JP2007138704A - Glass panel mounting structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To mount a glass panel visually advantageously without complicating its production steps. <P>SOLUTION: In this glass panel P mounting structure, a spacer 2 for space holding is interposed between a pair of plate glasses 1, the plate glasses are secured to each other at their outer peripheral parts with a sealing material 3, and a space part V between the plate glasses is kept in a depressurized state. The outside dimension of the outer plate glass 1B installed toward the outside with the glass panel installed on a building E is set larger than the outside dimension of the inner plate glass 1A installed toward the inside. A projection 10 projecting from the peripheral edge of the inner plate glass in the direction along the plate surfaces is formed on the outer plate glass along the at least one-side so that the peripheral edge of the inner plate glass does not project from the peripheral edge of the outer plate glass in the direction along the plate surfaces. The plurality of glass panels are positioned adjacent to each other so that the end faces of the projecting parts of the outer plate glasses face each other, and the projecting parts are connected to each other with connection devices D. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention provides a gap formed between the plate glasses by interposing a spacer for maintaining a gap between a pair of plate glasses whose plate surfaces are opposed to each other, and fixing the outer peripheral portions of the plate glasses with a sealing material. It is related with the glass panel which has hold | maintained the part in the pressure reduction state.

  A conventional glass panel has a spacer for holding a gap between a pair of plate glasses having the same outer dimensions, and the outer peripheral portions of the plate glasses are fixed with a sealing material, and the gap formed between the plate glasses is reduced in pressure. Kept in a state.

For this reason, as shown in FIG. 10, for example, a panel holding member (also referred to as a glazing channel) provided with a soft holding portion 6 that elastically adheres to the plate surface of the plate glass 1 (1A, 1B) on the outer peripheral portion of the glass panel P. When 8 is attached and attached to the sash 9 or the like of the building, the outer plate glass 1B attached to the outside of the building and soft as shown by the arrow over the entire circumference of the glass panel P Rainwater W that has entered the inside of the panel holding member 8 from between the holding portion 6 easily comes into contact with the sealing material 3, and the sealing material 3 is corroded by contact with the rainwater W and deteriorates at an early stage. There exists a fault which cannot hold the part V in a pressure-reduced state over a long period of time.
This invention is made | formed in view of the said situation, Comprising: It aims at enabling it to hold | maintain a space | gap part in a pressure-reduced state over a long term in the state which attached the glass panel to the building.

  As illustrated in FIG. 2, the first characteristic configuration of the present invention includes a spacer 2 for holding a gap between a pair of plate glasses 1 (1 </ b> A, 1 </ b> B) whose plate surfaces are opposed to each other, and the plate glass 1. The outer peripheral portions of the glass panel P are fixed with the sealing material 3, and the gap V formed between the glass sheets 1 is held in a reduced pressure state, and the glass panel P is attached to the building E. The outer dimension of the outer glass sheet 1B attached to the outside of the building in a state is made larger than the outer dimension of the inner glass sheet 1A attached to the inner side of the building, and the peripheral edge of the inner glass sheet 1A is more than the peripheral edge of the outer glass sheet 1B. Is also provided so as not to protrude in the direction along the plate surface.

[Action and effect]
Since the outer dimension of the outer plate glass 1B is made larger than the outer dimension of the inner plate glass 1A, the outer plate glass 1B is provided so that the periphery of the inner plate glass 1A does not protrude in the direction along the plate surface from the periphery of the outer plate glass 1B. The sealing material 3 can be positioned on the inner side in the plate surface direction than the peripheral edge of the outer plate glass 1B, and the glass panel P is attached to the building E. In this state, there is little possibility that the rainwater W that has entered the periphery of the glass panel P along the outer glass sheet 1B will come into contact with the sealing material 3.
Therefore, it is difficult for rainwater to come into contact with the sealing material with the glass panel attached to the building, and the sealing material is less likely to corrode with rainwater and deteriorate early. Can be kept in a state.

  As illustrated in FIG. 2, the second characteristic configuration of the present invention is the state in which the outer glass sheet 1 </ b> B is at least lower than the outer edge of the inner glass sheet 1 </ b> A with the glass panel P attached to the building E. It exists in the point provided so that it may protrude.

[Action and effect]
With the glass panel P attached to the building E, the outer plate glass 1B has a peripheral edge protruding at least below the inner peripheral plate glass 1A. Therefore, the sealing material 3 on the lower end side of the glass panel P is provided. The rainwater W that can be provided above the lower end of the outer glass sheet 1B and has entered the lower end side of the glass panel P along the outer glass sheet 1B is less likely to contact the sealing material 3.
Therefore, rainwater that easily enters and stays at the lower end side of the glass panel with the glass panel attached to the building is less likely to come into contact with the sealing material, so that the void can be reliably maintained in a reduced pressure state for a long period of time. .

  2 and 3, the third characteristic configuration of the present invention is that the outer glass sheet 1B is provided so that its peripheral edge protrudes from the peripheral edge of the inner glass sheet 1A over the entire periphery. It is in.

[Action and effect]
In a state where the glass panel P is attached to the building E, the outer plate glass 1B is provided so that the periphery of the outer plate glass 1B protrudes from the periphery of the inner plate glass 1A over the entire periphery. It is difficult to contact the sealing material 3 over the entire periphery of the panel P, and it is possible to attach the panel holding member 8 to the outer peripheral portion of the outer glass sheet 1B and attach it to the sash 9 as shown in FIG. Become.
Therefore, it is difficult for rainwater to come into contact with the sealing material over the entire circumference of the glass panel with the glass panel attached to the building, so that corrosion and deterioration of the sealing material due to rainwater can be reliably prevented. Also, it is possible to attach it to the building advantageously in terms of appearance so that the outer glass sheet does not protrude outside by using panel holding members and sashes that are small in size in the glass panel thickness direction and easy to reduce in size and weight. it can.

  As illustrated in FIGS. 4 to 8, the fourth characteristic configuration of the present invention is that the outer glass sheet 1 </ b> B of the glass panel P attached to the building E so as to be adjacent to each other is changed to the outer glass sheet 1 </ b> B of the adjacent glass panel P. The opposing peripheral edge is provided so as to protrude toward the adjacent glass panel rather than the peripheral edge of the inner plate glass 1A.

[Action and effect]
While the glass panels P are attached to the building E so as to be adjacent to each other, the gap F1 between the outer glass sheets 1B of the adjacent glass panels P is reduced, and the amount of the sealing material C1 filling the gap F1 is reduced. A sufficient amount of the sealing material C2 can be filled in the gap F2 between the inner plate glasses 1A.
Therefore, in a state where the glass panels are attached to the building so as to be adjacent to each other, the sealing material that fills the gaps between the outer glass plates is not conspicuous from the outside of the building, but it is attached to the gaps between the inner glass plates while advantageously attaching to the exterior. It is easy to ensure the sealing performance with the filled sealing material.

  As illustrated in FIGS. 4 to 6, the fifth characteristic configuration of the present invention is, in particular, the glass panel P attached to the corner A of the building E so that the plate surfaces are adjacent to each other in a state of crossing each other. The outer plate glass 1B is provided so that the periphery of the outer plate glass 1B protrudes toward the glass panel adjacent to the outer plate glass 1A.

[Action and effect]
The glass panel P in which the periphery of the inner plate glass 1A protrudes toward the glass panel adjacent to the periphery of the outer plate glass 1B, or the glass panel P in which the periphery of the inner plate glass 1A and the periphery of the outer plate glass 1B are aligned is removed from the building. Compared with the case of attaching to the corner A, the gaps F1 and F2 between the glass panels P at the protruding corner A can be reduced.
Therefore, with the glass panel attached to the corner of the building, the gap between the glass panels at the corner can be easily filled with a small amount of sealing material, so that the construction cost can be reduced. The sealing material is not conspicuous and can be attached advantageously in appearance.

  As illustrated in FIGS. 7 and 9, the sixth characteristic configuration of the present invention is adjacent to the protruding portion that protrudes toward the glass panel adjacent to the peripheral edge of the inner plate glass of the outer plate glass. In the point which has provided the fixing | fixed part of the connector which connects the said protrusion part of the said glass panel.

[Action and effect]
In a state where the glass panels P are attached to the building E so as to be adjacent to each other, the connector D is attached to the fixing portion 11 provided on the protruding portion 10 that protrudes toward the adjacent glass panel from the periphery of the inner side glass 1A of the outer side glass 1B. It can fix and can connect adjacent glass panels P.
Therefore, compared with the case where a cylindrical body for forming a through hole is provided across the outer plate glass and the inner plate glass sandwiching the gap, and the connecting tool is fixed with a bolt inserted into the through hole, the glass panel Adjacent glass panels can be connected without complicating the manufacturing process.
In addition, with the glass panels attached to the building so as to be adjacent to each other, the connector can be fixed by entering the gap between the inner plate glasses, so that the inner plate glass protrudes closer to the adjacent glass panel side than the peripheral edge of the outer plate glass. Compared with the case where the connecting tool is fixed to the fixing portion provided in the protruding portion, the amount of protrusion of the connecting tool toward the inner surface of the glass panel can be reduced, and the mounting can be advantageously performed in appearance.
In addition, although the code | symbol was described in order to make contrast with drawing convenient, this invention is not limited to the structure of an accompanying drawing by this entry.

Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the parts denoted by the same reference numerals as those in the conventional example indicate the same or corresponding parts.
[First Embodiment]
FIG. 1 shows one embodiment of the glass panel of the present invention, and this glass panel P is spaced along a plate surface between a pair of plate glasses 1 (1A, 1) whose plate surfaces are opposed to each other. Solder glass having a low gas permeability as a sealing material having a melting point lower than that of the plate glass 1 over the entire periphery of the outer periphery of the plate glass 1. A low-melting glass 3 or the like is fixed, a gap V is formed between a pair of plate glasses 1, and the gap V is sucked and held in a reduced pressure state.

The plate glasses 1A and 1B are made of a transparent rectangular float plate glass having a thickness of about 3 mm in the present embodiment, and one plate glass 1A covers the suction part 4 used for sucking the gap V. The cap 5 is bonded and fixed.
Of the two plate glasses 1A and 1B, one plate glass 1A is provided as an inner plate glass attached toward the inside of the building with the glass panel P attached to the building E, and the other plate glass 1B is provided with the glass panel P. In the state attached to E, it is provided as an outer glass plate attached toward the outside of the building.

The outer dimension of the outer glass sheet 1B is about 6 mm longer and wider than the outer dimension of the inner glass sheet 1A, and the periphery of the inner glass sheet 1A does not protrude in the direction along the plate surface from the peripheral edge of the outer glass sheet 1B. As described above, the outer plate glass 1B is protruded in the direction along the plate surface by about 3 mm from the periphery of the inner plate glass 1A over the entire circumference, and the outer glass plate 1B is attached to the building E with the glass panel P attached to the building E. The peripheral edge protrudes downward from the peripheral edge of the inner glass sheet 1A.
Moreover, since the periphery of the outer side glass 1B is made to protrude in the direction along a plate surface from the periphery of the inner side glass 1A over the whole periphery, the outer peripheral parts of the plate glass 1 (1A, 1B) are made by the low melting glass 3. When fixing, by placing a paste-like low-melting-point glass material on the protruding portion 10, the void portion V can be formed with good workability.

The spacer 2 is made of a material having a compressive strength of 5 × 10 ³ kgf / cm ² (about 4.9 × 10 ⁴ N / cm ² ) or more, for example, stainless steel (SUS304), and has a diameter of 0.8. A cylindrical shape having a height of about 3 mm to 1.0 mm and a height of about 0.15 mm to 1.0 mm is preferable, and the interval between the spacers 2 is preferably about 20 mm.

  FIG. 2 shows a panel holding member having a U-shaped cross section provided with a soft holding portion 6 and a water drain hole 7 which are elastically adhered to the plate surfaces of the glass plates 1A and 1B on the outer peripheral portion of the glass panel P. 8 is attached to the sash (a part of the building E) 9 attached to the horizontal wall of the building E in a vertical posture and the peripheral edge of the outer glass sheet 1B is the entire circumference. Since the rainwater W penetrates into the inside of the panel holding member 8 from between the outer plate glass 1B and the soft holding portion 6 as shown by the arrow, it is provided so as to protrude from the peripheral edge of the inner plate glass 1A. The rain water W is unlikely to contact the low melting point glass (sealing material) 3 over the entire circumference of the glass panel P. Therefore, the low melting point glass 3 is not easily corroded and deteriorated by the rain water W. It can be kept in a reduced pressure state for a long time.

[Second Embodiment]
FIG. 3 shows a state in which the panel holding member 8 is attached to the outer peripheral portion of the outer glass sheet 1B of the glass panel P and attached to the sash 9 of the building E, and the dimension in the glass panel thickness direction is small. The panel holding member 8 and the sash 9 that can be easily reduced in size and weight can be attached to the building E.

[Third Embodiment]
FIG. 4 shows a state in which the two glass panels P are attached to the corner A of the building so as to be adjacent to each other with the plate surfaces crossing each other, and the periphery of the outer plate glass 1B is attached to the inner plate glass 1A. Since it is provided so as to protrude toward the adjacent glass panel rather than the periphery, a gap between the glass panels P at the protruding corner A, that is, a gap F1 between the outer glass sheets 1B and a gap F2 between the inner glass sheets 1A are provided. The gaps F1 and F2 can be made small and easily filled with a small amount of joint sealing material C, the construction cost can be reduced, and the joint sealing material C is not conspicuous and is advantageously attached in appearance. Can do.

  In addition, as a form which attaches two pieces of the said glass panels P to the corner A of a building, the end surface of the outer side glass 1B in one glass panel P and the outer surface of the outer side glass 1B in the other glass panel P are substantially flush. 5, even if the gaps F1 and F2 between the glass panels P are filled with the joint sealing material C as shown in FIG. 5, the outer plate glass in one glass panel P as shown in FIG. A gap F3 between the inner surface of 1B and the other glass panel P may be filled with a joint sealing material C.

[Fourth Embodiment]
7 to 9 show a state in which the four glass panels P are arranged side by side and attached to the building E so as to be adjacent to each other. The peripheral edge of the outer glass sheet 1B of each glass panel P is defined by the peripheral edge of the inner glass sheet 1A. Is provided so as to protrude to the adjacent glass panel side, so that the inner plate glass 1A is reduced while reducing the gap F1 between the outer plate glasses 1B and reducing the amount of the joint sealing material C (C1) filling the gap F1. A sufficient amount of joint sealing material C (C2) can be filled in the gaps F2 between the inner glass plates 1A while being advantageously attached from the outside so that the joint sealing material C does not stand out from the outside of the building E. A sufficient sealing property can be secured by the sealing material C2 filled in the gap portion.

  Moreover, the bolt through-hole as a fixing | fixed part of the connector D which connects the protrusion part 10 and the protrusion part 10 of the adjacent glass panel P to the protrusion part 10 which protrudes rather than the periphery of the inner side plate glass 1A of the outer side glass plate 1B. 11, the connecting tool D fixed to the bolt through hole 11 with the bolt 12 is fixed to the building E, the adjacent glass panels P are connected to each other and fixed to the building E, and the manufacturing process of the glass panel P Adjacent glass panels P can be connected to each other without complicating, and the connector D can be fixed by entering the gap F2 between the inner glass plates 1A. It can be attached advantageously in terms of appearance. In this case, if necessary, an elastic cushioning material is inserted into the gap between the bolt through hole 11 and the bolt 12 or the gap between the protruding portion 10 and the fixture 10, and the impact force on the glass panel is applied to the relative movement due to external force. Decrease.

  In addition, as a form in which adjacent glass panels P are connected and fixed to the building E, a connecting tool that connects and connects a part of the protruding portions 10 integrally from the front and back is fixed to the building E, or the protruding portions 10 are connected. The connecting member D is inserted in the projecting portion 10 so that the outer fitting member is fitted between the projecting portions 10 and fixed to the building E, and the projecting portion 10 is not provided with the bolt through hole 11 or the like. A part of 10 may be a fixing part of the connector D.

[Other Embodiments]
<1> The glass panel of the present invention is such that a part of the periphery of the outer plate glass protrudes in a direction along the plate surface rather than the periphery of the inner plate glass, and the periphery of the inner plate glass extends along the plate surface rather than the periphery of the outer plate glass. It may be provided so as not to protrude in the direction.
That is, for example, in the case of a rectangular glass panel, only one side, two sides, or three sides of the outer plate glass may be provided in a state of protruding in the direction along the plate surface from the periphery of the inner plate glass.
<2> In the glass panel of the present invention, the outer peripheral portions of the plate glass may be fixed with metal solder mainly composed of indium, lead, tin, zinc or the like as a sealing material.
<3> The glass panel of the present invention may be attached to a window frame (sash) of an openable / closable window provided in a building.
<4> In the glass panel of the present invention, the peripheral edge of the outer glass sheet that is attached so as to be adjacent to each other in a state in which the plate surfaces intersect each other at the projecting corners of the building is projected to the adjacent glass panel side rather than the peripheral edge of the inner glass sheet. The protruding portion formed in this manner may be provided with a fixing portion for a connecting tool that connects the protruding portion and the protruding portion of the adjacent glass panel.
<5> The plate glass used in the glass panel of the present invention is not limited to the float glass described in the previous embodiment, and the type thereof can be arbitrarily selected. For example, template glass, ground glass (surface treatment) Glass having a function of diffusing light), meshed glass or tempered glass, plate glass having functions such as heat ray absorption, ultraviolet ray absorption, heat ray reflection, and low radiation, and combinations thereof.
The glass composition may be soda silicate glass (soda lime silica glass), borosilicate glass, aluminosilicate glass, or various crystallized glasses.
<6> The plate glass used for the glass panel of the present invention is a plate glass having a thickness of more than 3 mm, for example, about 10 mm, particularly in the case of a plate glass or tempered glass considering wind pressure strength in the fourth embodiment. It may be what you do.
<7> The material of the spacer used for the glass panel of the present invention is not limited to stainless steel. For example, the spacer may be formed of various materials such as Inconel 718, other metal materials, quartz glass, and ceramics. In addition, the shape of the spacers is not limited to a cylindrical shape, and may be a prismatic shape. The spacing between the spacers can be changed as appropriate.

Partially cutaway perspective view showing glass panel Partial cross-sectional perspective view showing a glass panel attached to a building Partial cross-sectional perspective view showing a glass panel attached to a building Sectional view showing the state of glass panel installation in the building Sectional view showing the state of glass panel installation in the building Sectional view showing the state of glass panel installation in the building Plan view showing the state of glass panel installation in the building VIII-VIII sectional view of FIG. IX-IX sectional view of FIG. Illustration of prior art

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Plate glass 1A Inner plate glass 1B Outer plate glass 2 Spacer 3 Sealing material 10 Protrusion part 11 Fixing part A Outer corner part D Connection tool E Building P Glass panel V Air gap part

Claims (1)

A spacer for holding a gap is interposed between a pair of plate glasses whose plate surfaces are opposed to each other, the outer peripheral portions of the plate glasses are fixed with a sealing material, and the gap formed between the plate glasses is in a reduced pressure state. The glass panel mounting structure held in the
The outer dimension of the outer glass sheet attached to the outside of the building with the glass panel attached to the building is made larger than the outer dimension of the inner glass sheet attached to the inside of the building, and the periphery of the inner glass sheet is the outer side Protruding portions that protrude in the direction along the plate surface from the peripheral edge of the inner plate glass are provided along at least one side of the outer plate glass so as not to protrude in the direction along the plate surface from the peripheral edge of the plate glass,
A glass panel mounting structure in which a plurality of the glass panels are adjacent to each other so that the end faces of the protruding portions of the outer plate glass face each other, and the protruding portions are connected by a connector.

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