JP2003192399A - Cover for glass panel suction hole and method of using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cover for a glass panel suction hole, which can control flow of fused spacers into the glass panel suction hole and a method of using the same. <P>SOLUTION: In the cover 6 which seals a suction hole 5 placed at a glass panel P to exhaust gas in a gap part V by sucking, this cover for the glass panel suction hole is attached a flow control means 9 at the periphery of the cover 6 and by which flowing of fluid into the suction hole 5 is controlled. The method of using the cover for the glass panel suction hole is carried out by that, a sealing material 7 and a spacer 10 are placed on a plate glass 1 at the peripheral part of the suction hole 5, the place of the spacer 10 is at least within the working range of the flow control means 9 and the cover 6 is placed thereon, a gap for suction 11 is kept with the spacer 10 and through which gas in the gap part V is exhausted by sucking, and then the cover 6 is bonded with the plate glass 1 by fusing the spacer 10 and sealing material 7 sealing the suction hole 5. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pair of plate glasses, the peripheral portions of which are hermetically sealed with a gap between the surfaces of both plate glasses, and a suction hole for sucking and exhausting gas in the gap. In a vacuum glass provided on a plate glass, a suction hole lid body used to seal the suction hole and a suction hole lid body that seals the suction hole of the vacuum glass using the lid body. Regarding usage.

[0002]

2. Description of the Related Art A suction hole in a vacuum glass is indispensable for sucking and exhausting gas from the gap of the vacuum glass, and a lid for sealing the suction hole is conventionally made of a flat plate glass. The vacuum glass is adhered to the plate glass side of the vacuum glass or the like to seal the suction hole. More specifically, conventionally, a sealing material such as low-melting glass that is melted by heating is placed on the sheet glass around the suction hole, and a sheet glass is placed above the sealing material using a special dedicated mechanism. Hold the lid so that a suction gap is formed between the lid and the lid, and when the suction and exhaust of gas from the gap are completed, place the lid on the melted and fluidized sealing material. It was dropped and the lid was adhered by the sealing material to seal the suction hole.

[0003]

However, in such a conventional method, a mechanism for holding the lid body to secure a gap for sucking gas and dropping the lid body when necessary is complicated. There was room for improvement in this respect. As a solution to such a problem, a spacer that melts by heating is placed on the plate glass around the suction hole, and a gap for suction is secured between the plate glass and the lid by the spacer, and at the same time as the sealing material by heating. It is conceivable that the spacer is also melted, and the melting of the spacer causes the lid to drop onto the sealing material and adhere. However, in this way,
There is a possibility that the spacer that has been melted and fluidized by heating will flow into the suction hole, and the smaller the lid, the higher the possibility.If the spacer flows into the suction hole, the quality of the vacuum glass will deteriorate. Therefore, depending on the material of the spacer, impurities vaporized from the spacer may enter the gap of the vacuum glass and adhere to the surface of the glass.

The present invention focuses on such a conventional problem, and an object thereof is to improve the lid for sealing the suction hole of the vacuum glass even if the lid is made small. , The melted and fluidized spacer can be regulated from flowing into the suction hole of the vacuum glass, thereby enabling the use of the spacer melted by heating, without requiring a complicated mechanism, Moreover, a vacuum glass suction lid and an effective method of using the lid, which can surely perform suction and exhaust of gas in the gap and adhesion of the lid with a sealing material while avoiding deterioration of the quality of the vacuum glass. To provide.

[0005]

[Structure] As a characteristic structure of the invention of claim 1, as shown in FIGS. 1 to 11, a pair of plate glasses 1 and 2 are disposed between the surfaces of both plate glasses 1 and 2. The peripheral portion is hermetically sealed with the gap V, and the suction holes 5 for sucking and exhausting the gas in the gap V are provided in the plate glass 1.
In the vacuum glass P provided in the
A lid 6 for a suction hole used to seal the suction hole 5 in a state in which the suction hole 5 is sealed by the lid 6, a flow for restricting the inflow of the fluid into the suction hole 5. The regulating means 9 is provided at the peripheral portion of the lid body 6.

[0006] The characteristic structure of the invention of claim 2 is, as illustrated in FIGS. 4, 5, 8 and 9, the flow regulating means 9
Are inclined surfaces 8, 15, 1 provided on the peripheral portion of the lid body 6.
It is composed of 7.

According to a third aspect of the present invention, as shown in FIG. 8, the lid 6 has a conical portion 14,
The flow restricting means 9 is formed by the inclined surface 15 of the conical portion 14.

According to a fourth aspect of the present invention, as illustrated in FIG. 8, the conical portion 14 of the lid 6 is a conical conical portion.

As shown in FIGS. 6 and 7, the flow restricting means 9 is composed of a stepped portion 13 provided on the peripheral portion of the lid body 6, as shown in FIGS. 6 and 7. It is in.

The characteristic configuration of the invention of claim 6 is, as illustrated in FIG. 2, FIG. 4, FIG. 5, and FIG. 7 to FIG.
5. A lid 6 for sealing the suction hole 5 provided in the plate glass 1 of the vacuum glass P by using the lid 6 according to any one of 5 above.
The sealing material 7 and the spacer 10 which are melted by heating are arranged on the plate glass 1 around the suction hole 5, and at least the spacer 10 is within the working range of the flow regulating means 9 of the lid body 6. Position, and dispose the lid 6 above the spacer 10 and the sealing material 7,
With the spacer 10 holding the suction gap 11 between the plate glass 1 and the lid 6, the gas in the gap V of the vacuum glass P is sucked and exhausted from the suction hole 5, and the spacer 10 and The sealing material 7 is heated and melted, and the lid 6 is bonded to the plate glass 1 by the sealing material 7 to seal the suction hole 5.

The characterizing feature of the invention of claim 7 is shown in FIGS.
As illustrated in 0, the sealing material 7 and the spacer 10 are separately configured, the sealing material 7 is placed on the plate glass 1, and the spacer 10 is placed on the sealing material 7. Then, the spacer 10 and the sealing material 7 are heated and melted.

As shown in FIG. 2, FIG. 5 and FIG. 7, the characteristic constitution of the invention of claim 8 is that the sealing material 7 and the spacer 10 are separately formed, and the spacer 1 is provided on the plate glass 1.
0 is placed, and the suction holes 5
On the side and in a state where the sealing material 7 is arranged on the plate glass 1 outside the working range of the flow regulating means 9,
The spacer 10 and the seal material 7 are heated and melted.

As mentioned above, the reference numerals are given for the sake of convenience in comparison with the drawings, but the present invention is not limited to the configuration of the accompanying drawings by the entry.

[Operation and Effect] According to the characterizing feature of the invention of claim 1, it is a suction hole lid used for sealing the suction hole of the vacuum glass, and the suction hole is sealed by the lid. In this arrangement, since the flow restricting means for restricting the inflow of the fluid into the suction hole is provided in the peripheral portion of the lid, for example, the spacer is used to have the suction hole. Even if a spacer is secured between the plate glass and the lid body and the spacer is melted by heating after the gas is sucked and exhausted from the gap portion of the vacuum glass, the spacer that is melted and fluidized is the lid body. Invasion into the suction hole is regulated by the flow regulating means provided on the peripheral portion. Therefore, unlike the conventional case, a complicated mechanism for holding a lid is not required, and even if a small lid is used and a spacer that is melted by heating is used, a suction gap is provided between the plate glass and the lid. Even if secured, the fluidized spacer does not invade the suction holes to deteriorate the quality of the vacuum glass or infiltrate impurities into the gap. It is possible to reliably bond the lid.

According to the characterizing feature of the second aspect of the invention, since the flow restricting means is constituted by the inclined surface provided on the peripheral portion of the lid body, only the inclined surface is provided on the peripheral portion of the lid body. With a very simple structure, it is possible to regulate the invasion of the spacer fluidized by heating into the suction hole.

According to the characterizing feature of the invention of claim 3, since the lid body is provided with the conical portion and the flow restricting means is constituted by the inclined surface of the conical portion, the conical portion of the conical portion is formed. In addition to restricting the fluidized spacer from entering the suction hole due to the inclined surface, the shape of the suction hole can be made to correspond to the shape of the cone shape of the lid, so that the lid can be moved to the suction hole side. Accompanied by,
Since the center of the lid is also automatically aligned with the center of the suction hole, the centering function is provided, and the sealing of the suction hole by the lid becomes more reliable.

According to the feature of the invention of claim 4, since the pyramidal portion of the lid is a conical pyramidal portion, for example, as compared with the case where the pyramidal portion of the lid is pyramidal. As a result, it becomes easy to manufacture the lid body and form the suction hole corresponding thereto, and the centering function described above becomes more reliable.

According to the characterizing feature of the invention of claim 5, the flow restricting means is constituted by the step portion provided on the peripheral portion of the lid body, so that only the step portion is provided on the peripheral portion of the lid body. With a very simple structure, it is possible to regulate the invasion of the spacer fluidized by heating into the suction hole.

According to a characteristic construction of the invention of claim 6, a lid body for sealing a suction hole provided in a plate glass of vacuum glass by using the lid body according to any one of claims 1 to 5. The method of using, wherein a sealing material and a spacer, which are melted by heating, are placed on the plate glass around the suction hole, and at least the spacer is positioned within the working range of the flow restricting means of the lid, and the spacer and the seal are sealed. Since the lid is placed above the material and the spacer holds the suction gap between the plate glass and the lid, the gas in the gap of the vacuum glass is sucked and exhausted from the suction hole. Without using a complicated lid holding mechanism, a spacer that melts by heating is used to secure a suction gap between the plate glass and the lid, and the gas in the gap is surely sucked and exhausted. be able to. Then, the spacer and the seal material are heated and melted, and the lid member is bonded to the plate glass by the seal material. However, since at least the spacer is located within the working range of the flow restricting means, the melted and fluidized spacer Invasion into the suction hole is restricted, and the suction hole can be reliably sealed by adhering the lid with a sealing material.

According to the characterizing feature of the seventh aspect of the invention, the sealing material and the spacer are formed separately, the sealing material is placed on the plate glass, and the spacer is placed on the sealing material. Since the spacer and the sealing material are heated and melted, the spacer fluidized by melting is prevented from entering the suction hole by the flow restricting means of the lid body that moves downward as the spacer melts. The lid can be adhered to the plate glass with the sealing material that has been melted and fluidized to seal the suction hole.

According to the feature of the invention of claim 8, the sealant and the spacer are formed separately, the spacer is placed on the plate glass, and the flow regulation is performed on the suction hole side of the spacer. Since the spacer and the sealing material are heated and melted while the sealing material is placed on the glass plate outside the working range of the means, the spacer fluidized by the melting is located within the working range of the flow restricting means of the lid. Intrusion into the suction hole is restricted, whereas the sealing material that is fluidized by melting is located outside the working range of the flow restriction means inside and the lid body is adhered to the plate glass. Adhesion of the lid body with respect to the suction hole becomes more reliable, and the suction hole can be sealed more reliably.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a lid for a vacuum glass suction hole and a method of using the lid according to the present invention will be described with reference to the drawings. As shown in FIG. 1, the vacuum glass P is a pair of plate glasses 1 and 2, and the surfaces of both plate glasses 1 and 2 have a large number of spacers 3 interposed therebetween,
As a result, the glass plates 1 and 2 are arranged so as to face each other with a gap V between the surfaces thereof, and the peripheral edges of the glass plates 1 and 2 have a lower melting point than the glass plates 1 and 2, and Bonded by a sealing material 4 for bonding, which is made of a low-melting glass having a low gas permeability, and a gap V between the two glass plates 1,
, Which are hermetically sealed under reduced pressure.

The thickness of the two glass plates 1 and 2 is 2.6.
A transparent float plate glass of about 5 to 3.2 mm is used, and the gap V between both plate glasses 1 and 2 is 1.33 Pa.
The pressure is reduced to (1.0 × 10 ^-2 Torr) or less. The decompression of the gap V will be described in detail later,
In order to suck and exhaust the gas in the gap V to reduce the pressure, one plate glass 1 is provided with a suction hole 5 having a circular cross section, as shown in detail in FIGS. 2 to 4. This suction hole 5
It also serves as a getter storage space for storing a columnar getter G. The getter G is stored in the suction hole 5,
The suction hole 5 is sealed by a circular lid body 6 made of transparent float plate glass, and the lid body 6 has a higher melting point than the low melting point glass constituting the bonding seal material 4, 6 and the lid glass sealing member 7 made of a low melting point glass having a lower melting point than that of the plate glass 1.

The lid 6 for sealing the suction hole 5 is, for example, a getter G having a diameter of 12 mm and a diameter of 10 mm.
In the case of housing the housing, the inclined surface having a diameter of about 20 mm and, as enlarged and shown in FIG. 8 is provided, and the inclined surface 8 thereof is, as described later,
In the arrangement state in which the suction hole 5 is sealed by the lid body 6, it is configured to function as a flow restricting means 9 that restricts the inflow of the fluid into the suction hole 5. The spacer 3
Is preferably cylindrical in shape, and has a compressive strength of 4.9 × so that it can withstand the atmospheric pressure acting on both glass plates 1 and 2.
Material of 10 ⁸ Pa (5 × 10 ³ kgf / cm ² ) or more,
For example, stainless steel (SUS304) or Inconel 7
18 and the like, and in the case of a columnar shape, the diameter is about 0.3 to 1.0 mm and the height is 0.15 to 1.0 m.
The distance between the spacers 3 is set to about 20 m.
It is set to about m.

Next, a process of manufacturing the vacuum glass P and the like will be described. First, of the pair of plate glasses 1 and 2, the plate glass 2 on which the suction hole 5 is not formed is supported substantially horizontally, and a sealing material for bonding made of paste-like low melting point glass is provided on the upper surface of the peripheral edge part. 4 is applied, and
A large number of spacers 3 are arranged at predetermined intervals, and the other plate glass 1 is placed from above. At this time, if the area of the plate glass 2 located below is made slightly larger and the peripheral portion thereof is configured to slightly project from the peripheral portion of the upper plate glass 1, it is convenient for application of the sealing material 4 for bonding. Then, the both glass plates 1 and 2 are housed in a heating furnace (not shown) in a substantially horizontal state, the bonding sealing material 4 is melted by firing, and the both bonding glass materials 4 are melted by the bonding sealing material 4 in a molten state.
A joining process of joining the peripheral edges of the two and sealing the gap V is performed.

After that, a getter G is inserted into the suction hole 5 of the plate glass 1 and, as shown in FIG. 4, a material which is melted by heating around the suction hole 5 of the plate glass 1, for example, a temperature fuse made of metal is used. A plurality of cylindrical spacers 10 are placed, and the lid 6 is placed on the spacers 10 as shown in FIG. Of the lower surface of this lid body 6,
Inside the inclined surface 8, a lid sealing material 7 made of a low melting point glass made by adding an organic substance to glass powder called frit is preliminarily adhered in an annular shape by screen printing or the like. When the body 6 is placed on the spacer 10, the inclined surface 8 of the peripheral portion of the lid 6 is placed on the plurality of spacers 10 in contact with each other, and the sealing material 7 for the lid is located inside thereof. The suction gap 11 is set between the lower surface of the lid sealing material 7 and the upper surface of the plate glass 1.

In this way, the suction holes 5 are sealed by the lid body 6, and then the weight 12 made of quartz glass is placed on the lid body 6, and as shown in FIG. , The suction sealing device 20 is covered from above. The suction sealing device 20 includes a cylindrical suction cup 22 whose upper surface is closed by a transparent quartz glass 21.
A flexible pipe 23 communicating with the internal space of the suction cup 22 is communicated with the suction cup 22, and an O-ring 24 is provided on the lower surface of the suction cup 22 to seal the upper surface of the glass plate 1 from the quartz glass of the suction cup 22. A heating source 25 including a lamp, a laser generator, and the like is provided on the outer upper surface of the device 21.

The suction sealing device 20 as described above is used for the plate glass 1
In the state in which the gap V is gradually covered, the suction cup 22 is depressurized by suction by a rotary pump or a turbo molecular pump (not shown) connected to the flexible pipe 23, and the gas in the gap V is sucked. A baking process is performed in which suction and exhaust are performed through the holes 5, and the inside of the gap V is 1.
Reduce the pressure to 33 Pa or less. During the depressurization, the heating source 2
The sealing material 7 for the lid and the spacer 10 are locally heated and melted by 5 to bond the lid 8 to the plate glass 1. When the inside of the gap V is depressurized to a predetermined pressure, the getter G is Is also heated and activated, and water, CO, and CO ₂ , which are not sucked by the suction and exhaust of the baking process,
Gases such as N ₂ , H ₂ and O ₂ , that is, various gases such as an oxidizing gas, a sulfurizing gas, a carbonizing gas and an organic gas are adsorbed and removed.

At this time, since the spacer 10 is a thermal fuse made of metal and is divided into a plurality of pieces, it is fluidized by melting and has a surface tension as shown in FIG. It tries to become a polka dot. The polka dot-shaped spacer 10 is below the inclined surface 8 of the lid body 6, that is,
Since it is located within the working range of the inclined surface 8, it is forcibly discharged to the outside by the inclined surface 8 which is moving downward due to the weight of the weight 12, as shown in FIG. Is prevented from entering. And the spacer 10
Inside, that is, outside the working range of the inclined surface 8, the lid sealing material 7 is melted, and the lid 6 is bonded to the plate glass 1 by the molten lid sealing material 7, and finally, As shown in FIG. 3, the suction hole 5 will be sealed.

[Other Embodiments] Next, another embodiment will be described. In order to avoid redundant description, the same parts or parts having the same actions as those described in the previous embodiment are designated by the same reference numerals. Therefore, the description thereof will be omitted, and only the configuration different from the previous embodiment will be mainly described.

(1) In the above embodiment, the inclined surface 8 is provided on the lower peripheral portion of the lid body 6, and the inclined surface 8 restricts the inflow of the fluid into the suction hole 5. Although an example in which the flow restricting means 9 is configured to function as the above is shown, various specific structures can be adopted for the flow restricting means 9.
For example, as shown in FIG. 6 and FIG. 7, a step portion 13 located downward toward the center is provided on the lower peripheral portion of the circular lid body 6, and the step portion 13 constitutes the flow restricting means 9, It is also possible to position the plurality of spacers 10 below the portion 13 and position the sealing material 7 for the lid inside the spacers 10.

Further, as shown in FIG. 8, a conical pyramidal portion 14 is integrally provided on the lower portion of the lid body 6, and a part of the inclined surface 15 of the conical pyramidal portion 14 restricts the flow. It can also be configured to function as the means 9. According to this another embodiment, since the lower portion of the lid 6 has a conical shape, a part of the inclined surface 15 functions as the flow restricting means 9 as the lid sealing material 7 and the spacer 10 are melted. In addition to the above, it also has a centering function in which the center of the lid body 6 and the center of the suction hole 5 are automatically aligned. Further, as a modification of the embodiment shown in FIG. 8, as shown in FIG. 9, the lower portion of the lid body 6 serves as a partial spherical portion 16 and a part of the partially spherical inclined surface 17 functions as the flow restricting means 9. Alternatively, the lower portion of the lid body 6 may be formed into a pyramid shape, and the suction holes may be formed into corresponding square suction holes.

In the embodiment shown in FIGS. 8 and 9, the lid sealing material 7 is not adhered to the lower surface of the lid 6 and is located within the working range of the flow regulating means 9. There is. That is, as shown in FIG. 10, an annular sealing material 7 for lids is placed on the plate glass 1, a plurality of spacers 10 are placed on the sealing material 7, and the spacers 10 are placed on the sealing material 7.
The lid 6 shown in FIG. 9 is placed. In this case, not only the spacer 10 but also the lid sealing material 7 is below the inclined surfaces 15 and 17 of the pyramidal portion 14 and the partial spherical portion 16 forming the flow restricting means 9, that is, the flow restricting means 9 of the flow restricting means 9. It will be located within the range of action. Then, as the lid 6 moves downward due to the melting of the spacer 10, the spacer 10 is forcibly discharged outward by the inclined surfaces 15 and 17, and in the case of such a configuration It is preferable that the spacer 10 is formed of lost wax, that is, a material that is melted and gasified by heating.

(2) In the above-described embodiments, an example in which the lid sealing material 7 and the spacer 10 are formed separately is shown. However, as shown in FIG. 11, for lids made of low-melting glass. A plurality of projections 7a are integrally provided on the sealing material 7 so that a suction gap 11 is secured between the projections 7a.
The spacer 10 can also be configured by the plurality of protrusions 7a. That is, it is possible to integrate the lid sealing material 7 and the spacer 10 with the same material. In this case, the molten and fluidized lid sealing material 7 and the spacer 10 are replaced by the suction holes 5. With the invasion of the inside blocked,
The lid 6 is bonded to the plate glass 1.

(3) In the above embodiments, an example in which the vacuum glass P is composed of a pair of float glass plates 1 and 2 has been shown. However, depending on the use and purpose of the vacuum glass P, for example, a template glass, a surface. Frosted glass with light diffusion function by processing, mesh glass, wire-lined plate glass, tempered glass, double tempered glass, low reflection glass, high transmission plate glass, ceramic printing glass, special glass with heat ray and ultraviolet ray absorption function, or Various glasses such as a combination thereof can be appropriately selected and implemented. Also, regarding the composition of the glass, soda silicate glass, soda lime glass, borosilicate glass, aluminosilicate glass, various crystallized glasses, and the like can be used, and the thickness of the plate glasses 1 and 2 can be appropriately selected freely. is there. Although the above also applies to the lid body 6, the lid body 6 is not limited to glass in particular, and may be made of various materials such as metal and ceramics. . Also, an example in which the getter G is housed in the suction hole 5 sealed by the lid body 6 is shown, but depending on the degree of pressure reduction in the gap portion V of the vacuum glass P, the getter G is shown.
May not be necessary, so the getter G is not essential.

[Brief description of drawings]

FIG. 1 is a partially cutaway perspective view of a vacuum glass.

FIG. 2 is a sectional view of a vacuum glass and a suction sealing device in a manufacturing process.

FIG. 3 is a sectional view of the main part of the vacuum glass.

FIG. 4 is a perspective view of a main part of vacuum glass in a manufacturing process.

FIG. 5 is a sectional view of an essential part showing the action of the lid body.

FIG. 6 is a perspective view of a lid according to another embodiment.

FIG. 7 is a cross-sectional view of a main part showing an operation of a lid according to another embodiment.

FIG. 8 is a cross-sectional view of a main part showing an operation of a lid according to another embodiment.

FIG. 9 is a cross-sectional view of a main part showing an operation of a lid according to another embodiment.

FIG. 10 is a perspective view showing the arrangement of spacers according to another embodiment.

FIG. 11 is a perspective view of a spacer according to another embodiment.

[Explanation of symbols]

1, 2 pairs of plate glass 5 suction holes 6 lid 7 Seal material 8 Inclined surface of lid 9 Flow control measures 10 Spacer 11 Suction gap 13 Step of lid 14 Conical conical section 15 Inclined surface of cone P vacuum glass V gap

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[Procedure amendment]

[Submission date] February 24, 2003 (2003.2.2)
4)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title: Glass panel suction hole lid and method of using the lid

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pair of plate glasses, the peripheral portions of which are hermetically sealed with a gap between the surfaces of both plate glasses, and a suction hole for sucking and exhausting gas in the gap. In a glass panel provided on a plate glass, a suction hole lid used for sealing the suction hole, and a suction hole for sealing the suction hole of the glass panel using the lid. The present invention relates to a method of using the lid.

[0002]

2. Description of the Related Art Suction holes in glass panels are made of glass.
The panel gas from the gap portion is indispensable for sucking exhaust, lid for sealing the suction holes are conventionally formed of a flat plate glass, or the like low-melting glass Garasupa
The flannel was adhered to the plate glass side to seal the suction hole. More specifically, conventionally, a sealing material such as low-melting glass that is melted by heating is placed on the sheet glass around the suction hole, and a sheet glass is placed above the sealing material using a special dedicated mechanism. Hold the lid so that a suction gap is formed between the lid and the lid, and when the suction and exhaust of gas from the gap are completed, place the lid on the melted and fluidized sealing material. It was dropped and the lid was adhered by the sealing material to seal the suction hole.

[0003]

However, in such a conventional method, a mechanism for holding the lid body to secure a gap for sucking gas and dropping the lid body when necessary is complicated. There was room for improvement in this respect. As a solution to such a problem, a spacer that melts by heating is placed on the plate glass around the suction hole, and a gap for suction is secured between the plate glass and the lid by the spacer, and at the same time as the sealing material by heating. It is conceivable that the spacer is also melted, and the melting of the spacer causes the lid to drop onto the sealing material and adhere. However, in this way,
Spacer fluidized by melting by heating, there is a possibility that flows into the suction hole, its potential smaller the lid is high, the spacer flows into the suction hole, moth
The quality of the lath panel is deteriorated, and depending on the material of the spacer, impurities vaporized from the spacer may enter the gap portion of the glass panel and adhere to the surface of the glass.

The present invention focuses on such a conventional problem, and an object thereof is to improve the lid for sealing the suction hole of the glass panel even if the lid is made small. , It is possible to regulate that the melted and fluidized spacers flow into the suction holes of the glass panel , thereby enabling the use of spacers that are melted by heating,
It is possible to surely perform suction / exhaust of gas in the gap and adhesion of the lid by the sealing material without requiring a complicated mechanism and avoiding deterioration of quality of the glass panel.
A glass panel suction lid and an effective method of using the lid.

[0005]

[Structure] As a characteristic structure of the invention of claim 1, as shown in FIGS. 1 to 11, a pair of plate glasses 1 and 2 are disposed between the surfaces of both plate glasses 1 and 2. The peripheral portion is hermetically sealed with the gap V, and the suction holes 5 for sucking and exhausting the gas in the gap V are provided in the plate glass 1.
In the glass panel P provided in, the suction hole lid body 6 is used for sealing the suction hole 5, and the suction hole lid 5 is sealed by the lid body 6. A flow restricting means 9 for restricting the inflow of the fluid into the suction hole 5 is provided in the peripheral portion of the lid body 6.

[0006] The characteristic structure of the invention of claim 2 is, as illustrated in FIGS. 4, 5, 8 and 9, the flow regulating means 9
Are inclined surfaces 8, 15, 1 provided on the peripheral portion of the lid body 6.
It is composed of 7.

According to a third aspect of the present invention, as shown in FIG. 8, the lid 6 has a conical portion 14,
The flow restricting means 9 is formed by the inclined surface 15 of the conical portion 14.

According to a fourth aspect of the present invention, as illustrated in FIG. 8, the conical portion 14 of the lid 6 is a conical conical portion.

As shown in FIGS. 6 and 7, the flow restricting means 9 is composed of a stepped portion 13 provided on the peripheral portion of the lid body 6, as shown in FIGS. 6 and 7. It is in.

The characteristic configuration of the invention of claim 6 is, as illustrated in FIG. 2, FIG. 4, FIG. 5, and FIG. 7 to FIG.
A glass panel using the lid 6 according to any one of 5 above.
A method of using a lid body 6 for sealing a suction hole 5 provided in a plate glass 1 of a rule P, wherein the plate glass 1 around the suction hole 5 is used.
A seal material 7 and a spacer 10 which are melted by heating are arranged on the upper side, and at least the spacer 10 is positioned within the working range of the flow regulating means 9 of the lid body 6, and the spacer 10 and the seal material 7 In the state where the lid body 6 is arranged in the space and the spacer 10 holds the suction gap 11 between the plate glass 1 and the lid body 6, the suction hole 5
The gas in the gap V of the glass panel P is sucked and exhausted from the above, the spacer 10 and the sealing material 7 are heated and melted, and the lid 6 is adhered to the plate glass 1 by the sealing material 7 to seal the suction hole 5. It's about to stop.

The characterizing feature of the invention of claim 7 is shown in FIGS.
As illustrated in 0, the sealing material 7 and the spacer 10 are separately configured, the sealing material 7 is placed on the plate glass 1, and the spacer 10 is placed on the sealing material 7. Then, the spacer 10 and the sealing material 7 are heated and melted.

As shown in FIG. 2, FIG. 5 and FIG. 7, the characteristic constitution of the invention of claim 8 is that the sealing material 7 and the spacer 10 are separately formed, and the spacer 1 is provided on the plate glass 1.
0 is placed, and the suction holes 5
On the side and in a state where the sealing material 7 is arranged on the plate glass 1 outside the working range of the flow regulating means 9,
The spacer 10 and the seal material 7 are heated and melted.

As mentioned above, the reference numerals are given for the sake of convenience in comparison with the drawings, but the present invention is not limited to the configuration of the accompanying drawings by the entry.

[Operation and Effect] According to the characterizing feature of the invention of claim 1, it is a lid for a suction hole used for sealing a suction hole of a glass panel , and the suction hole is sealed by the lid. In this arrangement, since the flow restricting means for restricting the inflow of the fluid into the suction hole is provided in the peripheral portion of the lid, for example, the spacer is used to have the suction hole. Even if the spacer is melted by heating after securing a gap for suction between the plate glass and the lid and sucking and exhausting gas from the gap part of the glass panel , the spacer that is melted and fluidized is the lid. Invasion into the suction hole is regulated by the flow regulating means provided on the peripheral portion. Therefore, unlike the conventional case, a complicated mechanism for holding a lid is not required, and even if a small lid is used and a spacer that is melted by heating is used, a suction gap is provided between the plate glass and the lid. Even if secured, the fluidized spacer does not invade the suction holes to deteriorate the quality of the glass panel , and does not cause impurities to enter the gap. It is possible to reliably bond the lid.

According to the characterizing feature of the second aspect of the invention, since the flow restricting means is constituted by the inclined surface provided on the peripheral portion of the lid body, only the inclined surface is provided on the peripheral portion of the lid body. With a very simple structure, it is possible to regulate the invasion of the spacer fluidized by heating into the suction hole.

According to the characterizing feature of the invention of claim 3, since the lid body is provided with the conical portion and the flow restricting means is constituted by the inclined surface of the conical portion, the conical portion of the conical portion is formed. In addition to restricting the fluidized spacer from entering the suction hole due to the inclined surface, the shape of the suction hole can be made to correspond to the shape of the cone shape of the lid, so that the lid can be moved to the suction hole side. Accompanied by,
Since the center of the lid is also automatically aligned with the center of the suction hole, the centering function is provided, and the sealing of the suction hole by the lid becomes more reliable.

According to the feature of the invention of claim 4, since the pyramidal portion of the lid is a conical pyramidal portion, for example, as compared with the case where the pyramidal portion of the lid is pyramidal. As a result, it becomes easy to manufacture the lid body and form the suction hole corresponding thereto, and the centering function described above becomes more reliable.

According to the characterizing feature of the invention of claim 5, the flow restricting means is constituted by the step portion provided on the peripheral portion of the lid body, so that only the step portion is provided on the peripheral portion of the lid body. With a very simple structure, it is possible to regulate the invasion of the spacer fluidized by heating into the suction hole.

According to a characteristic constitution of the invention of claim 6, a glass is produced by using the lid body according to any one of claims 1 to 5.
A method of using a lid body for sealing a suction hole provided in a plate glass of a panel , wherein a sealing material and a spacer which are melted by heating are placed on the plate glass around the suction hole, and flow control means of the lid body is used. at least spacers is positioned within the operating range, in a state where placing the upper on the lid of the spacer and the sealing material, holding the suction gap between the glass sheet and the cover by a spacer, a glass from the suction holes Since the gas in the gap between the panels is sucked and exhausted, a spacer that melts by heating is used without the need for a complicated mechanism for holding the lid as in the past, and a suction gap is created between the plate glass and the lid. It is possible to reliably suck and exhaust the gas in the gap. Then, the spacer and the seal material are heated and melted, and the lid member is bonded to the plate glass by the seal material. However, since at least the spacer is located within the working range of the flow restricting means, the melted and fluidized spacer Invasion into the suction hole is restricted, and the suction hole can be reliably sealed by adhering the lid with a sealing material.

According to the characterizing feature of the seventh aspect of the invention, the sealing material and the spacer are formed separately, the sealing material is placed on the plate glass, and the spacer is placed on the sealing material. Since the spacer and the sealing material are heated and melted, the spacer fluidized by melting is prevented from entering the suction hole by the flow restricting means of the lid body that moves downward as the spacer melts. The lid can be adhered to the plate glass with the sealing material that has been melted and fluidized to seal the suction hole.

According to the feature of the invention of claim 8, the sealant and the spacer are formed separately, the spacer is placed on the plate glass, and the flow regulation is performed on the suction hole side of the spacer. Since the spacer and the sealing material are heated and melted while the sealing material is placed on the glass plate outside the working range of the means, the spacer fluidized by the melting is located within the working range of the flow restricting means of the lid. Intrusion into the suction hole is restricted, whereas the sealing material that is fluidized by melting is located outside the working range of the flow restriction means inside and the lid body is adhered to the plate glass. Adhesion of the lid body with respect to the suction hole becomes more reliable, and the suction hole can be sealed more reliably.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a cover for a suction hole of a glass panel and a method of using the cover according to the present invention will be described with reference to the drawings. The vacuum glass P as a glass panel is, as shown in FIG.
In the above, the surfaces of both glass plates 1 and 2 have a large number of spacers 3 interposed therebetween, whereby
Glass plates 1 and 2 which are arranged so as to face each other with a gap V between their surfaces and have a lower melting point than the plate glasses 1 and 2 and a low gas permeability. Are joined together by the joining sealing material 4 and the gap V between the two glass plates 1 and 2 is hermetically sealed in a depressurized state.

The thickness of the two glass plates 1 and 2 is 2.6.
A transparent float plate glass of about 5 to 3.2 mm is used, and the gap V between both plate glasses 1 and 2 is 1.33 Pa.
The pressure is reduced to (1.0 × 10 ^-2 Torr) or less. The decompression of the gap V will be described in detail later,
In order to suck and exhaust the gas in the gap V to reduce the pressure, one plate glass 1 is provided with a suction hole 5 having a circular cross section, as shown in detail in FIGS. 2 to 4. This suction hole 5
It also serves as a getter storage space for storing a columnar getter G. The getter G is stored in the suction hole 5,
The suction hole 5 is sealed by a circular lid body 6 made of transparent float plate glass, and the lid body 6 has a higher melting point than the low melting point glass constituting the bonding seal material 4, 6 and the lid glass sealing member 7 made of a low melting point glass having a lower melting point than that of the plate glass 1.

The lid 6 for sealing the suction hole 5 is, for example, a getter G having a diameter of 12 mm and a diameter of 10 mm.
In the case of housing the housing, the inclined surface having a diameter of about 20 mm and, as enlarged and shown in FIG. 8 is provided, and the inclined surface 8 thereof is, as described later,
In the arrangement state in which the suction hole 5 is sealed by the lid body 6, it is configured to function as a flow restricting means 9 that restricts the inflow of the fluid into the suction hole 5. The spacer 3
Is preferably cylindrical in shape, and has a compressive strength of 4.9 × so that it can withstand the atmospheric pressure acting on both glass plates 1 and 2.
Material of 10 ⁸ Pa (5 × 10 ³ kgf / cm ² ) or more, such as stainless steel (SUS304) or Inconel 71
8 and the like, and in the case of a columnar shape, the diameter is about 0.3 to 1.0 mm and the height is 0.15 to 1.0 mm.
The distance between the spacers 3 is set to about 20 mm.
It is set to a degree.

Next, a process of manufacturing the vacuum glass P and the like will be described. First, of the pair of plate glasses 1 and 2, the plate glass 2 on which the suction hole 5 is not formed is supported substantially horizontally, and a sealing material for bonding made of paste-like low melting point glass is provided on the upper surface of the peripheral edge part. 4 is applied, and
A large number of spacers 3 are arranged at predetermined intervals, and the other plate glass 1 is placed from above. At this time, if the area of the plate glass 2 located below is made slightly larger and the peripheral portion thereof is configured to slightly project from the peripheral portion of the upper plate glass 1, it is convenient for application of the sealing material 4 for bonding. Then, the both glass plates 1 and 2 are housed in a heating furnace (not shown) in a substantially horizontal state, the bonding sealing material 4 is melted by firing, and the both bonding glass materials 4 are melted by the bonding sealing material 4 in a molten state.
A joining process of joining the peripheral edges of the two and sealing the gap V is performed.

After that, a getter G is inserted into the suction hole 5 of the plate glass 1 and, as shown in FIG. 4, a material which is melted by heating around the suction hole 5 of the plate glass 1, for example, a temperature fuse made of metal is used. A plurality of cylindrical spacers 10 are placed, and the lid 6 is placed on the spacers 10 as shown in FIG. Of the lower surface of this lid body 6,
Inside the inclined surface 8, a lid sealing material 7 made of a low melting point glass made by adding an organic substance to glass powder called frit is preliminarily adhered in an annular shape by screen printing or the like. When the body 6 is placed on the spacer 10, the inclined surface 8 of the peripheral portion of the lid 6 is placed on the plurality of spacers 10 in contact with each other, and the sealing material 7 for the lid is located inside thereof. The suction gap 11 is set between the lower surface of the lid sealing material 7 and the upper surface of the plate glass 1.

In this way, the suction holes 5 are sealed by the lid body 6, and then the weight 12 made of quartz glass is placed on the lid body 6, and as shown in FIG. , The suction sealing device 20 is covered from above. The suction sealing device 20 includes a cylindrical suction cup 22 whose upper surface is closed by a transparent quartz glass 21.
A flexible pipe 23 communicating with the internal space of the suction cup 22 is communicated with the suction cup 22, and an O-ring 24 is provided on the lower surface of the suction cup 22 to seal the upper surface of the glass plate 1 from the quartz glass of the suction cup 22. A heating source 25 including a lamp, a laser generator, and the like is provided on the outer upper surface of the device 21.

The suction sealing device 20 as described above is used for the plate glass 1
In the state in which the gap V is gradually covered, the suction cup 22 is depressurized by suction by a rotary pump or a turbo molecular pump (not shown) connected to the flexible pipe 23, and the gas in the gap V is sucked. A baking process is performed in which suction and exhaust are performed through the holes 5, and the inside of the gap V is 1.
Reduce the pressure to 33 Pa or less. During the depressurization, the heating source 2
The sealing material 7 for the lid and the spacer 10 are locally heated and melted by 5 to bond the lid 8 to the plate glass 1. When the inside of the gap V is depressurized to a predetermined pressure, the getter G is Is also heated and activated, moisture, CO, CO ₂ , N ₂ , which was not sucked by the suction and exhaust of the baking process,
Gases such as H ₂ and O ₂ , that is, various gases such as an oxidizing gas, a sulfurizing gas, a carbonizing gas, and an organic gas are adsorbed and removed.

At this time, since the spacer 10 is a thermal fuse made of metal and is divided into a plurality of pieces, it is fluidized by melting and has a surface tension as shown in FIG. It tries to become a polka dot. The polka dot-shaped spacer 10 is below the inclined surface 8 of the lid body 6, that is,
Since it is located within the working range of the inclined surface 8, it is forcibly discharged to the outside by the inclined surface 8 which is moving downward due to the weight of the weight 12, as shown in FIG. Is prevented from entering. And the spacer 10
Inside, that is, outside the working range of the inclined surface 8, the lid sealing material 7 is melted, and the lid 6 is bonded to the plate glass 1 by the molten lid sealing material 7, and finally, As shown in FIG. 3, the suction hole 5 will be sealed.

[Other Embodiments] Next, another embodiment will be described. In order to avoid redundant description, the same parts or parts having the same actions as those described in the previous embodiment are designated by the same reference numerals. Therefore, the description thereof will be omitted, and only the configuration different from the previous embodiment will be mainly described.

(1) In the above embodiment, the inclined surface 8 is provided on the lower peripheral portion of the lid body 6, and the inclined surface 8 restricts the inflow of the fluid into the suction hole 5. Although an example in which the flow restricting means 9 is configured to function as the above is shown, various specific structures can be adopted for the flow restricting means 9.
For example, as shown in FIG. 6 and FIG. 7, a step portion 13 located downward toward the center is provided on the lower peripheral portion of the circular lid body 6, and the step portion 13 constitutes the flow restricting means 9, It is also possible to position the plurality of spacers 10 below the portion 13 and position the sealing material 7 for the lid inside the spacers 10.

Further, as shown in FIG. 8, a conical pyramidal portion 14 is integrally provided on the lower portion of the lid body 6, and a part of the inclined surface 15 of the conical pyramidal portion 14 restricts the flow. It can also be configured to function as the means 9. According to this another embodiment, since the lower portion of the lid 6 has a conical shape, a part of the inclined surface 15 functions as the flow restricting means 9 as the lid sealing material 7 and the spacer 10 are melted. In addition to the above, it also has a centering function in which the center of the lid body 6 and the center of the suction hole 5 are automatically aligned. Further, as a modification of the embodiment shown in FIG. 8, as shown in FIG. 9, the lower portion of the lid body 6 serves as a partial spherical portion 16 and a part of the partially spherical inclined surface 17 functions as the flow restricting means 9. Alternatively, the lower portion of the lid body 6 may be formed into a pyramid shape, and the suction holes may be formed into corresponding square suction holes.

In the embodiment shown in FIGS. 8 and 9, the lid sealing material 7 is not adhered to the lower surface of the lid 6 and is located within the working range of the flow regulating means 9. There is. That is, as shown in FIG. 10, an annular sealing material 7 for lids is placed on the plate glass 1, a plurality of spacers 10 are placed on the sealing material 7, and the spacers 10 are placed on the sealing material 7.
The lid 6 shown in FIG. 9 is placed. In this case, not only the spacer 10 but also the lid sealing material 7 is below the inclined surfaces 15 and 17 of the pyramidal portion 14 and the partial spherical portion 16 forming the flow restricting means 9, that is, the flow restricting means 9 of the flow restricting means 9. It will be located within the range of action. Then, as the lid 6 moves downward due to the melting of the spacer 10, the spacer 10 is forcibly discharged outward by the inclined surfaces 15 and 17, and in the case of such a configuration It is preferable that the spacer 10 is formed of lost wax, that is, a material that is melted and gasified by heating.

(2) In the above-described embodiments, an example in which the lid sealing material 7 and the spacer 10 are formed separately is shown. However, as shown in FIG. 11, for lids made of low-melting glass. A plurality of projections 7a are integrally provided on the sealing material 7 so that a suction gap 11 is secured between the projections 7a.
The spacer 10 can also be configured by the plurality of protrusions 7a. That is, it is possible to integrate the lid sealing material 7 and the spacer 10 with the same material. In this case, the molten and fluidized lid sealing material 7 and the spacer 10 are replaced by the suction holes 5. With the invasion of the inside blocked,
The lid 6 is bonded to the plate glass 1.

(3) In the above embodiments, an example in which the vacuum glass P is composed of a pair of float glass plates 1 and 2 has been shown. However, depending on the use and purpose of the vacuum glass P, for example, a template glass, a surface. Frosted glass with light diffusion function by processing, mesh glass, wire-lined plate glass, tempered glass, double tempered glass, low reflection glass, high transmission plate glass, ceramic printing glass, special glass with heat ray and ultraviolet ray absorption function, or Various glasses such as a combination thereof can be appropriately selected and implemented. Also, regarding the composition of the glass, soda silicate glass, soda lime glass, borosilicate glass, aluminosilicate glass, various crystallized glasses, and the like can be used, and the thickness of the plate glasses 1 and 2 can be appropriately selected freely. is there. Although the above also applies to the lid body 6, the lid body 6 is not limited to glass in particular, and may be made of various materials such as metal and ceramics. . Also, an example in which the getter G is housed in the suction hole 5 sealed by the lid body 6 is shown, but depending on the degree of pressure reduction in the gap portion V of the vacuum glass P, the getter G is shown.
May not be necessary, so the getter G is not essential.

[Brief description of drawings]

FIG. 1 is a partially cutaway perspective view of a vacuum glass.

FIG. 2 is a sectional view of a vacuum glass and a suction sealing device in a manufacturing process.

FIG. 3 is a sectional view of the main part of the vacuum glass.

FIG. 4 is a perspective view of a main part of vacuum glass in a manufacturing process.

FIG. 5 is a sectional view of an essential part showing the action of the lid body.

FIG. 6 is a perspective view of a lid according to another embodiment.

FIG. 7 is a cross-sectional view of a main part showing an operation of a lid according to another embodiment.

FIG. 8 is a cross-sectional view of a main part showing an operation of a lid according to another embodiment.

FIG. 9 is a cross-sectional view of a main part showing an operation of a lid according to another embodiment.

FIG. 10 is a perspective view showing the arrangement of spacers according to another embodiment.

FIG. 11 is a perspective view of a spacer according to another embodiment.

[Explanation of Codes] 1, 2 Pairs of Plate Glass 5 Suction Hole 6 Lid 7 Sealing Material 8 Inclined Surface of Lid 9 Flow Restricting Means 10 Spacer 11 Suction Gap 13 Lid Step 14 Conical Cone 15 Inclined surface of cone P Glass panel V Gap

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Claims (8)

[Claims] 1. A pair of plate glasses are hermetically sealed at their peripheral edges in a state where there is a gap between the surfaces of both plate glasses, and a suction hole for sucking and exhausting gas in the gap is provided in the plate glass. In a vacuum glass, a suction hole lid body used to seal the suction hole, wherein in a state where the lid body seals the suction hole, intrusion of a fluid into the suction hole is prevented. A lid for a vacuum glass suction hole, in which a flow regulating means for regulating is provided in a peripheral portion of the lid. 2. The vacuum glass suction hole lid according to claim 1, wherein the flow restricting means is constituted by an inclined surface provided on a peripheral portion of the lid. 3. The vacuum glass suction hole lid according to claim 2, wherein the lid has a conical portion, and the flow restricting means is constituted by an inclined surface of the conical portion. 4. The lid for a vacuum glass suction hole according to claim 3, wherein the pyramidal portion of the lid is a conical pyramidal portion. 5. The lid for a vacuum glass suction hole according to claim 1, wherein the flow restricting means is constituted by a step portion provided on a peripheral portion of the lid. 6. A method of using a lid for sealing a suction hole provided in a plate glass of vacuum glass using the lid according to claim 1, wherein the suction hole is used. A seal material and a spacer that are melted by heating are arranged on the surrounding plate glass, and at least the spacer is positioned within the working range of the flow restricting means of the lid body, and the lid body is located above the spacer and the seal material. And the spacer holds a suction gap between the plate glass and the lid body, sucks and exhausts the gas in the gap of the vacuum glass from the suction hole, and heats and melts the spacer and the sealing material. Then, the method of using a lid for a vacuum glass suction hole, wherein the lid is adhered to a plate glass with the sealing material to seal the suction hole. 7. The seal material and the spacer are formed as separate bodies, the seal material is placed on the plate glass, and the spacer and the seal material are placed in a state where the spacer is placed on the seal material. The method of using the lid for a vacuum glass suction hole according to claim 6, wherein the material is heated and melted. 8. The sealing material and the spacer are formed as separate bodies, the spacer is placed on the plate glass, and the suction hole is closer to the spacer than the flow restricting means. The method of using the lid for a vacuum glass suction hole according to claim 6, wherein the spacer and the sealing material are heated and melted in a state where the sealing material is placed on the plate glass.