A water heater system includes a water tank and a flow-through heating assembly. The water tank contains heated water. The flow-through heating assembly may extend into the water tank and heats water as water is passed through an interior channel of the flow-through heating assembly. In one embodiment, the flow through heater assembly is a thermosiphonic heater having a hollow body and a heating element extending therein such that an annular recess is defined between an interior surface of the hollow body and the external surface of the heating element.

The invention provides for protection of life safety, property and the liability thereof, by means of a intrinsically safe unpressurized storage tank water heater while producing hot pressurized water. The design addresses, with effect, convection, radiation, conduction and evaporative heat energy losses. Heat lost returned as usable hot water resulting in ultra-low standing loss. The stationary water medium prevents sedimentation, fouling of the heating element and gases expelled. Being dielectrically isolated, the medium may also be treated to further reduce corrosion. The design allows for a quick recovery rate and provides adjustable volume of hot water, being stackable, stage able, renewable, repairable and recyclable.

An electric water heater appliance is provided herein. The electric water heater appliance may include a tank, an electric heating element, and a temperature sensor. The tank may define an interior volume extending from a top portion to a bottom portion. The interior volume may define a volume height along a vertical direction between the bottom portion and the top portion. The electric heating element may be operable to heat water within the interior volume. The temperature sensor may be attached to the tank above the electric heating element. A sensor gap may be defined along the vertical direction between the electric heating element and the temperature sensor.

A hot water storage arrangement having an electronic control unit, by means of which various modes of operation of the storage arrangement can be set. Those modes of operation can represent a normal mode of operation (at a setpoint temperature of between 30 C. and 100 C.), a frost protection mode of operation (at a temperature <10 C. and >1 C.), a time switch mode of operation (in which it is possible to set times of different setpoint temperatures with an adjustable time switch), an ECO mode of operation (in which an electronic temperature limit of between 30 C. and 55 C. is set), a hygiene mode of operation (in which a periodic increase in temperature of 55 C. is set) and/or and run-dry detection mode of operation (in which a temperature difference between a first temperature and a second temperature after heating of the hot water storage arrangement is ascertained).

The present invention relates to an electric water heater having an instantaneous hot water storage-type structure allowing a continuous outflow of a large amount of hot water instantaneously, without having to heat the water accommodated inside a housing directly. In the present invention, since the water flowed into the housing is heated while passing through the first and second heat exchange pipes, there is an effect that a large amount of hot water is instantaneously provided without having to heat a large amount of the water accommodated in the housing directly.

System and methods of operating a water heater receiving power from an electrical grid. The water heater includes a heating element, a controller, and a first control circuit. The first control circuit including an energizing terminal and a microprocessor. The method includes connecting an energizing terminal of the first control circuit between a power output terminal of the controller and the heating element, receiving driving power from the controller based on a temperature signal. The method also includes receiving a control signal from the controller based on electrical grid information, and selectively energizing the heating element, by the microprocessor of the first control circuit and through the energizing terminal of the first control circuit based on the control signal.

A low water cutoff switch controller features a dual inline package (DIP) in combination with low water cutoff switch processor. The dual inline package (DIP) has DIP switches, each DIP switch configured to set in a respective application type or mode corresponding to a particular water heater model for the low water cutoff switch controller to control, and also configured to provide DIP switch signaling containing information about a respective DIP switch set. The low water cutoff switch processor is configured to respond to the DIP switch signaling, and also configured to respond to corresponding signaling containing information about a sensed water level contained in the particular water heater model being controlled by the low water cutoff switch controller, and provide control signaling containing information to control the operation of the particular water heater model. The low water cutoff switch controller is a single controller that can be used for controlling any one of a plurality of different water heater models and have different voltage applications by setting a respective one of the DIP switches.

A fluid-heating device for heating fluid with a heater includes: a heating portion that is molded so as to cover the surrounding of the heater; and a support body integrally cast into the heating portion, the heating portion being molded in a state in which the heater is supported by the support body in a die for molding the heating portion.

In one aspect, the present disclosure is directed to preventing or lessening ice in remote water tanks. The remote water tanks can include a body at least partially defining a chamber that receives a liquid and having an open top portion that provides one or more animals access to the liquid. Further, a heat exchanger can be at least partially received within the chamber, and can receive a thermal transfer fluid that is circulated therethrough to maintain a temperature of the liquid in the chamber. Also, an external heat collector can be in fluid communication with the heat exchanger to transfer solar or other heat to the thermal transfer fluid as the thermal transfer fluid is circulated therethrough.

The invention relates to a compensation assembly for use in a hot water device and an associated hot water device. The hot water device includes a water tank for holding water to be heated, and the compensation assembly includes a compensation vessel and a ventilation component that allows air to be exchanged between the compensation vessel and the atmosphere. The ventilation component includes a blocking element designed to prevent water from leaking from the compensation vessel via the ventilation component.