Provided is an induction heating device with which discharging can be easily avoided even when a large electric current is used. The induction heating device comprises a high-frequency power supply provided with a connection portion for an alternating-current power supply, and a heating coil portion connected to the high-frequency power supply. In the heating coil portion, a plurality of coils include n coils surrounding a cavity portion in a plane, wherein the plurality of coils are mutually connected in series via one of a plurality of capacitors.

An induction cooking appliance apparatus includes an induction coil, and a coil carrier configured to hold the induction coil and including a heat dissipation unit for dissipating heat emitted by the induction coil.

An induction cooking appliance apparatus includes an induction coil, and a coil carrier configured to hold the induction coil and including a heat dissipation unit for dissipating heat emitted by the induction coil.

A device for inductively soldering at least one ferromagnetic contact element to at least one conductor structure on a nonmetallic plate, includes a system for fastening a plate during the soldering operation, at least one soldering tool having at least one induction loop or induction coil suitable for emitting a magnetic field, a system for mutually positioning the soldering tool and the contact element such that the switched-on magnetic field of the soldering tool reliably heats the ferromagnetic contact element and thus the solder joint, a generator that is suitable for generating an alternating voltage with a frequency of up to 1500 kHz and that can be connected to the induction loop or induction coil.

An induction heating device according to an embodiment includes an inverter configured to supply an AC current to a working coil and includes a plurality of switches; a drive circuit configured to supply a switching signal for a switching operation of the plurality of switches to the inverter; and a controller configured to control driving of the working coil by supplying a control signal corresponding to a required power value of the working coil to the drive circuit. The controller may drive the working coil based on the required power value, receive a resonance current value of the working coil when the working coil is driven, calculate a container efficiency index based on an output power value of the working coil, the required power value, the resonance current value and a preset limit current value, and control the driving of the working coil based on the container efficiency index.

An induction heating device according to an embodiment includes an inverter configured to supply an AC current to a working coil and includes a plurality of switches; a drive circuit configured to supply a switching signal for a switching operation of the plurality of switches to the inverter; and a controller configured to control driving of the working coil by supplying a control signal corresponding to a required power value of the working coil to the drive circuit. The controller may drive the working coil based on the required power value, receive a resonance current value of the working coil when the working coil is driven, calculate a container efficiency index based on an output power value of the working coil, the required power value, the resonance current value and a preset limit current value, and control the driving of the working coil based on the container efficiency index.

A spring induction heater assembly is shown and described. The device has a quench tank incorporated into the design. A motor and drive mechanism provide rotation of a spring about one axis from a first position used for loading, to a second position for heat treatment with an induction coil and a third position where the spring is released dropped into a quench tank. Another rotational system is operational to rotate the spring on a spindle in the second or horizontal position while the spring is located between at least two legs of an induction coil. The induction coil provides even heating to the spring coils thereby providing desired changes to the material properties. The quench tank can have an automated system to remove the springs from the quench tank.

A spring induction heater assembly is shown and described. The device has a quench tank incorporated into the design. A motor and drive mechanism provide rotation of a spring about one axis from a first position used for loading, to a second position for heat treatment with an induction coil and a third position where the spring is released dropped into a quench tank. Another rotational system is operational to rotate the spring on a spindle in the second or horizontal position while the spring is located between at least two legs of an induction coil. The induction coil provides even heating to the spring coils thereby providing desired changes to the material properties. The quench tank can have an automated system to remove the springs from the quench tank.

An atmospheric pressure ionisation (API) ion source is provided that comprises a heater configured to heat a spray of droplets. The ion source may comprise a target, where the spray of droplets is arranged to impact upon the target. An inductive heater may be configured to surround and heat at least a part of the target. Alternatively, a resistive heater may be configured within a target comprising an electrically conductive tube. Also, there may be provided an inductive heater configured to heat a flow of gas, wherein the heated flow of gas is arranged to heat the spray of droplets.

An atmospheric pressure ionisation (API) ion source is provided that comprises a heater configured to heat a spray of droplets. The ion source may comprise a target, where the spray of droplets is arranged to impact upon the target. An inductive heater may be configured to surround and heat at least a part of the target. Alternatively, a resistive heater may be configured within a target comprising an electrically conductive tube. Also, there may be provided an inductive heater configured to heat a flow of gas, wherein the heated flow of gas is arranged to heat the spray of droplets.