In an electric water heater having adjustable set point and differential temperatures, upper and lower heating elements, and associated temperature sensors respectively operative to sense upper and lower tank water temperatures, a specially designed control system is provided for controlling the heating elements. The control system is operative to prevent dry firing of the heating elements by measuring temperatures over time with the temperature sensors.

A LWCO remote monitoring and diagnosing system or device features a signal processor configured to: receive signaling containing information for running a remote low water cut off (LWCO) mobile application, and also containing information about historical data related to a LWCO circuit that monitors and controls a burner of a boiler that opens and closes to provide water to the boiler depending on the water level in the boiler; and determine corresponding signaling containing information about the historical data requested based upon the signaling received.

A heat pump water heater and systems and methods for its control. The systems are configured to heat water within a water storage tank of a heat pump water heater wherein a controller within the system is operatively connected to a plurality of heat sources including at least one electric heating element and a heat pump and sensors in order to selectively energize one of the plurality of heat sources. The controller is configure to process data representative of the temperature of water within the tank near the top of the water storage tank, and rate of water flowing out of the water storage tank, in order to automatically selectively energize the heat sources. The selection of heat sources by the controller is determined by a mode of operation selected by the user and the data processed by the controller in view of the selected mode of operation.

A water heater and a method of heating water utilizing microwave energy are disclosed. The water heater includes an inlet pipe connecting tubular coils. The tubular coils overlap over one another in a pyramid-shape structure. The tubular coils include a microwave generator positioned adjacent to them. The water heater includes an insulation member that positions around the tubular coils. The tubular coils connect to an outlet pipe including a pressure relief valve and a switch. The inlet pipe supplies cold water to the tubular coils. The microwave generator produces microwave energy directed at the tubular coils. The microwave energy penetrates into the tubular coils and heats up the water. The insulation member reflects back the microwave energy into the tubular coils and ensures there is no loss of energy. The hot water flows through the outlet pipe.

A water heater and a method of heating water utilizing microwave energy are disclosed. The water heater includes an inlet pipe connecting tubular coils. The tubular coils overlap over one another in a pyramid-shape structure. The tubular coils include a microwave generator positioned adjacent to them. The water heater includes an insulation member that positions around the tubular coils. The tubular coils connect to an outlet pipe including a pressure relief valve and a switch. The inlet pipe supplies cold water to the tubular coils. The microwave generator produces microwave energy directed at the tubular coils. The microwave energy penetrates into the tubular coils and heats up the water. The insulation member reflects back the microwave energy into the tubular coils and ensures there is no loss of energy. The hot water flows through the outlet pipe.

An on-demand hot water dispenser includes a housing, a water heating system received in the housing, and a faucet connected to the water heating system through the housing for dispensing hot water into a container. A drip tray is positioned below the faucet and a screen covers the drip tray to support the container during dispensing of the hot water.

A beverage machine having a heater tank with a horizontally oriented heating element. The heating element may be arranged as a helical coil with a longitudinal axis arranged horizontally in the heater tank. A bottom wall of the heater tank may define a concave shape at the interior of the heater tank, and the heating element may be at least partially arranged within the concave shape, e.g., with a longitudinal axis of the coil extending along a central portion of the bottom wall. An inlet to the heater tank may be arranged at the bottom wall, e.g., in the central portion of the bottom wall, and may direct liquid at the heating element.

A beverage machine having a heater tank with a horizontally oriented heating element. The heating element may be arranged as a helical coil with a longitudinal axis arranged horizontally in the heater tank. A bottom wall of the heater tank may define a concave shape at the interior of the heater tank, and the heating element may be at least partially arranged within the concave shape, e.g., with a longitudinal axis of the coil extending along a central portion of the bottom wall. An inlet to the heater tank may be arranged at the bottom wall, e.g., in the central portion of the bottom wall, and may direct liquid at the heating element.

The present invention relates to an instantaneous heater, comprising a heating assembly, wherein the heating assembly includes a heating element, a first shell, a first inlet tube, a first water outlet, a hot water cavity, a cold water cavity and a capillary tube, the hot water cavity is in the first shell, the heating element is in the hot water cavity, the hot water cavity communicates with the cold water cavity, the first inlet tube communicates with the cold water cavity, the first water outlet is on the top of the first shell and communicates with the hot water cavity, the capillary tube is in the cold water cavity, one end of the capillary tube communicates with the hot water cavity and the other end communicates with the outside of the first shell. The instantaneous heater boasts simple structure, low cost and effective prevention of vapor from rapidly erupting.

A heater for heating liquid to boiling comprises a heating element (48; 106), a first heating region (18, 20; 100) heated by said heating element (48; 106) for heating liquid flowing therethrough to a temperature below boiling, and a second heating region (22; 102) for heating said liquid to boiling. The second region permits the exit of steam therefrom separately from heated water.