An induction cooking system includes a first container that receives first contents and a second container sized to fit within the first container. The second container is composed of a ferromagnetic material such that the second container is heated in response to received electromagnetic radiation. An exterior surface of the second container is in contact with the first contents of the first container, and an interior surface of the second container is in contact with second contents placed within the second container.

To reduce the power supply voltage during induction heating using a coil provided in a stator core. A method for manufacturing a stator according to one aspect of the present disclosure includes: disposing a three-phase coil in an annular stator core; and making a three-phase alternating current pass through the three-phase coil, thereby inductively heating the stator core. Capacitors are respectively provided between a power supply configured to supply the three-phase alternating current to ends of the three-phase coil and each one of the ends of coils of respective phases in the three-phase coil, whereby a circuit comprising the three-phase coil serves as a resonant circuit when the three-phase alternating current is made to pass through the three-phase coil.

A heating system for heating multiple working areas of a metallic workpiece, one working area after another according to a heating plan, includes at least one induction heating unit, at least one travel unit, and an induction heating power supply unit. The induction heating unit heats the working areas from a working distance which is greater than a predetermined height. The travel unit provides relative motion according to the heating plan between the induction heating unit and the workpiece at a travel velocity. The induction heating power supply unit provides current at a desired magnitude and frequency, generating therefrom a magnetic field which extends to the working area. The induction heating unit includes at least one hairpin coil at a vertical position with respect to the working areas, and a magnetic flux concentrator (MFC) surrounding the hairpin coil. The MFC increases the range of a magnetic field to include the working areas.

An induction heating device is provided. The induction heating device comprises a plurality of induction heating devices disposed at intervals along the circumference of a ring-shaped workpiece, a setting unit for setting induction heating conditions, and a switching control unit. Each of the plurality of induction heating devices comprises heating coils disposed facing areas to be heated of the workpiece, a plurality of transformers connected to the heating coils in parallel, a plurality of matching units connected to any one of the plurality of transformers, an inverter unit having a rectifier unit and an inverter unit, an inverter control unit having a rectification control unit, and a group of switches.

Methods and apparatus to communicate via a weld cable are disclosed. An example welding accessory includes a first port to receive input power via a first weld cable, a power converter to convert the input power to output power, a second port to output the input power via a second weld cable, and one or more output switches to selectively divert the input power from the power converter to the second port.

An induction heating system can be adapted for shrink fitting a plurality of different assemblies. A plurality of tooling units associated to respective ones of the assemblies, each one having an appropriately configured induction coil and holder, can be provided. A computer can be used to control the delivery of electrical power to the induction coil in accordance with a heating recipe, and can be provided with an input device for inputting an assembly identifier allowing the computer to operate the control based on the right heating recipe.

An induction heating device for heating a metal article includes a support plate with an upper surface for receiving the metal article, and a plurality of induction coils, which are arranged concentrically around an axis and are provided at an underside of the support plate. Each induction coil is connected to and selectively powered by a generator, and at least one temperature probe is disposeable on the metal article during heating in order to monitor and control the heating of the article.

A method of making a component includes: depositing a metallic powder on a workplane; directing a beam from a directed energy source to fuse the powder in a pattern corresponding to a cross-sectional layer of the component; repeating in a cycle the steps of depositing and fusing to build up the component in a layer-by layer fashion; and during the cycle of depositing and melting, using an external heat control apparatus separate from the directed energy source to maintain a predetermined temperature profile of the component, such that the resulting component has a directionally-solidified or single-crystal microstructure.

A multifunctional assembly having a resistive element a conductive element in electrical communication with the resistive element, the conductive element defining at least one of a plurality of multifunctional zones of the resistive element, wherein the conductive element is configured to direct a flow of electricity across at least one of the plurality of multifunctional zones of the resistive element in a preselected manner.

A method of heating an inner pipe of a set of coaxial pipes, wherein the inner pipe is heated by induction using an electromagnetic induction coil (5) surrounding the outer pipe coaxially, the coil passing electrical power at a frequency lower than 100 Hz optimized for maximum energy efficiency of Joule effect heating of the inner pipe. A device (8) is also provided for induction heating an inner pipe of coaxial pipes, the device has a) an induction heater having at least one electromagnetic induction coil (5) coaxially surrounding the outer pipe of the coaxial pipes, and b) a raising device (9) for raising a portion (1-2) of coaxial pipes (1) above the sea bed (13) together with the induction coil(s) (5) surrounding it.