A hand-held heating unit is disclosed having a turbine connected to a generator to generate electrical power from a compressed air source. The electrical power produced by the generator is suppled to a transformer to establish a voltage which is in turn used to energize a coil with an alternating current. The current causes a magnetic field to form in the coil that can be used to heat ferrous materials within the coil. A circuit board can control the current and frequency for different applications.

A hand-held heating unit is disclosed having a turbine connected to a generator to generate electrical power from a compressed air source. The electrical power produced by the generator is suppled to a transformer to establish a voltage which is in turn used to energize a coil with an alternating current. The current causes a magnetic field to form in the coil that can be used to heat ferrous materials within the coil. A circuit board can control the current and frequency for different applications.

An induction heating system for heating a component, the induction heating system having an alternating voltage supply device, a capacitor, a displacement unit, and an induction coil. The alternating voltage supply device supplies alternating voltage to a series resonant circuit which is formed by the capacitor and the induction coil. The displacement unit allows the induction coil to be displaced laterally in at least one direction relative to the component. The capacitor is situated between the displacement unit and the induction coil. A device for the additive manufacturing of a component uses such an induction heating system.

An induction heating system for heating a component, the induction heating system having an alternating voltage supply device, a capacitor, a displacement unit, and an induction coil. The alternating voltage supply device supplies alternating voltage to a series resonant circuit which is formed by the capacitor and the induction coil. The displacement unit allows the induction coil to be displaced laterally in at least one direction relative to the component. The capacitor is situated between the displacement unit and the induction coil. A device for the additive manufacturing of a component uses such an induction heating system.

An induction heating type cooktop according to an embodiment of the present disclosure includes: a case; a cover plate configured to be coupled to an upper end of the case and provided with an upper plate portion on which an object to be heated is disposed; a thin film configured to be coated on the upper plate portion and having an opening in a center thereof; a working coil provided inside the case and including a first working coil and a second working coil; and at least one inverter configured to be driven to allow electric currents to flow through the first working coil and the second working coil, wherein a direction of the electric current flowing through the first working coil is the same as or different from a direction of the electric current flowing through the second working coil according to the object to be heated.

An induction heating type cooktop according to an embodiment of the present disclosure may include a case; a cover plate configured to be coupled to the upper end of the case and provided with an upper plate portion on which an object to be heated is disposed; a thin film configured to be coated on the upper plate portion; a first working coil and a second working coil provided inside the case; an inverter configured to be connected to the first working coil; and a first switch configured to be connected between the first working coil and the second working coil. The first switch may determine whether the first working coil and the second working coil are connected in series.

lower boxlower boxlower boxlower boxlower boxlower box An induction cooktop includes: a cover plate with at least one cooking point; a retaining plate; at least one inductive heating coil arranged in an intermediate space between the cover plate and the retaining plate; at least one electronics housing fastened to a side of the retaining plate facing away from the at least one heating coil and having electronics for the at least one heating coil; and a lower box closing off the induction cooktop at a bottom of the induction cooktop, the lower box being open at a top of the lower box. The at least one electronics housing with the electronics is arranged in the lower box. The retaining plate covers the lower box at the top of the lower box. The induction cooktop includes a fan for generating a primary cooling air flow for cooling the electronics in the lower box. At least one cooling air opening is arranged in the retaining plate.

An induction heating device includes a casing; a first induction heating module in the casing; a first heat sink located below the first induction heating module; a first heat pipe that passes through the first heat sink, that extends outward from the first induction heating module, and that is configured to discharge heat from the first heat sink out of the first induction heating module; an air-discharge fan located at an inner side of the casing and configured to discharge air from inside of the casing to outside of the casing; and a cooling fan located at the inner side of the casing and configured to blow air to the air-discharge fan. The first heat pipe has an end that protrudes from the first induction heating module and that is located at an air-flow path defined between the cooling fan and the air-discharge fan.

An induction heating device includes a casing; a first induction heating module in the casing; a first heat sink located below the first induction heating module; a first heat pipe that passes through the first heat sink, that extends outward from the first induction heating module, and that is configured to discharge heat from the first heat sink out of the first induction heating module; an air-discharge fan located at an inner side of the casing and configured to discharge air from inside of the casing to outside of the casing; and a cooling fan located at the inner side of the casing and configured to blow air to the air-discharge fan. The first heat pipe has an end that protrudes from the first induction heating module and that is located at an air-flow path defined between the cooling fan and the air-discharge fan.

A magnetic inductor for heating parts by means of induction having a geometry with a density greater than or equal to 99.9% (absence of pores), produced by a plurality of welded layers formed by metal dust particles of a conductive, non-magnetic material (such as, inter alia, copper, tin, aluminium, gold, or silver), preferably copper or a copper-based alloy, having a spherical shape and a grain size between 40 and 100 μm, and in a single-piece part including electrical and mechanical connections. Also, a method for producing the magnetic inductor with EBM technology (electron beam melting/production technology based on electron beam fusion), using a system comprising an electron gun, a vacuum chamber, a working chamber and a manipulation system.