KR101393889B1 - Apparatus for Induction Heating - Google Patents

Abstract

The present invention relates to a heating apparatus for heating a heating body, comprising a first induction heating coil disposed at one side of a heating body, a second induction heating coil disposed at the other side of the heating body, Heating coil and the second induction heating coil are spaced apart from each other such that the first induction heating coil and the second induction heating coil are spaced apart from each other so as to pass between the first induction heating coil and the second induction heating coil, And an interval adjusting unit for moving at least one of the first induction heating coil and the second induction heating coil,
According to the present invention, since the energy efficiency transferred to the heating body is prevented from decreasing as the thickness of the heating body is changed, the accuracy of the operation for heating the heating body to the target temperature can be improved.

Description

[0001] Apparatus for Induction Heating [0002]

The present invention relates to an induction heating apparatus for heating a heating body using an induction coil.

Generally, an induction heating apparatus is a system for heating a heating body by using an eddy current generated by a current supplied to an induction coil. Such an induction heating apparatus supplies a high frequency alternating current to the induction coil to form a strong high frequency magnetic field around the induction coil, thereby heating the heating body positioned adjacent to the induction coil.

1 is a schematic perspective view of an induction heating apparatus according to the prior art.

Referring to FIG. 1, an induction heating apparatus 10 according to the related art includes an induction coil 11 for heating a heating body 100, an induction heating coil 12 provided with the induction coil 11, A power supply mechanism 13 for supplying a current to the coil 11 and a pedestal 14 in which the induction coil 11 and the power supply mechanism 13 are installed.

The induction coil 11 heats the heating body 100 using a current supplied from the power supply mechanism 13. [ The induction coil 11 is installed inside the induction heating coil 12.

The induction heating coil 12 is coupled to the pedestal 14 at a predetermined distance from the power supply mechanism 13. The induction heating coil 12 includes a through hole 121 through which the heating body 100 passes. The induction heating coil 12 is formed in a rectangular parallelepiped shape in which the through hole 121 is formed at the center. That is, the induction heating coil 12 is formed in the form of a "square" shape in the form of a closed square ring. The induction coil 11 is installed in the induction heating coil 12 so as to surround the heating body 100 passing through the through hole 121.

The power supply mechanism (13) supplies current to the induction coil (11). When a high frequency current supplied from the power supply mechanism 13 flows into the induction coil 11, a strong high frequency magnetic field is formed around the induction coil 11, .

The pedestal (14) supports the induction coil (11) and the power supply mechanism (13). The induction coil 11 and the power supply mechanism 13 are fixedly coupled to the pedestal 14 by a predetermined distance from each other.

The distance between the heating body 100 and the induction coil 11 is determined by the distance from the induction coil 11 to the heating body 100 during the passage of the heating body 100 through the through- To the energy efficiency of the system. As described above, in the induction heating apparatus 10 according to the related art, the heating body 100 is heated while the heating body 100 passes through the through hole 121 formed in the induction heating coil assembly 12 , And the distance between the heating body 100 and the induction coil 11 is determined by the size of the through hole 121. Therefore, the induction heating apparatus 10 according to the prior art has the following problems.

First, the induction heating apparatus 10 according to the related art changes the energy efficiency to be transmitted from the induction coil 11 to the heating body 100 when the heating body 100 is changed to have a thickness thinner than the conventional one There is a problem that it is difficult to heat the heating body 100 to a target temperature. There is a method of reducing the speed at which the heating body 100 moves so that the heating time of the heating body 100 is increased by the induction coil 11. According to this, There is a problem that the production efficiency is lowered due to an increase in the processing time. There is a method of increasing the current supplied to the induction coil 11. However, according to the conventional induction heating apparatus 10, there is a problem that the energy consumption is increased and the process cost is increased.

Second, if the heating body 100 is changed to have a thicker thickness than the conventional heating body 10, the induction heating coil 10 must be replaced. Accordingly, the induction heating apparatus 10 according to the related art is costly to provide the induction heating coil 12 that is suitable for the thickness of the heated body 100, and the induction heating coil 12 is replaced The heating operation of the heating body 100 must be stopped during the heating operation.

Third, the heating body 100 may not be formed with a uniform thickness as a whole according to a manufacturing environment, or may have a thickness partially changed as an abnormal strain occurs even if the heating body 100 is formed with a uniform thickness. Accordingly, the induction heating apparatus 10 according to the related art has a problem that the portion of the heating body 100 whose thickness is thinned can not be heated to the target temperature. In the induction heating apparatus 10 according to the related art, when the portion of the heating body 100 where the thickness of the heating body 100 is increased is larger than the through hole 121, Or the like.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an induction heating apparatus capable of efficiently heating a changed heating body to a target temperature even if the heating body is changed to have a thinner thickness than conventional ones.

An object of the present invention is to provide an induction heating apparatus capable of preventing a loss in cost and working time for heating a changed heating body even if the heating body is changed to have a thicker thickness than the conventional one.

The present invention provides an induction heating apparatus capable of efficiently heating a heating body to a target temperature even when the heating body has a partly different thickness and preventing the heating body from being stuck or stuck in the induction heating coil will be.

In order to solve the above-described problems, the present invention can include the following configuration.

An induction heating apparatus according to the present invention includes: a first induction heating coil disposed at one side of a heating body; A second induction heating coil disposed on the other side of the heating body; Wherein the first induction heating coil and the second induction heating coil are separated from each other such that the heating body passes between the first induction heating coil and the second induction heating coil; And an interval for moving at least one of the first induction heating coil and the second induction heating coil so as to adjust the distance between the first induction heating coil and the second induction heating coil, And a control unit.

According to the present invention, the following effects can be obtained.

The present invention can improve the accuracy of the operation of heating the changed heating body to the target temperature by preventing the energy efficiency transferred to the changed heating body from being reduced even if the heating body is changed to have a thin thickness.

Even if the heating body is changed to have a thick thickness, the work for heating the changed heating body can be continuously performed, thereby preventing the loss in the working time, thereby improving the production efficiency.

The present invention can improve the accuracy of the work for heating the heating body to the target temperature even if the heating body has a partially different thickness and can improve the accuracy of the work for heating the heating body by preventing the heating body from being stuck or stuck Stability and production efficiency can be improved.

1 is a schematic perspective view of an induction heating apparatus according to the prior art;
2 is a schematic perspective view of an induction heating apparatus according to the present invention;
3 is a schematic exploded perspective view of the induction heating apparatus according to the present invention.
4 is a schematic side view of an induction heating apparatus according to the present invention
5 is a conceptual side view for explaining a coupling relation between the first induction heating coil and the support according to the present invention
Figure 6 is a schematic front view of an induction heating apparatus according to the present invention
7 is a conceptual side view for explaining a coupling relationship of the gap adjusting unit according to the present invention

Hereinafter, preferred embodiments of the induction heating apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a schematic perspective view of the induction heating apparatus according to the present invention, FIG. 3 is a schematic exploded perspective view of the induction heating apparatus according to the present invention, FIG. 4 is a schematic side view of the induction heating apparatus according to the present invention, FIG. 6 is a schematic front view of the induction heating apparatus according to the present invention, and FIG. 7 is a schematic front view illustrating a coupling relation of the gap adjusting unit according to the present invention As shown in Fig.

2 and 3, the induction heating apparatus 1 according to the present invention is for heating the heating body 100 by using an eddy current generated by the current supplied to the induction coil. The induction heating apparatus 1 according to the present invention heats the heating body 100 positioned adjacent to the induction coil by supplying a high frequency alternating current to the induction coil to form a strong high frequency magnetic field around the induction coil .

The induction heating apparatus 1 according to the present invention includes a first induction heating coil unit 2 located at one side of the heating body 100 and a second induction heating coil unit 2 located at the other side of the heating body 100 (2) and the second induction heating coil (3) are spaced apart from each other, and a second induction heating coil (2) And an interval adjusting portion 5 for adjusting the interval between the induction heating coils 3. [

The first induction heating coil 2 includes a first induction coil 21 (shown in FIG. 3) for heating the heating body 100. The first induction coil 21 is installed inside the first induction heating coil 2. The second induction heating coil 3 includes a second induction coil 31 (shown in FIG. 3) for heating the heating body 100. The second induction coil 31 is installed inside the second induction heating coil body 3. When the current is supplied to the first induction coil 21 and the second induction coil 31, the heating body 100 rotates around the first induction coil 21 and the second induction coil 31 And is heated as a strong high-frequency magnetic field is formed. The heating body 100 is heated while passing between the first induction heating coil body 2 and the second induction heating coil body 3.

The gap adjusting part 5 moves at least one of the first induction heating coil unit 2 and the second induction heating coil unit 3 to move the first induction heating coil unit 2 and the second induction heating coil unit 3, The gap between the induction heating coils 3 is adjusted. The gap adjusting unit 5 adjusts the distance between the first induction coil 21 and the heating body 100 and the distance between the second induction coil 31 and the heating body 100, Can be adjusted. Therefore, the induction heating apparatus 1 according to the present invention can achieve the following operational effects.

First, in the induction heating apparatus 1 according to the present invention, when the heating body 100 is changed to have a thinner thickness than the conventional heating body 100, the first induction heating coil unit 2 ) And the second induction heating coil (3) can be narrowed. The distance between the first induction coil 21 and the heating body 100 and the distance between the second induction coil 31 and the heating body 100 are changed, It can be adjusted to correspond to the thickness. Therefore, even if the heating body 100 is changed to have a small thickness, the induction heating apparatus 1 according to the present invention can prevent the heating body 100 from being deformed by the first induction coil 21 and the second induction coil 31, Can be prevented from being reduced. Accordingly, the induction heating apparatus 1 according to the present invention can accurately heat the modified heating body 100 to the target temperature even if the heating body 100 is changed to have a thin thickness. In this process, And the increase in the energy consumption can prevent the process cost from increasing.

Secondly, the induction heating apparatus 1 according to the present invention is characterized in that when the heating body 100 is changed to have a thicker thickness than that of the conventional heating body 100, the first induction heating coil unit 2 ) And the second induction heating coil (3) can be adjusted to widen. Accordingly, the induction heating apparatus 1 according to the present invention can be applied to the heating body 100 without changing the first induction heating coil unit 2 and the second induction heating coil unit 3, It is possible to respond easily. Therefore, the induction heating apparatus 1 according to the present invention can continuously perform the work for heating the heating body 100 even if the heating body 100 is changed to have a thick thickness, It is possible to improve the production efficiency.

Thirdly, the induction heating apparatus 1 according to the present invention may be configured such that a distance between the first induction coil 21 and the heating body 100 and a distance between the first induction coil 21 and the heating body 100, The interval between the first induction heating coil unit 2 and the second induction heating coil unit 3 can be adjusted so that the distance between the second induction coil 31 and the heating body 100 is kept constant. have. Therefore, the induction heating apparatus 1 according to the present invention can improve the accuracy of the work for heating the heating body 100, and in this process, as the processing time increases or the energy consumption increases, Can be prevented from increasing.

The induction heating apparatus 1 according to the present invention is characterized in that a thicker portion of the heating body 100 than the other portions of the heating body 100 enters between the first induction heating coil unit 2 and the second induction heating coil unit 3 , The gap between the first induction heating coil body (2) and the second induction heating coil body (3) can be increased. Accordingly, the induction heating apparatus 1 according to the present invention can prevent the heating body 100 from being stuck or caught in the first induction heating coil body 2 and the second induction heating coil body 3 . Accordingly, the induction heating apparatus 1 according to the present invention can improve the stability and the production efficiency for the work for heating the heating body 100.

Hereinafter, the first induction heating coil unit 2, the second induction heating coil unit 3, the support unit 4, and the gap adjusting unit 5 will be described in detail with reference to the accompanying drawings.

2 to 4, the first induction heating coil unit 2 is coupled to the support unit 4 at one side of the heating body 100. The first induction heating coil unit 2 is coupled to the support unit 4 on the opposite side of the second induction heating coil unit 3 with respect to the heating member 100. For example, when the first induction heating coil unit 2 is coupled to the supporter 4 such that the first induction heating coil unit 2 is positioned on the heating member 100, the second induction heating coil unit 3 is connected to the heating member 100, The support portion 4 may be connected to the lower portion of the support portion 4. The first induction heating coil body 2 may be formed in a rectangular shape as a whole.

The first induction coil 21 (shown in FIG. 3) is installed in the first induction heating coil 2. The first induction coil 21 may be electrically connected to the power supply unit 200 (shown in FIG. 2). The power supply unit 200 supplies a current to the first induction coil 21 and the second induction coil 31 to generate a strong current about the first induction coil 21 and the second induction coil 31 The heating body 100 positioned between the first induction coil 21 and the second induction coil 31 is heated by forming a high frequency magnetic field. The induction heating apparatus 1 according to the present invention may be configured as a separate facility from the power supply unit 200. The induction heating apparatus 1 according to the present invention may be configured to include the power supply unit 200.

The first induction heating coil unit 2 may include a first coil cover 22 on which the first induction coil 21 is installed. The first induction coil 21 is connected to the surface of the heating body 100 passing between the first induction heating coil body 2 and the second induction heating coil body 3 in a horizontal direction, And may be installed inside the cover 22. The first coil cover 22 may be formed in a rectangular shape as a whole.

The first induction heating coil 2 may include a first coupling mechanism 23 for coupling to the support 4. One side of the first coupling mechanism 23 is coupled to the first coil cover 22 and the other side is coupled to the support portion 4. [ Accordingly, when the first induction heating coil unit 2 is coupled to the support unit 4, the first coupling mechanism 23 is positioned between the first coil cover 22 and the support unit 4 .

2 to 4, the second induction heating coil unit 3 is coupled to the support unit 4 so as to be positioned on the other side of the heating member 100. The second induction heating coil unit 3, And the first induction heating coil 2 are coupled to the supporting part 4 at a predetermined distance from each other. Thus, the heating body 100 passes through a space S (shown in FIG. 4) in which the second induction heating coil body 3 and the first induction heating coil body 2 are spaced apart from each other, . The second induction heating coil 3 may be formed in a rectangular shape as a whole.

A second induction coil 31 (shown in Fig. 3) for heating the heating body 100 is installed in the second induction heating coil body 3. [ The second induction coil 31 is electrically connected to the power supply unit 200. The second induction coil 31 is arranged on the surface of the heating body 100 passing between the first induction heating coil body 2 and the second induction heating coil body 3 in a horizontal direction, And is installed inside the heating body 3. Accordingly, in the induction heating apparatus 1 according to the present invention, the second induction coil 31 and the first induction coil 21 can be implemented as a TF (Transverse Flux) type. Therefore, when current is supplied from the power supply unit 200 to the second induction coil 31 and the first induction coil 21, the second induction coil 31 and the first induction coil 21 The heating body 100 can be heated by forming a magnetic flux perpendicular to the surface of the heating body 100 in accordance with the right-hand rule of the ampere.

The second induction heating coil unit 3 may include a second coil cover 32 on which the second induction coil 31 is installed. The second induction coil 31 is arranged on the surface of the heating body 100 passing between the first induction heating coil body 2 and the second induction heating coil body 3 in a horizontal direction, And may be installed inside the cover 32. The second coil cover 32 may be formed in a rectangular shape as a whole.

The second induction heating coil 3 may include a second coupling mechanism 33 for coupling to the support 4. One side of the second coupling mechanism 23 is coupled to the second coil cover 32, and the other side is coupled to the support portion 4. [ Accordingly, when the second induction heating coil unit 3 is coupled to the support unit 4, the second engagement mechanism 33 is positioned between the second coil cover 32 and the support unit 4 .

Here, since the heating body 100 is subject to abnormal deformation, vibration, or shaking in the course of passing through the first induction heating coil body 2 and the second induction heating coil body 3, Can be sandwiched between the first induction heating coil 2 and the second induction heating coil 3. In this case, since the induction heating coil according to the prior art is formed in the form of a closed loop, the entire structure has to be disassembled in order to remove the heating coil 100 from the induction heating coil. Therefore, the induction heating apparatus according to the prior art has a problem of causing considerable working time and production loss in removing the heating body 100.

In order to solve this problem, the second induction heating coil 3 and the first induction heating coil 2 are arranged on the other side (A, shown in FIG. 4) opposite to one side of the support 4 So that they can be separated from each other on the support part 4 so as to be opened. Accordingly, if the heating body 100 is sandwiched between the second induction heating coil 3 and the first induction heating coil 2 due to abnormal deformation, vibration, shaking, or the like, The induction heating apparatus 1 can easily remove the heating body 100 through the other side A opened between the second induction heating coil body 3 and the first induction heating coil body 2 . Therefore, the apparatus 1 for induction heating according to the present invention is characterized in that it comprises means for removing the heating body 100 from between the first induction heating coil 2 and the second induction heating coil 3, The productivity can be improved, and the production loss can be reduced by reducing the time taken to remove the heating body 100.

2 to 4, the support portion 4 supports the first induction heating coil body 2 and the second induction heating coil body 3. The supporting part 4 is formed in the first induction heating coil 2 and the second induction coil 31 so that the first induction coil 21 and the second induction coil 31 are positioned opposite to each other with respect to the heating body 100, The second induction heating coil 3 can be supported. Therefore, the heating body 100 passes through the space between the first induction heating coil 2 and the second induction heating coil 3 while passing through the first induction coil 21 and the second induction coil 3 31). The support portion 4 may be formed in a rectangular shape as a whole.

2 to 5, the supporting portion 4 may include a first supporting mechanism 41 for supporting the first induction heating coil 2.

The first supporting mechanism 41 can support the first induction coil 21 (shown in Fig. 3) on one side of the heating body 100 by supporting the first coupling mechanism 23 have. The first coupling mechanism 23 may be detachably coupled to the first support mechanism 41. Accordingly, the induction heating apparatus 1 according to the present invention can prevent the heating body 100 from being deformed or deformed in the course of passing through the first induction heating coil body 2 and the second induction heating coil body 3 Heating coils 2 and the second induction heating coil unit 3 as the first induction heating coil unit 2 and the second induction heating coil unit 3 are oscillated or vibrated, The heating body 100 can be easily removed. Therefore, the apparatus 1 for induction heating according to the present invention is characterized in that it comprises means for removing the heating body 100 from between the first induction heating coil 2 and the second induction heating coil 3, The productivity can be improved, and the production loss can be reduced by reducing the time taken to remove the heating body 100. In addition, the induction heating apparatus 1 according to the present invention can improve the ease of operation for replacing the first induction heating coil 2 when the first induction heating coil 2 is damaged.

The first support mechanism 41 includes a first support member 411 (shown in Fig. 3) and a second support member 412 (shown in Fig. 3) for supporting the first induction heating coil 2, . ≪ / RTI >

The first support member 411 can be inserted into the first insertion groove 231 of the first induction heating coil assembly 2 to support the first induction heating coil assembly 2. [ The first insertion groove 231 may be formed in the first coupling mechanism 23. A plurality of the first insertion grooves 231 may be formed in the first coupling mechanism 23. The first insertion grooves 231 are formed in the moving direction in which the heating body 100 moves in order to pass between the first induction heating coil body 2 and the second induction heating coil body 3 Direction). The first support member 411 may be formed in a cylindrical shape having a long length in the movement direction (X-axis direction) of the heating body 100 so as to be inserted into the first insertion grooves 231.

The second support member 412 can be inserted into the second insertion groove 232 of the first induction heating coil body 2 to support the first induction heating coil body 2. [ The second insertion groove 232 may be formed in the first coupling mechanism 23. A plurality of the second insertion grooves 232 may be formed in the first coupling mechanism 23. The second insertion grooves 232 may be formed such that the heating elements 100 are spaced apart from each other in the movement direction (X-axis direction) of the heating body 100. The second support member 412 may be formed in a cylindrical shape having a long length in the movement direction (X-axis direction) of the heating body 100 so as to be inserted into the second insertion grooves 232.

The second support member 412 and the first support member 411 are spaced apart from each other by a predetermined distance. The first induction heating coil unit 2 and the second induction heating coil unit 3 are spaced apart in the vertical direction (Z-axis direction) perpendicular to the movement direction (X-axis direction) of the heating body 100 The second support member 412 and the first support member 411 may be spaced apart from each other in the vertical direction (Z-axis direction). The first insertion groove 231 and the second insertion groove 232 may be formed to be perpendicular to each other. For example, the first insertion groove 231 is formed in the first direction (arrow B direction, shown in FIG. 5) toward the first induction heating coil body 2 from the second induction heating coil body 3 The first engaging mechanism 23 may be provided with a first engaging portion 23a. In this case, the second insertion groove 232 is formed in the first induction heating coil body 2 so as to face the first supporting coil 4 in the second direction (arrow C direction, Can be formed in the coupling mechanism (23). Accordingly, the first induction heating coil body 2 is supported by the second support member 412 and the first support member 411 by weight, and thereby the first induction heating coil body 2 is firmly fixed to the first support mechanism 41 Can be combined. The first induction heating coil 2 may be coupled to the second support member 412 and the first support member 411 so as to be easily separated from each other. Specifically, it is as follows.

First, when the first induction heating coil body 2 is coupled to the first support mechanism 41, as shown by the dotted line in FIG. 5, the first induction heating coil body 2, So that the first supporting member 411 is inserted into the groove 231. Thereafter, when the first induction heating coil body 2 rotates in the first rotation direction (R1 arrow direction, as shown in FIG. 5), the second support member 412 is inserted into the second insertion groove 232, . Therefore, the second support member 412 and the first support member 411 are formed such that rotation of the first induction heating coil unit 2 by the weight in the first rotation direction (arrow R1 direction) is restricted The first induction heating coil 2 can be supported. 5, the first induction heating coil unit 2 is supported by the second support member 412 and the first support member 411 by using the weight, 1 supporting mechanism 41. [0053] Therefore, the induction heating apparatus 1 according to the present invention can improve the easiness of the operation of coupling the first induction heating coil body 2 to the support portion 4. [ The first induction heating coil 2 can be moved by an operator or a transfer device (not shown).

Next, when the first induction heating coil unit 2 is separated from the first support mechanism 41, the first induction heating coil unit 2 is moved in the direction of the first support member 411 with respect to the first support member 411, (R2 arrow direction, shown in Fig. 5) opposite to the first rotation direction. Accordingly, the first induction heating coil body 2 can be separated from the second support member 412. [ Thereafter, when the first induction heating coil unit 2 moves in a direction away from the first support mechanism 41, the first induction heating coil unit 2 is moved from the first support member 411 And can be separated from the support portion 4 by being separated. The first induction heating coil 2 can be moved by an operator or a transfer device (not shown).

Therefore, the induction heating apparatus 1 according to the present invention can improve the ease of the operation of replacing the first induction heating coil 2 when the first induction heating coil 2 is damaged. In the induction heating apparatus 1 according to the present invention, when the heating body 100 passes through the first induction heating coil body 2 and the second induction heating coil body 3, Heating coil unit 2 is sandwiched between the first induction heating coil unit 2 and the second induction heating coil unit 3 as the first induction heating coil unit 2 and the second induction heating coil unit 3 are shaken, The heating body 100 can be easily removed.

Although not shown, the first induction heating coil body 2 is coupled to the first support mechanism 41 so as to be supported by the first support member 411 and the second support member 412, And may be fastened to the first support mechanism 41 by the same fastening means.

2 to 4, the support 4 may include a second support mechanism 42 for supporting the second induction heating coil 3.

The second supporting mechanism 42 supports the second coupling mechanism 33 so that the second induction coil 31 (shown in Fig. 3) can be supported on the other side of the heating body 100 have. The second coupling mechanism 33 may be detachably coupled to the second support mechanism 42. Therefore, the induction heating apparatus 1 according to the present invention can improve the easiness in the operation of replacing the second induction heating coil unit 3 when the second induction heating coil unit 3 is damaged.

The second support mechanism 42 may include a fixing protrusion 421 (shown in Fig. 3) for supporting the second induction heating coil body 3.

The fixing protrusion 421 can be inserted into the fixing groove 331 (shown in Fig. 3) of the second induction heating coil body 3 to support the second induction heating coil body 3. The fixing groove 331 may be formed in the second engaging mechanism 33. The fixing protrusions 421 may be formed in a rectangular shape. The fixing groove 331 may be formed in a size and shape corresponding to the fixing protrusion 421. The fixing protrusions 421 and the fixing grooves 331 may be formed in the vertical direction (Z-axis direction). When the second induction heating coil unit 3 is lowered while the fixing groove 331 is positioned above the fixing protrusion 421, the fixing protrusion 421 is fixed to the fixing groove 331, So that the second induction heating coil body 3 can be supported. Therefore, the second induction heating coil unit 3 can be coupled to the second support mechanism 42. [ When the second induction heating coil unit 3 is lifted in a state where the second induction heating coil unit 3 is coupled to the second support mechanism 42, The fixing groove 331 can be separated from the second supporting mechanism 42 by being separated from the fixing protrusion 421. [ Therefore, the induction heating apparatus 1 according to the present invention can improve the easiness in the operation of replacing the second induction heating coil unit 3 when the second induction heating coil unit 3 is damaged. The second induction heating coil 3 can be moved by an operator or a transfer device (not shown).

The second support mechanism 42 may include a plurality of the fixing protrusions 421. The fixing protrusions 421 may be spaced apart from each other in the moving direction (X-axis direction) of the heating body 100. The fixing protrusions 421 may be formed to face each other. Accordingly, when the second induction heating coil unit 3 is coupled to the second support mechanism 42, the second induction heating coil unit 3 can be positioned between the fixing projections 421 . A plurality of the fixing grooves 331 may be formed in the second coupling mechanism 33. The fixing grooves 331 are formed at positions corresponding to the positions where the second fixing protrusions 421 are formed so that the fixing protrusions 421 can be inserted.

Although not shown, the second induction heating coil unit 3 is coupled to the second support mechanism 42 so as to be supported by the fixing protrusions 421, and then is fastened to the second support mechanism 42 by fastening means such as bolts 42, respectively.

3, 6 and 7, the support portion 4 may include a support body 43 for supporting the first support mechanism 41 and the second support mechanism 42. [

The support main body 43 supports the first induction heating coil body 2 and the second induction heating coil body 3 by supporting the first support mechanism 41 and the second support mechanism 42, Can support. The support body 43 is provided with the first support mechanism 41 and the second support mechanism 43 so that the first induction heating coil body 2 and the second induction heating coil body 3 are positioned apart from each other by a predetermined distance, (42). The support body 43 may be formed as a generally rectangular parallelepiped.

The first support mechanism 41 may be movably coupled to the support body 43. The first support mechanism 41 may be moved by the gap adjusting unit 5 while being coupled to the support body 43. As the first support mechanism (41) moves, the first induction heating coil (2) can move. Accordingly, the induction heating apparatus 1 according to the present invention is arranged such that the interval D between the first induction heating coil unit 2 and the second induction heating coil unit 3, according to the thickness of the heating body 100 , Shown in Fig. 6). The first support mechanism 41 may be movably coupled to the support body 43 while a part of the first support mechanism 41 is inserted into the support body 43. When the first induction heating coil body 2 is positioned above the heating body 100 and the second induction heating coil body 3 is positioned below the heating body 100, The support mechanism 41 may be coupled to the support body 43 to be movable up and down.

The second support mechanism 42 may be movably coupled to the support body 43. The second support mechanism 42 may be moved by the gap adjusting unit 5 while being coupled to the support body 43. The induction heating apparatus 1 according to the present invention is capable of moving the second heating mechanism 3 according to the thickness of the heating body 100 The distance D between the first induction heating coil unit 2 and the second induction heating coil unit 3 can be adjusted. May be movably coupled to the support body 43 while being inserted into the support body 43. The first induction heating coil body 2 is positioned on the upper side of the heating body 100, When the second induction heating coil unit 3 is positioned below the heating body 100, the second support mechanism 42 can be coupled to the support body 43 in a liftable manner.

2 to 7, the gap adjusting part 5 is coupled to the supporting part 4. As shown in FIG. The gap adjusting unit 5 adjusts the thickness T of the heating body 100 by moving at least one of the first induction heating coil unit 2 and the second induction heating coil unit 3, (D) between the first induction heating coil unit (2) and the second induction heating coil unit (3) can be adjusted according to the position of the first induction heating coil unit (3).

The gap adjusting unit 5 moves the first induction heating coil unit 2 to move the gap D between the first induction heating coil unit 2 and the second induction heating coil unit 3 Can be adjusted. In this case, the gap adjusting unit 5 can move the first induction heating coil unit 2 by moving the first support mechanism 41. [0050] The gap adjusting portion 5 may adjust the distance D between the first induction heating coil 2 and the second induction heating coil 3 by moving the first supporting mechanism 41 up and down have.

The gap adjusting section 5 moves the second induction heating coil body 3 so that the gap D between the first induction heating coil body 2 and the second induction heating coil body 3 is It can also be adjusted. In this case, the gap adjusting unit 5 can move the second induction heating coil unit 3 by moving the second support mechanism 42. [0043] The gap adjusting portion 5 can adjust the distance D between the first induction heating coil 2 and the second induction heating coil 3 by moving the second supporting mechanism 42 up and down have.

The gap adjusting unit 5 moves both the first induction heating coil unit 2 and the second induction heating coil unit 3 so that the first induction heating coil unit 2 and the second induction heating coils The distance (D, shown in FIG. 6) between the coils 3 may be adjusted. In this case, the gap adjusting unit 5 moves the first support mechanism 41 and the second support mechanism 42 to move the first induction heating coil 2 and the second induction heating coil (3) can be moved. The gap adjusting unit 5 can move the first induction heating coil unit 2 and the second induction heating coil unit 3 by moving the first support mechanism 41 and the second support mechanism 42 up and down, And the distance D between the electrodes. The gap adjusting unit 5 can move the first induction heating coil unit 2 and the second induction heating coil unit 3 in directions opposite to each other. That is, the gap adjusting unit 5 can move the first induction heating coil unit 2 and the second induction heating coil unit 3 in a direction approaching each other or a direction away from each other. Therefore, the induction heating apparatus 1 according to the present invention is designed such that the distance D between the first induction heating coil 2 and the second induction heating coil 3 depends on the thickness of the heating body 100 By reducing the time taken to adjust, the production efficiency can be improved.

2 to 7, the gap adjusting portion 5 may include a first moving mechanism 51 (shown in FIG. 2) for moving the first induction heating coil 2.

The first moving mechanism (51) is coupled to the supporting part (4). The first moving mechanism (51) can move the first induction heating coil (2) by moving the first supporting mechanism (41). The first moving mechanism (51) may lift the first supporting mechanism (41). The first moving mechanism 51 includes a first power source 511 (shown in FIG. 7) that generates a driving force, a first rotating mechanism 512 (shown in FIG. 7) that is rotated by the first power source 511, And a first conversion mechanism 513 (shown in FIG. 7) for converting the linear motion of the rotary motion of the first rotation mechanism 512.

 The first power source 511 is coupled to the support body 43. The first power source 511 may cause the first conversion mechanism 513 to move along the first rotation mechanism 512 by rotating the first rotation mechanism 512. [ The first power source 511 may be coupled to the support body 43 so as to be positioned above the support body 43. The first power source 511 may be a motor.

The first rotating mechanism 512 is rotatably coupled to the support body 43. The first rotating mechanism 512 rotates by the driving force generated by the first power source 511. The first rotating mechanism 512 may be coupled to the support body 43 so as to be positioned inside the support body 43. The first rotating mechanism 512 may be a ball screw, a rolling screw, or the like. The first power source 511 may be directly coupled to the rotating shaft of the first rotating mechanism 512. When the first power source 511 and the first rotating mechanism 512 are installed at a predetermined distance from each other, the first moving mechanism 51 moves the first power source 511 and the first rotating mechanism (Not shown) for connecting the rotary shaft of the first and second rotary shafts 512 and 512 to each other. The first connecting means may be a pulley, a belt, or the like. When the first moving mechanism 51 moves up and down the first induction heating coil body 2, the first rotating mechanism 512 is coupled to the support body 43 in the vertical direction (Z-axis direction) .

One side of the first conversion mechanism 513 is coupled to the first rotation mechanism 512 and the other side is coupled to the first support mechanism 41. The first conversion mechanism 513 may convert the rotational motion of the first rotating mechanism 512 into a linear motion and move as the first rotating mechanism 512 rotates. The first support mechanism 41 moves as the first conversion mechanism 513 moves so that the first induction heating coil body 2 moves in the direction approaching the second induction heating coil body 3 Can move in a direction away from the second induction heating coil (3). The first conversion mechanism 513 is coupled to the first rotation mechanism 512 in accordance with the direction in which the first rotation mechanism 512 rotates or is coupled to the first rotation mechanism 512 in a straight line Can be moved. The first conversion mechanism 513 may be a ball nut, a rolled nut, or the like.

Although not shown, the first moving mechanism 51 may be a cylinder type using a hydraulic cylinder or a pneumatic cylinder, a gear type using a rack gear and a pinion gear, a belt using a pulley and a belt, The first induction heating coil 2 may be moved using a linear motor method or the like.

2 to 7, the gap adjusting portion 5 may include a second moving mechanism 52 (shown in FIG. 2) for moving the second induction heating coil 3.

The second moving mechanism (52) is coupled to the support part (4). The second moving mechanism (52) can move the second induction heating coil (3) by moving the second supporting mechanism (42). The second moving mechanism (52) may lift the second supporting mechanism (42). The second moving mechanism 52 includes a second power source 521 (shown in FIG. 7) that generates a driving force, a second rotating mechanism 522 (shown in FIG. 7) that is rotated by the second power source 521, And a second conversion mechanism 523 (shown in Fig. 7) for converting the linear motion of the rotational motion of the second rotating mechanism 522. In Fig.

 The second power source 521 is coupled to the support body 43. The second power source 521 may cause the second conversion mechanism 523 to move along the second rotation mechanism 522 by rotating the second rotation mechanism 522. [ The second power source 521 may be coupled to the support body 43 so as to be positioned above the support body 43. The second power source 521 and the first power source 511 may be coupled to the support body 43 at a predetermined distance from each other. The second power source 521 may be a motor.

The second rotating mechanism 522 is rotatably coupled to the support body 43. The second rotating mechanism 522 rotates by the driving force generated by the second power source 521. The second rotating mechanism 522 may be coupled to the support body 43 so as to be positioned inside the support body 43. The second rotating mechanism 522 may be a ball screw, a rolling screw, or the like. The second power source 521 may be directly coupled to the rotation axis of the second rotation mechanism 522. When the second power source 521 and the rotation shaft of the second rotation mechanism 522 are spaced apart from each other by a predetermined distance, the second movement mechanism 52 moves the second power source 521 and the second rotation mechanism (Not shown) for connecting the rotary shaft of the first and second rotary shafts 522 and 522. The second connecting means may be a pulley, a belt, or the like. When the second moving mechanism 52 moves up and down the second induction heating coil unit 3, the second rotating mechanism 522 is coupled to the support body 43 in the vertical direction (Z-axis direction) .

One end of the second conversion mechanism 523 is coupled to the second rotation mechanism 522, and the other end thereof is coupled to the second support mechanism 42. The second conversion mechanism 523 may convert the rotational motion of the second rotating mechanism 522 into a linear motion and move as the second rotating mechanism 522 rotates. The second support mechanism 42 moves as the second conversion mechanism 523 moves so that the second induction heating coil body 3 is moved in the direction approaching the first induction heating coil body 2 Can move in a direction away from the first induction heating coil (2). The second conversion mechanism 523 is coupled to the second rotation mechanism 522 in accordance with the direction in which the second rotation mechanism 522 rotates or is coupled to the second rotation mechanism 522 in a straight line Can be moved. The second conversion mechanism 523 may be a ball nut, a rolling nut, or the like.

Although not shown, the second moving mechanism 52 uses a cylinder system using a hydraulic cylinder or a pneumatic cylinder, a gear system using a rack gear and a pinion gear, a belt system using a pulley and a belt, or a linear motor system To move the second induction heating coil (3). When the gap adjusting unit 5 moves both the first induction heating coil unit 2 and the second induction heating coil unit 3, the second moving mechanism 52 and the first moving mechanism 51 can move the second induction heating coil unit 3 and the first induction heating coil unit 2 in directions opposite to each other.

6 and 7, the induction heating apparatus 1 according to the present invention includes a guide unit 7 for guiding the first induction heating coil unit 2 and the second induction heating coil unit 3 to move linearly, (6).

The guide portion 6 can guide the first induction heating coil 2 to move linearly by guiding the first supporting mechanism 41 to move linearly. The guide portion 6 may include a first guide block 61 installed on the first support mechanism 41 and a first guide rail 62 installed on the support body 43. The first guide block (61) is movably coupled to the first guide rail (62). The first guide rail 62 guides the first guide block 61 to move in a straight line. Accordingly, the first support mechanism 41 can be moved linearly along the first guide rail 62. Accordingly, the induction heating apparatus 1 according to the present invention is arranged such that the first induction heating coil unit 2 and the second induction heating coil unit 3 Can be precisely adjusted. Therefore, the induction heating apparatus 1 according to the present invention can improve the accuracy of the work for heating the heating body 100. [ The first guide block 61 may be an LM block and the first guide rail 62 may be an LM rail. The guide portion 6 may include a plurality of the first guide blocks 61 and the first guide rails 62 so as to guide both sides of the first support mechanism 41.

The guide portion 6 can guide the second induction heating coil body 3 to move linearly by guiding the second support mechanism 42 to linearly move. The guide portion 6 may include a second guide block 63 installed on the second support mechanism 42. The second guide block 62 may be movably coupled to the first guide rail 62. Accordingly, the second guide block 62 and the first guide block 61 may share the first guide rail 62. The first guide rail 62 guides the second guide block 63 to move in a straight line. Therefore, the second support mechanism 42 can be moved linearly along the first guide rail 62. Accordingly, the induction heating apparatus 1 according to the present invention is arranged such that the second induction heating coil unit 3 and the first induction heating coil unit 2 Can be precisely adjusted. Therefore, the induction heating apparatus 1 according to the present invention can improve the accuracy of the work for heating the heating body 100. [ The second guide block 63 may be an LM block. The guide portion 6 may include a plurality of the second guide blocks 63 so as to guide both sides of the second support mechanism 42. Although not shown, the guide portion 6 may include a second guide rail for guiding the second guide block 63 to move in a straight line.

2 and 4, the induction heating apparatus 1 according to the present invention may include a support mechanism 7 to which the support portion 4 is movably coupled.

The support mechanism (7) supports the support part (4). The support part 4 may be movably coupled to the support mechanism 7. [ The support portion 4 may be coupled to the support mechanism 7 so as to be movable in a direction (Y-axis direction) perpendicular to the movement direction (X-axis direction) of the heating body 100. Accordingly, the induction heating apparatus 1 according to the present invention is configured such that the support portion 4 is moved to the other side of the second induction heating coil 3 and the first induction heating coil 2, So that the heating body 100 can be easily removed through the heat exchanger (A). Therefore, the apparatus 1 for induction heating according to the present invention is characterized in that it comprises means for removing the heating body 100 from between the first induction heating coil 2 and the second induction heating coil 3, The productivity can be improved, and the production loss can be reduced by reducing the time taken to remove the heating body 100.

The support mechanism 7 can guide the support portion 4 to linearly move in the direction (Y-axis direction) perpendicular to the moving direction (X-axis direction) of the heating body 100. [ Therefore, the support mechanism 7 moves the support portion 4 so that the heating body 100 is again positioned between the first induction heating coil body 2 and the second induction heating coil body 3 The ease of operation can be improved. The supporting portion 4 can be moved by a separate conveying means (not shown). The conveying means may be a cylinder type using a hydraulic cylinder or a pneumatic cylinder, a gear type using a motor, a rack gear and a pinion gear, a ball screw type using a motor and a ball screw, a belt type using a motor, a pulley and a belt, The supporting part 4 can be moved by a method using a motor or the like. The support part 4 may be moved manually by an operator.

The support mechanism 7 may be formed as a rail so that the support portion 4 can be moved. In this case, the support part 4 may include a wheel (not shown) which can be moved along the support mechanism 7. [ The wheel is rotatably coupled to the support (4). The wheel can move along the support mechanism 7 while rotating as the support portion 4 moves. A plurality of the wheels may be coupled to the support portion 4. [

The support mechanism 7 can support the power supply device 200. In this case, as the support portion 4 moves, the power supply device 200 can move together. The power supply unit 200 may be supported on the support mechanism 7 so as to be positioned on the opposite side of the first induction heating coil unit 2 with respect to the support unit 4.

3, 6 and 7, the induction heating apparatus 1 according to the present invention includes a measuring unit 8 for measuring the thickness (T, shown in FIG. 6) of the heating body 100 6). ≪ / RTI >

The measuring unit 8 can measure the thickness T of the heating body 100 entering between the first induction heating coil unit 2 and the second induction heating coil unit 3. [ That is, the measuring unit 8 measures the thickness of the heating body 100 before the heating body 100 enters between the first induction heating coil body 2 and the second induction heating coil body 3 T) can be measured. In the case where the heating body 100 passes between the first induction heating coil unit 2 and the second induction heating coil unit 3, The thickness T can be measured with respect to a portion before entering between the first induction heating coil unit 2 and the second induction heating coil unit 3. [ The measuring unit 8 can measure the thickness T of the heating body 100 by using ultrasonic waves, radiation, magnetism, or the like. The measuring unit 8 may provide the measured thickness T of the heating body 100 to the gap adjusting unit 5 using at least one of wire communication and wireless communication.

The gap adjusting unit 5 is configured to move at least one of the first induction heating coil unit 2 and the second induction heating coil unit 3 according to the thickness T measured by the measurement unit 8 , The gap between the first induction heating coil unit 2 and the second induction heating coil unit 3 can be adjusted to correspond to the thickness T of the heating body 100. Therefore, the induction heating apparatus 1 according to the present invention can reduce the gap between the first induction heating coil 2 and the second induction heating coil 3 according to the thickness T of the heating body 100 3), thereby optimizing the energy efficiency transmitted to the heating body 100 from the first induction coil 21 (shown in Fig. 3) and the second induction coil 31 (shown in Fig. 3) It is possible. The gap adjusting unit 5 adjusts the gap between the first induction heating coil unit 2 and the second induction heating coil unit 3 which can optimize the energy efficiency according to the thickness T of the heating body 100. [ And a memory (not shown) for storing interval information.

In the induction heating apparatus 1 according to the present invention, even if the heating body 100 has a partly different thickness T, the induction heating apparatus 1 according to the present invention is not limited to a structure in which the first induction coil 21 and the heating body 100 And a distance between the first induction heating coil unit 2 and the second induction heating coil unit 3 so that a distance between the second induction heating coil unit 3 and the second induction coil 31 and the heating body 100 is kept constant, Can be adjusted in real time. Therefore, the induction heating apparatus 1 according to the present invention can improve the accuracy of the work for heating the heating body 100, and in this process, as the processing time increases or the energy consumption increases, Can be prevented from increasing.

The measuring unit 8 may be installed at one side of the first induction heating coil 2 or at one side of the second induction heating coil 3. One side of the first induction heating coil unit 2 and one side of the second induction heating coil unit 3 are connected to the first induction heating coil unit 2 and the second induction heating coil unit 3, Is a surface that faces toward the heating body 200 before it enters between the integrated bodies 3. The measuring unit 8 may be installed at a position spaced apart from the first induction heating coil unit 2 and the second induction heating coil unit 3. [ In this case, the measuring unit 8 may be installed in an apparatus which performs the pre-process on the heating body 100 before the heating body 100 is transferred to the induction heating apparatus 1 according to the present invention .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Will be clear to those who have knowledge of.

1: induction heating device 2: first induction heating coil 3: second induction heating coil
4: Support part 5: Spacing part 6: Guide part 7: Support mechanism
8: measurement unit 21: first induction coil 22: first coil cover 23: first coupling mechanism
31: second induction coil 32: second coil cover 33: second coupling mechanism
41: first supporting mechanism 42: second supporting mechanism 43: supporting body 51: first moving mechanism
52: second moving mechanism 61: first guide block 62: first guide rail
63: second guide block 100: heating body 200: power supply part

Claims (11)

A first induction heating coil disposed at one side of the heating body;
A second induction heating coil disposed on the other side of the heating body;
Wherein the first induction heating coil and the second induction heating coil are separated from each other such that the heating body passes between the first induction heating coil and the second induction heating coil; And
Heating coil and the second induction heating coil so that the distance between the first induction heating coil and the second induction heating coil is adjusted, ≪ / RTI >
The first induction heating coil includes a first insertion groove and a second insertion groove for inserting the support portion to be detachably coupled to the support portion;
Wherein the support portion includes a first support member to be inserted into the first insertion groove and a second support member to be spaced apart from the first support member in a direction in which the first induction heating coil and the second induction heating coil are spaced apart from each other 2 support member;
The first insertion groove is formed to be directed in a first direction from the second induction heating coil to the first induction heating coil to be supported by the first support member;
And the second insertion groove is formed in the second induction heating coil body so that the second induction heating coil body is detachably supported by the second induction heating coil body by the second induction heating coil body, Direction of the substrate. delete delete delete delete The method according to claim 1,
Wherein the second support member includes a first induction heating coil in which the first support member is inserted into the first insertion groove is rotatably supported by the first induction heating coil and the second induction heating coil, Wherein the first induction heating coil is inserted into the second insertion groove to limit rotation of the first induction heating coil in the first rotation direction by weight, Is separated from the second insertion groove when it is rotated in a second rotation direction opposite to the second rotation direction. The method according to claim 1,
The support portion includes a fixing protrusion for supporting the second induction heating coil,
Wherein the second induction heating coil includes a fixing groove into which the fixing protrusion is inserted,
And the fixing protrusion is inserted into the fixing groove to support the second induction heating coil. delete The method according to claim 1,
And a measuring unit for measuring the thickness of the heating body entering between the first induction heating coil and the second induction heating coil,
Wherein the gap adjusting unit adjusts the gap between the first induction heating coil and the second induction heating coil according to the thickness measured by the measuring unit. The method according to claim 1,
And a support mechanism in which the support portion is movably coupled in a direction perpendicular to a direction in which the heating body moves to pass between the first induction heating coil and the second induction heating coil;
Wherein the first induction heating coil and the second induction heating coil are spaced apart from each other to open the other side opposite to the one side facing the support;
Wherein the support mechanism comprises a rail,
Wherein the support comprises a wheel movable along the rail such that the heating body is removed from between the first induction heating coil and the second induction heating coil. delete

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