KR20150001050A - Apparatus for manufacturing vacuum pair glass - Google Patents

Abstract

In the present invention, disclosed is an apparatus for manufacturing vacuum multi-layer glass, comprising a vacuum chamber; a supporting tool which is installed in the vacuum chamber to support a plurality of sheets of vacuum multi-layer glass; and a capping tool which caps the capping member of the sheets of vacuum multi-layer glass supported by the supporting tool, wherein the capping tool has a plurality of first capping modules for supporting the capping members; and a second capping module which heats frit members coated on one side of each capping member supported by the first capping module and enables the frit members to pressurize the heated capping member toward the vacuum multi-layer glass. The disclosed apparatus for manufacturing vacuum multi-layer glass has the capping tool with mesh-shaped heating members to heat the capping member and frit member at the same time, thereby easily capping discharge holes on the vacuum multi-layer glass in a case of supporting various sized vacuum multi-layer glass by the supporting tool.

Description

[0001] APPARATUS FOR MANUFACTURING VACUUM PAIR GLASS [0002]

The present invention relates to an apparatus for producing a vacuum double-layered glass having a capping device capable of coping with vacuum double-layered glass of various sizes.

Generally, the vacuum double-layered glass is fused with a frit seal between the first and second glass plates which are disposed opposite to each other and spaced apart from each other by spacers to bond the first and second glass plates, The frit sealing member is cooled by blowing compressed air, air and gas inside the first and second glass plates bonded through the exhaust holes formed in one of the first and second glass plates are exhausted, and then the exhaust holes are exhausted using a capping member Followed by sealing.

The vacuum multilayer glass includes a vacuum chamber, a supporting device provided inside the vacuum chamber for supporting the vacuum multilayer glass, and a capping device for capping the exhaust hole of the vacuum multilayer glass supported by the supporting device using the capping member. And a vacuum double-layered glass manufacturing apparatus.

In this case, in order to seal the exhaust hole of each supporting device, each capping device corresponding to a plurality of vacuum multilayer glasses supported by the supporting device must be provided .

Conventionally, a vacuum double-layered glass of various sizes may be manufactured by changing the glass from time to time. In such a case, a capping device should be provided for each location corresponding to vacuum multi-layer glass of various sizes.

Particularly, conventionally, since the heating member and the pressing member for pressing the capping member to the exhaust hole side are provided as one unit, the frit member of the capping member sealing the exhaust hole is provided as a single unit, The above-mentioned units must be provided individually.

An embodiment of the present invention provides a vacuum double-layered glass manufacturing apparatus having a capping device capable of easily responding to vacuum double-layered glass of various sizes.

The apparatus for manufacturing a vacuum double-layered glass according to an embodiment of the present invention includes a vacuum chamber, a support device installed inside the vacuum chamber to support the plurality of vacuum multilayer glasses, And a capping device for capping the capping member of the capping member,

The capping device comprises:

A plurality of capping modules for supporting each of the capping members,

And a pressing module for simultaneously pressing the capping members supported by the capping modules toward the vacuum double-layered glass side.

According to the present invention, even when a plurality of vacuum multilayer glasses of various sizes are supported by the supporting device, the exhaust holes of each vacuum multilayer glass can be easily capped.

1 is a view showing a vacuum multilayer glass of the present invention.
2 is a view showing a vacuum double-layered glass manufacturing apparatus for producing a vacuum double-layered glass according to the present invention.
3 is a cross-sectional view showing a supporting device among the vacuum double-glazed glass manufacturing apparatus of the present invention.
4 is a cross-sectional view of a capping apparatus in a vacuum double-layered glass manufacturing apparatus of the present invention.
5 is a plan view showing a heating member of the vacuum double-layered glass producing apparatus of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. It is provided to fully inform the owner of the scope of the invention. Also, for convenience of description, the size of components may be exaggerated or reduced in the drawings, and like reference numerals refer to like elements throughout the specification.

1, the vacuum double-layered glass 10 includes first and second glass plates 11 and 12 arranged so as to face each other and a plurality of spacers 14 And a frit sealing member 13 for sealing the space between the first and second glass plates 11 and 12 by bonding the first and second glass plates 11 and 12 to each other.

The first glass plate 11 and the second glass plate 12 are disposed to face each other as described above and are spaced apart by a plurality of spacers 14 provided between the first and second glass plates 11 and 12 do. The first glass plate 11 disposed at least on the indoor space side of the first and second glass plates 11 and 12 may be a low-e glass having excellent heat insulating effect.

At least one of the first and second glass plates 11 and 12 may be provided with an exhaust hole 15 for forming a space between the first and second glass plates 11 and 12 as a vacuum layer. The exhaust hole 15 is preferably formed in the first glass plate 11 disposed below the first and second glass plates 11 and 12. A capping member 16 may be mounted on the exhaust hole 15.

The plurality of spacers 14 are disposed between the first and second glass plates 11 and 12 to separate the first and second glass plates 11 and 12 from each other. Each of the spacers 14 may have the same shape and size, and may be regularly arranged with a certain distance therebetween.

The frit sealing member 13 is disposed at the edge of the first glass plate 11 and serves to bond the first and second glass plates 11 and 12 separated by the plurality of spacers 14 to each other. The frit sealing member 13 is melted by the heating device 40 provided inside the vacuum chamber 20 to seal the first and second glass plates 11 and 12.

Referring to FIG. 2, an apparatus for manufacturing a vacuum double-layered glass according to an embodiment of the present invention includes a vacuum chamber 20 and a support device (not shown) for supporting a vacuum multilayer glass 10 transferred to the inside of the vacuum chamber 20. [ A heating device 40 for heating the frit sealing member 13 of the vacuum multilayer glass 10 supported by the supporting device 30 and a vacuum chamber 20 And a capping device 60 for capping the exhaust hole 15 formed in each vacuum double-layered glass 10 by using the capping member 16. The capping device 16 includes a capping device 60,

The vacuum chamber 20 is a chamber forming a space in which a work for manufacturing the vacuum double-layered glass 10 is made. In this vacuum chamber 20, at least a part of each device such as the supporting device 30, the heating device 40, the vacuum device 50, and the capping device 60 may be arranged therein. Reference numeral 21 denotes an exhaust port formed for evacuating the vacuum chamber 20.

The support device 30 serves to support the vacuum multilayer glass 10 which has entered the vacuum chamber 20 by a transfer robot (not shown) as described above. At this time, in one embodiment of the present invention, the supporting device 30 can support the vacuum double-layered glass in a state of being assembled. A plurality of spacers 14 are disposed between the first and second glass plates 11 and 12 in the vacuum bonded multilayer glass in the assembled state and a plurality of spacers 14 are disposed between the first and second glass plates 11 and 12, (13) is applied.

3, the support device 30 includes a plurality of trays 31 disposed inside the vacuum chamber 20 and a plurality of support pin units 33 ).

The tray 31 serves as a body of a supporting device for allowing the vacuum double-layered glass 10 to be supported inside the vacuum chamber 20. A plurality of such trays 31 may be installed in the vacuum chamber 20 as described above. For example, in the embodiment of the present invention, three trays 31 may be installed so as to be vertically spaced from each other.

As described above, a plurality of support pin units 33 are provided on the respective trays 31 to substantially support the vacuum double-layered glass 10. The plurality of support pin units 33 can elastically support the vacuum double-layered glass 10.

Specifically, each support pin unit 33 may include a body 34, a support pin 35, and a first elastic member 36 as shown.

The body 34 is provided on the upper surface of the tray 31 and has an inner space in which the support pins 35 are received.

The support pin 35 is accommodated in the body 34 as described above, and the upper end of the support pin 35 is protruded through the body 34. A quartz-shaped contact portion 37 may be provided on the upper surface of the support pin 35 to prevent the vacuum double-layered glass 10 from being damaged when the vacuum double-layered glass 10 is contacted.

The first elastic member 36 is provided on the lower side of the support pin 35 inside the body 34 to elastically support the support pin 35 when the vacuum multilayer glass 10 contacts the support pin 35 .

The operation and effect of the support pin unit 33 having the above-described structure will be described as follows.

The conventional vacuum double-layered glass 10 can be supported by the plurality of support pin units 33 while being bent by the load of the vacuum double-layered glass 10 when the size thereof is large. In this case, when each of the support pin units 33 is fixed at a predetermined height, a force exceeding a permissible value is applied to the contact portion between the bent portion and the support pin unit 33, so that the damage of the vacuum multilayer glass 10 may occur . In other words, in the central portion where the bending of the vacuum multilayer glass 10 is intensified, a load greater than that of the edge portion is applied, and the vacuum multilayer glass 10 may be damaged.

In order to overcome this, in the embodiment of the present invention, as each of the support pin units 33 elastically supports the respective portions of the vacuum double-layered glass 10, the bending of the vacuum double- Even if a force is applied, the vacuum double-layered glass 10 can be supported without being damaged.

In addition, the supporting device 30 may support a vacuum double-layered glass in a state before being assembled, not a vacuum double-layered glass in a state of being assembled. This supporting device comprises a first supporting member, not shown, but supporting the first glass plate 11 and a second supporting member supporting the second glass plate 12 and supporting the second glass plate 12 on the first supporting member And a second support member which vertically moves toward the glass plate 11.

In this case, a coating device (not shown) for applying the frit sealing member 13 to the edge of the first glass plate 11 supported by the first supporting member may be further provided in the vacuum chamber 20.

The second supporting member constructed as described above is formed by applying the frit sealing member 13 to the edge of the first glass plate 11 by the application device and then heating the frit sealing member 13 by the heating device 40 The second glass plate 12 can be vertically moved toward the first glass plate 11 and pressed. This is for joining the first and second glass plates 11 and 12 as the second glass plate 12 presses the heated frit sealing member 13.

2, the heating device 40 further comprises a heating and melting process of the frit sealing member 13 between the first and second glass plates 11 and 12 to seal the first and second glass plates 11 and 12 . The heating device 40 may be a laser irradiation device for irradiating an IR lamp or a laser, and various other means may be adopted as long as the frit sealing member 13 can be heated and melted smoothly in a vacuum environment.

In the case of the IR lamp, the heating device 40 may be installed on the entire inner surface of the vacuum chamber 20, that is, on the front, rear, left, right, upper, and lower surfaces. More specifically, the heating device 40 may be a plurality of heating members (IR lamps) installed on each side of the inner surface of the vacuum chamber.

The plurality of heating members may be arranged concentrically or concentrically in at least one of the inner surfaces of the vacuum chamber 20. In addition, the plurality of heating members may be arranged to form a plurality of rows and columns in at least one of the inner surfaces of the vacuum chamber.

The vacuum apparatus 50 includes a vacuum pump 51 for evacuating the air inside the vacuum chamber 20 to the outside, thereby making the inside of the vacuum chamber 20 a vacuum environment. That is, in the embodiment of the present invention, the inside of the vacuum chamber 20 is made to be a vacuum environment by the vacuum pump 51, and the exhaust holes 15 formed in at least one of the first and second glass plates 11 and 12 As a result of capping with the capping member 16, the space between the first and second glass plates 11 and 12 can be made into a vacuum layer.

The capping device 60 caps the exhaust holes 15 formed in the respective vacuum multilayer glass 10 to cover the inner spaces of the vacuum multilayer glass 10 such as the first and second glass plates 11 and 12 ) Into a vacuum layer.

The capping device 60 according to the embodiment of the present invention is provided so as to be able to smoothly correspond to each of vacuum-spliced glass 10 of various sizes that can be supported on the tray 31 of the individual unit of the supporting device 30 . In other words, the capping device 60 may be provided in a number corresponding to each tray 31.

It is preferable that the capping device 60 is disposed below each vacuum double-layered glass 10 supported by the supporting device 30. [ This may be achieved by clamping and pressing the capping member 16 prior to pressing the capping member 16 against the vacuum multilayer glass 10 when the capping device 60 is disposed above each vacuum double layer glass 10, 16), it is only necessary to support the capping member 16 when the capping device 60 is disposed under each vacuum double-layered glass 10.

2, 4, and 5, the capping device 60 is disposed at a position corresponding to the exhaust hole 15 of each vacuum multilayer glass 10 from below the vacuum multilayer glass 10 A pressing module 80 for pressing the capping member 16 supported by each capping module 70 toward the exhaust hole 15 by pressing each capping module 70, . ≪ / RTI >

The capping module 70 supports each capping member 16 for clamping the vacuum multilayer glass 10 supported by the tray 31 and for capping the exhaust hole 15 of each vacuum multilayer glass 10 And the role of melting the frit member 16a applied to each capping member 16 can be performed at the same time.

For this, the capping module 70 may include a clamping member 71, a fixing plate 72, a moving plate 73, a second elastic member 74, and a heating member 77.

The clamping member 71 serves to clamp the vacuum multilayer glass 10 supported by the supporting device 30 as shown.

The fixing plate 72 is connected to the clamping member 71.

The moving plate 73 is spaced apart from the fixed plate 72. On this moving plate 73 is provided a seating pin 75 through which the capping member 16 on which the frit member 16a is applied is mounted with its upper end passing through the fixing plate 72. [ That is, the moving plate 73 is raised in accordance with the rising of the second capping module 80 to be described later, so that the capping member 16, which is seated on the seating pin 75, can be pressed toward the vacuum multilayer glass 10 .

A mounting pin 76 is provided on the moving plate 73 so that the second elastic member 74 is inserted and the upper end of the second elastic member 74 penetrates through the fixing plate 72 and is fixed to the fixing plate 72 .

The second elastic member 74 is disposed between the fixed plate 72 and the moving plate 73 as described above. The second elastic member 74 serves to elastically support the moving plate 73 to restore the moving plate 73 to its original position after capping of the capping member 16 is completed.

The heating member 77 serves to heat and melt the frit member 16a applied to the capping member 16 seated on the seating pin 75 as shown in FIG. A combined body, and an IR lamp housed in the body.

And the heating member 77 may be integrated with the moving plate 73 although not shown.

The pressurizing module 80 serves to press each capping module 70 toward each vacuum double-layered glass 10 side. The pressing module 80 includes a pressing member 81 corresponding to each tray and a lift unit 83 for moving the pressing member 81 up and down.

The pressing member 81 is provided for simultaneously pressing each capping member 16 corresponding to the exhaust hole 15 of the plurality of vacuum double-layered glass 10 supported by each tray 31. The pressing member 81 is provided in the shape of a mesh as shown in the figure. This is to prevent the pressing member 81 from interfering with the support pin unit 33 that substantially supports each vacuum double-layer glass 10. In other words, each support pin unit 33 can be disposed in the space between the mesh-shaped pressing members. Therefore, the pressing module 80 of the apparatus for manufacturing a vacuum double-layered glass according to the embodiment of the present invention is provided with the number corresponding to each vacuum double-layered glass of various sizes supported by the tray 31, May be provided in a corresponding number.

The elevating unit 83 is for elevating the urging member 81 and includes a driving member 84 and a driving member 84 disposed between the driving member 84 and the urging member 81, And a connecting member 85 for moving the member 81 up and down.

The driving member 84 may be a cylinder installed outside the vacuum chamber 20. Various other means can be applied as long as the driving member 84 can move the pressing member 81 up and down.

The connecting member 85 serves to raise and lower the pressing member 81 in accordance with the operation of the driving member 84 as described above. The connecting member 85 may be a link member, and various other means may be applied as long as the heating member can be raised and lowered.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. will be. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: Vacuum multilayer glass 11: First glass plate
12: second glass plate 13: frit sealing member
14: Spacer 15: Exhaust hole
16: capping member 20: vacuum chamber
30: support device 31: tray
33: support pin unit 34: body
35: support pin 36: first elastic member
37: contact part 40: heating device
50: Vacuum device 60: Capping device
70: capping module 71: clamping member
72: Fixing plate 73: Moving plate
74: second elastic member 75: seat pin
80: pressing module 81: pressing member
83: Lift unit

Claims (6)

A frit sealing member disposed at an edge of the first glass plate and capable of bonding the first and second glass plates; and a capping member covering the exhaust holes formed in one of the first and second glass plates, A vacuum double-layered glass manufacturing apparatus for manufacturing a vacuum double-layered glass including the above-
In the vacuum double-layered glass manufacturing apparatus,
A vacuum chamber,
A supporting device installed inside the vacuum chamber to support the vacuum multilayer glass,
And a capping device for capping the plurality of vacuum multilayer glass capping members supported by the support device,
The capping device comprises:
A plurality of capping modules for supporting each of the capping members,
And a pressing module that simultaneously presses the capping members supported by the capping modules toward the respective vacuum double-layered glass side. The method according to claim 1,
Wherein the support device comprises a tray and a plurality of support pin units mounted on an upper surface of the tray,
Each of the support pin units includes:
A body coupled to an upper surface of the tray,
A support pin accommodated in the body and penetrating the upper surface of the body to be in contact with the vacuum multilayer glass when the vacuum multilayer glass is supported;
And a first elastic member for elastically supporting the support pin inside the body. 3. The method of claim 2,
The capping module comprises:
A moving plate having a seating pin on which the capping member is seated,
A second elastic member for elastically supporting the moving plate,
And a heating member which is fastened to the moving plate and heats the frit member of the capping member which is seated on the seating pin. The method of claim 3,
The capping module comprises:
A clamping member for clamping the vacuum multilayer glass,
Further comprising a fixing plate connected to the clamping member and contacting the other end opposite to one end of the second elastic member in contact with the moving plate. The method of claim 3,
The pressing module includes:
A mesh-shaped pressing member disposed between the moving plate and the tray, and an elevating unit for moving the pressing member up and down. 6. The method of claim 5,
And the support pin is disposed between the mesh-shaped pressing members.

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