-liquid mixture and returning same into the inner container (2). Also provided is a control method for the water heater. This allows the implementation of gas-liquid mixture so as to produce micro-bubbled water available to a user, is not only energy-saving, water-saving, and environmentally friendly, provides water supply with strong cleaning performance, but also prepares in advance, before being used by the user, the micro-bubbled water in the inner container, thus better satisfying use demands of the user.