KR960003524A - Induction heater device - Google Patents

Abstract

According to the present invention, the induction heater device is composed of a plurality of C-type inductors arranged in parallel to each other in the direction of transport of the object, each C-type inductor has a first and second iron core angle and between the first and second iron core angles. Another C having a C-type chuck with a gap of which the object is transported through the gap and a heating coil wound around each of the first and second iron cores so that the magnetic flux direction of one C-type inductor is adjacent It is configured to face the magnetic flux direction of the -type inductor.

Description

Induction heater device

Since this is an open matter, no full text was included.

1 is a perspective view showing an induction heater apparatus according to a first embodiment of the invention.

2 is a circuit diagram showing a circuit equivalent to the induction heater device of FIG.

3 is a circuit diagram showing an induction heater apparatus according to a second embodiment of the invention.

4 is a perspective view showing an induction heater apparatus according to a third embodiment of the present invention.

Claims (29)

In order to heat the corner portion of a moving reheating object in an induction heating method: a plurality of C-type inductors are arranged parallel to the direction of movement of the object, each inductor having a first and second iron core angles C- It is provided with a core, the gap is formed between the first and second iron core, the edge portion of the object passes through the gap, the heating coil is wound on the first and second iron core, respectively, two adjacent C-type inducer of generates opposing magnetic flux; And at least one power source for supplying a high frequency current to the heating coil of the C-type inductor and generating magnetic flux. The induction heater apparatus according to claim 1, wherein the common power source is connected to the heating coil of the C-type inductor as a single power source. The C-type inductor of claim 1, wherein the C-type inductors are arranged on both sides of the object such that each pair of C-type inductors face each other in a direction perpendicular to the moving direction of the object, and the common power source is a C-type as a single power source. Induction heater apparatus, characterized in that connected to the induction machine. 4. The induction according to claim 3, wherein a switching device is inserted between the common power source and each heating coil of the C-type inductor for independently connecting and disconnecting the C-type inductor to and from the common power source. Heater unit. 4. The apparatus of claim 3, further comprising: switching means interposed between the common power source and each heating coil of the C-type inductor for independently connecting and disconnecting the C-type inductor to and from the common power source; And a matching device inserted between the common power supply and the switching means to match the impedance before the C-type inductor is switched to another C-type inductor with the impedance after the C-type inductor is switched to another C-type inductor. Induction heater apparatus, characterized in that. 2. The C-shaped iron core of claim 1, wherein the C-shaped iron core has a U-shaped iron core having a pair of horizontal portions and a vertical portion formed in combination with the U-shaped body, and is provided receivably at an upper horizontal end portion. Iron core, second iron core detachably provided at the end of the lower horizontal portion; And each of the first and second iron core angles includes a block iron core including a flake silicon steel sheet, and a water cooling structure for passing cooling water through the block iron core. 7. The block core of claim 6, wherein the block iron core comprises a block iron core element in the form of a rectangular parallelepiped and having a flake silicon steel sheet; A pair of adjacent plates supporting the block iron core elements between the adjacent plates in the lamella direction; And a semi-cylindrical iron core element and a radial flake silicon steel plate positioned outside each of the adjacent plates. 7. The block core of claim 6, wherein the block iron core comprises a block iron core element in the form of a rectangular parallelepiped and having a flake silicon steel sheet; A pair of adjacent plates supporting the block iron core elements between the adjacent plates in the lamella direction; And a semi-cylindrical iron core element and a radial flake silicon steel plate located outside of each adjacent plate; And the water cooling structure has a water cooling pipe attached to the corner portion of each adjacent plate to pass water, and a plurality of cooling fins are attached to the water cooling pipe, characterized in that each semi-cylindrical iron core element is separated into a plurality of radial zones Induction heater device. The method of claim 6, wherein the block iron core comprises a cylindrical iron core element comprising a radial flake silicon steel sheet; The water cooling structure has a central water cooling pipe inserted in the middle portion of the cylindrical iron core element for passing water, and a plurality of cooling fins are attached to the central water cooling pipe to separate the cylindrical iron core element into a plurality of radial zones. Induction heater device, characterized in that the branch pipe is attached to the corner of the cooling fins for passing the water supplied from the central water cooling pipe. 2. The apparatus of claim 1, further comprising: adjusting means for adjusting a distance of a gap between first and second iron core angles of each C-type inductor; The C-shaped iron core is divided into an upper iron core element having a first iron core angle and a lower iron core element having a second iron core angle; And the adjusting means includes a hinge for rotating and supporting the upper iron core element and the lower iron core element, and a hinge having a rotatable first hinge portion, wherein the rotatable first hinge has an end portion of the upper iron core element opposite to the first iron core angle. Has a curved surface; And the rotatable second hinge portion forms an end of the lower iron core element opposite the second iron core angle and is a curved surface on which the actually rotatable second hinge portion can rotate without changing the gap between the rotatable first and second hinge portions. Induction heater apparatus characterized by having 12. The rotatable second hinge portion of claim 10, wherein the cross-sectional area of the rotatable first hinge portion and its proximal portion is larger than the cross-sectional area of the upper iron core element portion stretched between the rotatable first hinge portion and the first iron core angle. Induction heater apparatus, characterized in that the cross-sectional area of the proximal portion of the thing is larger than the cross-sectional area of the lower iron core element portion tensioned between the rotatable second hinge portion and the second iron core angle. 11. The method of claim 10, wherein the adjusting means has a first hinge axis for rotating and supporting the rotatable first hinge portion of the upper iron core element, and the adjusting means has a second hinge axis for rotating and supporting the rotatable second hinge portion of the lower iron core element. An induction heater apparatus, comprising: a drive unit for transmitting torque to a first gear attached to a hinge side, a second gear attached to a second hinge shaft, and hung like a first gear; and a first or second hinge shaft. . The fireproof plate of claim 1, wherein the fireproof plate is provided at each end of the first and second iron cores to protect the C-type inductor from heat emitted from the reheating object, wherein the fireproof plate comprises a thermal nonconductive plate made of a thermally conductive material. And an area corresponding to each of said ends of the first and second iron cores opposed to the object, including a channel provided in the fireproof plate for cooling water to flow, and the channel being prevented from induction heating. Induction heater device. The induction heater apparatus according to claim 13, wherein the water channel comprises a water-cooled pipe formed of a nonmetallic tube and embedded in a fireproof plate. The induction heater apparatus according to claim 14, wherein the water-cooled pipe is formed of a synthetic tube, a ceramic pipe, or a quartz pipe. 14. A water channel according to claim 13, characterized in that the channel consists of a plurality of nonmetallic tubes embedded in a fireproof plate arranged in parallel with each other, and a pair of pipes formed of nonmetallic pipes embedded in the fireproof plate so as to communicate with both ends of the nonmetallic tube, respectively. Induction heater device. In the induction heating method, a plurality of C-type inductors arranged parallel to the moving direction of the object to heat the corner portions of the moving reheating object, and each having an upper portion having a first iron core disposed separately throughout the object. A lower iron core element having an iron core element, and an edge portion of the inserted object and having a second iron core angle opposite the first iron core, and a heating coil wound on the upper and lower iron cores, respectively; Adjusting means for adjusting the gap of the gap formed between the first and second iron core angles of each C-type inductor, adjusting means including a hinge for rotating and supporting the upper iron element and the lower iron core element, The hinge consists of an end of the opposing upper iron core element and has a curved rotatable first hinge portion, and the end of the lower iron core element opposes the second iron core angle and forms a gap between the rotatable first and second hinge portions. A rotatable second hinge portion having a curved surface that can actually rotate the rotatable second hinge portion without modification; And at least one power source for supplying a high frequency current to the heating coil of the C-type inductor to generate magnetic flux; And the cross-sectional area of the rotatable first hinge portion and its proximal portion is larger than the cross-sectional area of the upper iron core element portion extending between the rotatable first hinge portion and the first iron core angle, and between the rotatable second hinge portion and the second iron core angle. An induction heater apparatus, characterized in that it is larger than the cross-sectional area of the lower iron core element to tension. 18. The method of claim 17, wherein the adjusting means comprises a first hinge axis for rotating and supporting the first rotatable hinge portion of the upper iron core element, and the second hinge axis for rotating and supporting the second rotatable hinge portion of the upper iron core element. And a first gear, attached to the first hinge shaft, and the second gear is attached to the second hinge shaft and bite with the first gear, and a drive unit for transmitting torque to the first or second hinge shaft. Induction heater device, characterized in that consisting of. 19. The induction heater apparatus according to claim 18, wherein the diameter of the first gear is set smaller than the diameter of the second gear, and the drive unit transmits torque to the first hinge shaft. 18. The fireproof plate of claim 17, wherein a fireproof plate is provided at each end of the first and second iron cores to protect the C-type inductor from heat released from the reheating object, the fireproof plate being a thermally conductive plate made of a thermally conductive material. And a channel corresponding to each one end of the first and second iron cores facing the object, the channel including a channel provided in the fireproof plate for penetrating cooling water, wherein the channel is prevented from induction heating. Induction heater device characterized in that. 21. The induction heater apparatus according to claim 20, wherein the channel includes a water-cooled pipe formed of a nonmetallic tube and embedded in the fireproof plate. The induction heater apparatus according to claim 21, wherein the water-cooled pipe is formed of a synthetic tube, a ceramic pipe, or a quartz pipe. 21. The non-metal tube of claim 20, wherein the channel consists of a plurality of non-metallic tubes embedded in the inner plate so that the tube sections are arranged parallel to each other. Induction heater device characterized in that the communication. In order to protect the induction unit integrated with the induction heater device from the heat emitted from the reheating object, the fireproof plate is made of a thermally conductive plate made of a thermally conductive material, each end of the first and second iron cores facing the object. Has an area corresponding to; And a channel provided in the refractory plate for inducing the cooling water through and insulated from the heat in the induction heating method. The induction heater apparatus according to claim 24, wherein the channel includes a water-cooled pipe formed of a nonmetallic tube and embedded in the fireproof plate. The induction heater apparatus according to claim 25, wherein the water-cooled pipe is formed of a synthetic tube, a ceramic pipe, or a quartz pipe. The induction heater apparatus according to claim 25, wherein the water-cooled pipe is formed of a corrugated tube. The induction heater apparatus according to claim 25, wherein the water cooling pipe has a plurality of fins formed in combination with the outer periphery of the water cooling pipe. 25. The method of claim 24, wherein the channel includes at least one nonmetallic tube embedded in the fireproof plate so that the at least one nonmetallic tube portion is arranged in parallel with each other, and a pair of header pipes formed of nonmetallic pipes and inserted into the fireproof plate are provided. Induction heater device characterized in that it is in communication with each of the opposite ends of the at least one non-metallic tube. ※ Note: The disclosure is based on the initial application.