An embodiment of the present disclosure discloses an electrode boiler device configured to heat a fluid, the electrode boiler device includes a heating region formed such that electrolyzed water is disposed therein, and to have a length in one direction, a body part disposed in at least one region of an outer side of the heating region in a direction crossing a longitudinal direction of the heating region and formed to allow the fluid to be disposed therein to overlap the electrolyzed water, an electrode part having a plurality of electrodes formed to heat the electrolyzed water in the heating region, and a heat dissipation part disposed between the heating region and the body part.

An embodiment of the present disclosure discloses an electrode boiler device configured to heat a fluid, the electrode boiler device including a heating part formed such that electrolyzed water is disposed therein, a body part formed such that the fluid is disposed therein to overlap the electrolyzed water in at least one region, an electrode part including a plurality of electrodes that are disposed in the heating part to overlap the fluid in the body part and formed to heat the electrolyzed water, and a heat dissipation part disposed between the heating part and the body part.

An electrode boiler control apparatus includes a control circuit formed in an electrode boiler in which an intake electronic valve and an exhaust electronic valve in addition to an intake control valve and an exhaust control valve corresponding to air control valves formed at both sides of an upper portion of the electrode boiler, connected to the intake electronic valve and the exhaust electronic valve to control the intake electronic valve and the exhaust electronic valve; a current controller connected to a current transformer connected between electrode bars of the electrode boiler to control the current transformer; and a temperature controller connected to a temperature sensor formed on a hot water tank of the electrode boiler, and configured to control the temperature sensor and receive a temperature value measured by the temperature sensor.

One embodiment of present disclosure discloses an electrode boiler system including a body portion formed to receive the electrolyzed water therein, an electrode portion having a plurality of electrodes disposed in the body portion, wherein at least a portion of the plurality of electrodes contacts the electrolyzed water within the body portion, a first flow path portion through which the electrolyzed water in the body portion flows out and moves after heated by a current applied to the electrode portion, a second flow path portion through which the electrolyzed water flows into the body portion and which is formed to be spaced apart from the first flow path portion, and a control portion to control the current applied to the electrode portion.

A plasma heating apparatus including a boiler vessel for holding water to be heated, a cathode housed in the vessel, the cathode defining a watertight cathode chamber isolated from the water in the vessel, and, an anode housed in the cathode chamber, the anode including an internal passage for receiving a gas from outside of the vessel when the passage is connected to a gas supply, and wherein the anode is connectable to a power source for receiving power for generating a plasma in the cathode chamber. In another aspect, the present disclosure relates to a heat or power generating system or plant including the plasma heating apparatus.

A water heater control system comprising a comprising a temperature sensor, an anode rod, and a controller. The controller is configured to receive a signal indicative of a temperature from the temperature sensor and apply a voltage and/or current to the anode rod. A mounting bracket mates with a spud of a water heater and provides a conduit space for conductors providing connectivity among the controller, temperature sensor, and anode rod. The mounting bracket may provide mechanical support for the anode rod and the temperature sensor. The mounting bracket may comprise a housing mechanically supporting and surrounding the controller.

A heating system comprising: a liquid supply system; a cell configured to: receive liquid from the liquid supply system, provide heating thereof, and output heated fluid; a work extraction system configured to extract useable work from heated fluid output from the cell; wherein the cell comprises: (i) a housing arranged to define an internal portion for receiving liquid to be heated, and (ii) a plurality of electrodes configured to apply electrical energy to fluid in the internal portion; and wherein the electrodes are configured to apply electrical energy to said fluid in the internal portion to generate one or more bubbles of plasma for releasing energy into said fluid in the internal portion and the housing to provide heating of the fluid in the internal portion.

A system containing a device mounted to the flange of a tank style water heater while being connected to a AC power-source and thereby treating and heating the water, within a passage between electrodes in a core, simultaneously delivering bacteria free warm or hot improved water without limescale issues and being 20% to 30% more energy efficient. Furthermore, a method is describe using a pump to deliver the water to the device in connection with a control solution.

An instant electrode water is provided. The instant electrode water heater comprises a housing for containing water therein with the housing having a water inlet and a water outlet. A plurality of electrode plates is disposed inside the housing. The electrode plates are placed such that the electrode plates are oriented parallel to each other and have a predetermined distance between two successive electrode plates for directing water received at the water inlet through successive channels, with each channel being formed by two successive electrode plates, to the water outlet. A plurality of electric contacts is disposed in the housing such that each electric contact is in a touching relationship with a respective electrode plate for providing AC electric power thereto. Electric control circuitry is connected to the electric contacts for controllably providing electric power thereto. The electrode plates may be contained in an electrode cartridge which is removably disposed in a cavity of the housing. The electric control circuitry may comprise current sense circuitry for providing a current sense signal indicative of an electric power usage of the electrodes. A microcontroller is connected to the current sense circuitry, an AC electric power supply, and a user interface. The microcontroller determines supply of the AC electric power to the electrodes in dependence upon the current sense signal and the user input signal and provides a supply control signal indicative of the supply of the AC electric power to the electrodes to the AC electric power supply.

An electrode boiler control apparatus includes a control circuit formed in an electrode boiler in which an intake electronic valve and an exhaust electronic valve in addition to an intake control valve and an exhaust control valve corresponding to air control valves formed at both sides of an upper portion of the electrode boiler, connected to the intake electronic valve and the exhaust electronic valve to control the intake electronic valve and the exhaust electronic valve; a current controller connected to a current transformer connected between electrode bars of the electrode boiler to control the current transformer; and a temperature controller connected to a temperature sensor formed on a hot water tank of the electrode boiler, and configured to control the temperature sensor and receive a temperature value measured by the temperature sensor.