KR102185197B1 - Inductive heating device - Google Patents

Abstract

The present invention relates to an induction heating apparatus, and more particularly, a power supply source; And a heating coil connected to the power supply source and having a connection part including a corrugated pipe and a heating part for performing heating by electric power supplied through the connection part from a power supply source. And a position correction unit fixed to the connecting portion of the heating unit side of the corrugated pipe and having an x-axis moving unit and a y-axis moving unit, and includes, the length and left and right of the corrugated pipe according to the positional movement of the x-axis and y-axis moving means It relates to an induction heating apparatus that allows the heating element to have a uniform temperature distribution by adjusting the temperature and to obtain a glass substrate having high strength by performing uniform chamfering when used for chamfering of glass.

Description

Induction heating device {INDUCTIVE HEATING DEVICE}

The present invention relates to an induction heating device.

In a wide range of technologies and industries, such as video and optical equipment such as monitors, cameras, VTRs, mobile phones, transportation equipment such as automobiles, various tableware, and construction facilities, glass products are treated as essential components, and accordingly, the characteristics of each industrial field. Glass having various physical properties has been manufactured and used according to the requirements.

Among these, the touch screen is drawing attention as a core component of video equipment. A touch screen is a display and input device that is installed on a terminal monitor and allows a computer to perform specific commands by inputting various data such as simple contact or drawing characters or pictures using auxiliary input means such as a finger or a pen. Such a touch screen is increasingly important as a core component for various digital devices that transfer or exchange information with one or both sides such as mobile communication devices such as smartphones, computers, cameras, issuing machines such as certificates, and industrial equipment. The range is expanding rapidly.

Among the components constituting such a touch screen, the upper transparent protective layer that the user directly contacts is mainly a plastic organic material such as polyester or acrylic, and these materials are poor in heat resistance and mechanical strength, so they are deformed due to continuous and repeated use and contact. There are limitations in durability, such as damage, scratches, or damage. Therefore, the upper transparent protective layer of the touch screen is gradually being replaced by a reinforced thin plate glass having excellent heat resistance, mechanical strength and hardness from the existing transparent plastic. In addition, tempered thin glass is gradually expanding its use area by serving as a transparent protective window for LCD or OLED monitors in addition to touch screens.

When the tempered glass is cut, it is destroyed as an irregular fragment that is not the intended shape due to the large compressive stress existing on the surface, or even if it is cut in the intended shape, it compresses a large area within a range of about 20 mm left and right around the cutting line. Since the stress is lost and the strength decreases, it is difficult to cut it into a desired size or shape once it is strengthened, regardless of the composition of the glass.

Therefore, the cutting method of tempered glass requires very precise and strict conditions compared to the conventional cutting method of glass. The method introduced as a cutting method of this tempered glass is as follows.

First, there is a mechanical cutting method. In this manner, a diamond or carbide grading wheel is dragged across the glass surface to mechanically engrave a scale on the glass plate, which is then cut by bending the glass plate along the scale to create a cut edge. Typically, the mechanical cutting method as described above creates a lateral crack of about 100 to 150 μm in depth, and the crack is generated from the cutting line of the grasping wheel. Since the lateral crack decreases the strength of the window substrate, it must be removed by polishing the cut portion of the window substrate.

However, the above-described mechanical cutting method has a disadvantage that expensive cutting wheels need to be replaced over time, and precise cutting is not easy.

Next, there is a non-contact cutting method using a laser. In this method, when the laser expands the glass surface by moving along a predetermined path on the glass surface through a check in the edge of the window substrate, the cooler moves along and stretches the surface, thereby following the path of the laser. The crack is thermally propagated to cut the window substrate.

On the other hand, the cut surface of the tempered glass is sharp and the surface is uneven, so it is vulnerable to external impact, so it must undergo a chamfering process.

The chamfering process is generally performed by rotating a polishing wheel to process the cut, that is, chamfering. Through the chamfering process, the smoothness of the cut portion is improved and the strength is increased, but it has been difficult to provide a window substrate having excellent strength by the conventional chamfering process.

Korean Patent No. 1076105 discloses an edge grinding and/or polishing mechanism and method of a thin glass plate.

Korean Patent Registration No. 1076105

An object of the present invention is to provide an induction heating device capable of obtaining a heating element having a uniform temperature distribution.

An object of the present invention is to provide an induction heating device capable of obtaining a uniform chamfering amount when used for chamfering a glass substrate by induction heating of a heating element.

1. Power source; And

A heating coil connected to the power supply source and having a connection part including a corrugated pipe and a heating part for performing heating by power supplied through the connection part from a power supply source; And

Includes; a position correction unit fixed to the corrugated pipe reference heating unit side connection and having an x-axis moving unit and a y-axis moving unit,

Induction heating device capable of adjusting the length and left and right of the corrugated pipe according to the positional movement of the x-axis and y-axis moving means.

2. In the above 1, the x-axis moving means includes a first stage moving in the x-axis according to the rotation of the first motor and the first motor, and the y-axis moving means is the rotation of the second motor and the second motor. And a second stage that moves along the y-axis according to the induction heating apparatus.

3. The induction heating apparatus according to the above 2, wherein the y-axis moving means is fixed to the heating part side connection, and the y-axis moving means is movable in the y-axis according to the linear guide rail on the x-axis moving means.

4. The induction heating apparatus according to the above 2, wherein the x-axis moving means is fixed to the heating part side connection, and the x-axis moving means is movable in the x-axis according to the linear guide rail on the y-axis moving means.

5. The induction heating device of any one of 1 to 4 above, and

A glass chamfering apparatus comprising a heating element that is heated by a heating coil to chamfer the glass.

6. In the above 5, the imaging device for imaging the heating element and the heating coil from the upper or lower side of the heating element;

A control device that calculates a degree of shift between the center of the heating element and the center of the heating unit of the heating coil in the captured image received by the imaging device, and controls the x-axis moving unit or the y-axis moving unit according to the calculated value. , Glass chamfering device.

7. Positioning the heating element so that the heating unit of the induction heating device of any one of the above 1 to 4 surrounds the heating element by being spaced apart from the heating element by a predetermined distance;

Imaging the heating element and the heating coil from the upper or lower side of the heating element;

Calculating a degree of deviation between the center of the heating element and the center of the heating unit of the heating coil from the captured image; And

And matching the center of the heating element and the heating unit by moving the x-axis or y-axis moving means according to the degree of shift, and adjusting the length and left and right of the corrugated pipe.

According to the present invention, the center of the heating coil and the center of the heating element are exactly aligned, so that the heating element has a uniform temperature distribution. When this is used for chamfering of glass, uniform chamfering can be performed, thereby obtaining a glass substrate having high strength.

1 is a diagram schematically showing a heating element heated by a high frequency induction heating method.
FIG. 2 is a diagram schematically illustrating a chamfering method in which the heating element is moved while contacting the glass substrate to remove the edge where the horizontal and vertical surfaces of the glass substrate intersect in a strip shape by thermal stress.
3 is a view showing a temperature distribution of the heating element when the center of the induction coil and the center of the heating element do not match.
4 is a schematic plan view of an induction heating device according to an embodiment of the present invention.
5 is a schematic left side view of an induction heating device according to an embodiment of the present invention.
6 shows a corrugated pipe in the heating coil of the induction heating device according to an embodiment of the present invention.
7 is a front view of a position correction unit of an induction heating device according to an embodiment of the present invention.
8 is a schematic perspective view of a position correction unit of an induction heating device according to an embodiment of the present invention.

The present invention is a power supply source; And a heating coil connected to the power supply source and having a connection part including a corrugated pipe 33 and a heating part for performing heating by electric power supplied through the connection part from a power supply source. And a position correction unit fixed to the connecting portion of the heating unit side of the corrugated pipe and having an x-axis moving unit and a y-axis moving unit, and includes, the length and left and right of the corrugated pipe according to the positional movement of the x-axis and y-axis moving means It relates to an induction heating apparatus that allows the heating element to have a uniform temperature distribution by adjusting the temperature and to obtain a glass substrate having high strength by performing uniform chamfering when used for chamfering of glass.

The present invention relates to an induction heating device, which can be utilized when chamfering a glass substrate by electromagnetic induction heating of a heating element.

In the method of chamfering a glass substrate by induction heating, as shown in Figs. 1 and 2, the heating element 10 heated by electromagnetic induction by the heating coil 30 is brought into contact with the edge of the glass substrate 20 to prevent thermal stress. It is a method of chamfering the glass substrate 20 by cutting the edge part of the glass substrate 20 by this. When the heated heating element 10 is brought into contact with the edge of the glass substrate 20, due to the nature of the glass with a low heat transfer rate, thermal stress is generated at the edge where the heating element 10 is in contact, so that the portion from the contacting portion of the heating element to a predetermined depth is Fall off. Therefore, when the heating element 10 moves while in contact along the edge of the glass substrate 20, the edge of the glass substrate 20 may be chamfered.

This method fundamentally suppresses the generation of glass dust, and since the chamfered portion falls off in the form of a strip due to thermal stress, harmful elements such as cracks remaining on the edge of the glass can be removed without the use of hydrofluoric acid and reinforcing agents.

However, in this method, a uniform heat distribution of the heating element 10 is important. When the center of the heating element 10 is shifted from the center of the heating coil 30 as shown in FIG. 3, a portion close to the coil 30 is at a high temperature. However, the temperature of the part far from the coil 30 is lowered. When chamfering the glass substrate 20 with the heating element 10 having such a temperature distribution, there is a problem that chamfering is not uniformly performed.

However, in the present invention, the center of the heating element 10 and the center of the heating coil 30 are matched, so that the heating element 10 has a uniform temperature distribution, and thus, when used for chamfering the glass substrate 20, the Allows chamfering to be performed.

An induction heating device according to an embodiment of the present invention includes a power supply source, a heating coil, and a position correction unit.

FIG. 4 is a plan view of an induction heating device according to an embodiment, and FIG. 5 is a left side view, and with reference thereto, an induction heating device according to an embodiment of the present invention will be described in detail.

The power supply source 40 supplies electric power to the heating coil 30 so that the heating unit 32 of the heating coil 30 can heat the object to be heated.

The heating coil 30 has a connection part 31 and a heating part 32.

The connection part 31 may be connected to the power supply source 40 to receive power from the power supply source 40.

The connection part 31 includes a corrugated pipe 33 as illustrated in FIG. 6.

The corrugated pipe 33 can be adjusted in length and vertically, horizontally and vertically, and thus the length and left and right can be adjusted according to the positional movement of the position correction unit 50 to be described later. This will be described in detail later.

The heating unit 32 may perform heating by power supplied through the connection unit 31.

The heating part 32 may be directly connected to the connection part 31 to receive power, or may receive power indirectly through a separate conductor therebetween.

The position correction part 50 is fixed to the connection part 31 on the side of the heating part 32 on the basis of the corrugated pipe 33, and includes an x-axis moving unit 51 and a y-axis moving unit 52.

The connection part 31 is connected to and fixed to the power supply source 40, and the position correction part 50 is fixed to the connection part 31 on the heating part 32 side of the corrugated pipe 33. Accordingly, the length or the left and right of the corrugated pipe 33 is adjusted according to the positional movement of the x-axis or y-axis moving means 52, but the heating unit 32 without changing the rest of the heating coil 30 Position can be adjusted.

In the case of the position correction unit 50, as long as it is fixed to the portion and can move the portion in the x-axis and y-axis, the moving means is not particularly limited, and the implementation method thereof is not limited.

According to one embodiment, as illustrated in FIGS. 7 and 8, the y-axis moving means 52 is fixed to the heating part 32 side connection part 31, and the y-axis moving means 52 is an x-axis It can move in the y-axis according to the linear guide rail on the moving means 51. In such a case, the x-axis moving means 51 can move in the x-axis, and the y-axis moving means 52 is located on the x-axis moving means 51, and is attached to the linear guide rail on the x-axis moving means 51. You can move along the y-axis.

In terms of preventing the vertical movement of the corrugated pipe 33, the x-axis movement means 51 is preferably located on a fixed stage connected to the power supply source 40, and moves in the x-axis according to the linear guide rail on the fixed stage. May be.

In addition, according to another embodiment, on the contrary, the x-axis moving means 51 is fixed to the heating part 32 side connection part 31, and the x-axis moving means 51 is a y-axis moving means 52 ) It can also move in the x-axis according to the linear guide rail on the top.

In this case, on the contrary, the y-axis moving means 52 may be located on a fixed stage connected to the power supply source 40, and may move along the x-axis according to the linear guide rail on the fixed stage.

When explaining a specific example of the x-axis and y-axis moving means 52, for example, the x-axis moving means 51 moves in the x-axis according to the rotation of the first motor 51b and the first motor 51b. A first stage 51c may be provided. In addition, the y-axis moving means 52 may include a second motor 52b and a second stage 52c that moves in the y-axis according to the rotation of the second motor 52b.

In this case, the first stage 51c may move according to the linear guide rail on the second stage 52c, or conversely, the second stage 52c may move according to the linear guide rail on the first stage 51c.

In addition, the present invention provides a chamfering device for glass comprising the induction heating device.

The glass chamfering apparatus of the present invention includes a heating element 10 that is heated by the induction heating apparatus and the heating coil 30 to chamfer the glass.

As illustrated in FIG. 1, the heating element 10 may be positioned so that the heating unit 32 of the induction heating device is spaced apart from the heating element 10 by a predetermined distance to surround the heating element 10.

The heating element 10 is heated by induction heating, and it is possible to chamfer the glass by contacting it with a portion of the glass to be chamfered.

The chamfering device of the glass of the present invention includes an induction heating device in which the position of the heating unit 32 is easily adjusted, so that the center of the heating element 10 and the center of the heating unit 32 can be adjusted so that the center of the glass Uniform chamfering is possible.

The glass chamfering device of the present invention may further include an imaging device 60 and a control device 70 for ease of position adjustment.

The imaging device 60 captures an image of the heating element 10 and the heating coil 30.

The imaging is for obtaining an image for calculating the degree of shift of the center of the heating element 10 and the heating coil 30, and in terms of obtaining an image that is easy to calculate this, the imaging device includes the heating element 10 and the heating coil 30 ) It may be located on the upper side or the lower side, preferably vertically upper side or vertically lower side.

The control device 70 calculates the degree to which the center of the heating element 10 is shifted from the center of the heating unit 32 of the heating coil 30 in the captured image received by the imaging device 60.

By calculating this, it is possible to obtain the degree that the center of the heating element 10 and the center of the heating coil 30 are shifted in the x-axis and y-axis directions, and move the x-axis moving means 51 in the opposite direction by the shifted distance in the x-axis direction. It can be adjusted so that the center of the heating element 10 and the center of the heating unit 32 coincide with the center of the heating element 10 by moving the y-axis moving means 52 in the opposite direction by a distance shifted in the y-axis direction.

In addition, the present invention provides a heating coil position correction method.

According to one embodiment of the present invention, first, the heating element 10 is positioned so that the heating unit 32 of the induction heating device is spaced apart from the heating element 10 by a predetermined distance to surround the heating element 10.

In such a case, induction heating occurs by the power supplied from the power supply source 40, so that the heating element 10 can be heated.

Thereafter, the heating element 10 and the heating coil 30 are photographed.

This is to obtain an image for calculating the degree of shift of the center of the heating element 10 and the heating coil 30.

The imaging is for obtaining an image for calculating the degree of shift of the center of the heating element 10 and the heating coil 30, and in terms of obtaining an image that is easy to calculate this, the imaging is performed by the heating element 10 and the heating coil 30 It may be performed on the upper side or the lower side of the, and preferably may be performed on the vertical upper side or the vertical lower side.

The imaging may be performed through the imaging device 60 of the chamfering device including the induction heating device, but is not limited thereto.

Thereafter, from the captured image, the degree of deviation between the center of the heating element 10 and the center of the heating coil 30 is calculated.

Next, the centers of the heating element 10 and the heating unit 32 are matched by moving the x-axis or y-axis moving means 51, 52 according to the degree of shift, and adjusting the length and left and right of the corrugated pipe 33. .

The calculation and movement of the x-axis and y-axis moving means may be performed through the control device 70 of the chamfering device, but are not limited thereto.

In the above, preferred embodiments have been presented to aid in understanding of the present invention, but these embodiments are only illustrative of the present invention and do not limit the scope of the appended claims, and embodiments within the scope and spirit of the present invention It is obvious to those skilled in the art that various changes and modifications are possible, and it is natural that such modifications and modifications fall within the appended claims.

10: heating element 20: glass substrate
30: heating coil 31: connection
32: heating unit 33: corrugated pipe
40: power supply source 50: position correction unit
51: x-axis moving means 51a: linear guide rail
51b: first motor 51c: first stage
52: y-axis moving means 52a: linear guide rail
52b: second motor 52c: second stage
60: imaging device 70: control device

Claims (7)

Power source; And
A heating coil connected to the power supply source and having a connection part including a corrugated pipe and a heating part for performing heating by power supplied through the connection part from a power supply source; And
A position correction unit fixed to the connecting portion of the heating unit based on the corrugated pipe and having an x-axis moving unit and a y-axis moving unit; And
It is wrapped by the heating unit and includes a heating element that is heated by the heating unit to chamfer the glass,
A chamfering apparatus of glass, which adjusts the length and left and right of the corrugated pipe according to the positional movement of the x-axis moving means and the y-axis moving means provided in the position correction unit to match the center of the heating unit and the heating element.
The glass chamfering apparatus according to claim 1, wherein the y-axis moving means is fixed to the connecting part on the heating part side, and the y-axis moving means is movable along the y-axis along a linear guide rail on the x-axis moving means.
The glass chamfering apparatus according to claim 1, wherein the x-axis moving means is fixed to the connecting part on the side of the heating part, and the x-axis moving means is movable along the x-axis along a linear guide rail on the y-axis moving means.
The method according to claim 1, wherein the x-axis moving means includes a first stage that moves in the x-axis according to the rotation of the first motor and the first motor, and the y-axis moving means is applied to the rotation of the second motor and the second motor. A glass chamfering apparatus comprising a second stage that moves along the y-axis.
delete The apparatus according to claim 1, further comprising: an imaging device for imaging the heating element and the heating coil; And
A control device for calculating a degree of a shift between the center of the heating element and the center of the heating unit of the heating coil in the captured image received by the imaging device, and controlling the x-axis moving means or the y-axis moving means according to the calculated value. Further comprising, chamfering device of the glass.
Positioning the heating element so that the heating unit of the glass chamfering device according to claim 1 is spaced apart from the heating element by a predetermined distance to surround the heating element;
Imaging the heating element and the heating coil;
Calculating a degree of deviation between the center of the heating element and the center of the heating unit of the heating coil from the captured image; And
A step of matching the center of the heating element and the heating unit by moving the x-axis moving means or the y-axis moving means according to the degree of shift, and adjusting the length and left and right of the corrugated pipe. .

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