JPS6363845A - Earthquake damping mount method of glass panel - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to a method for seismic isolation mounting of glass panes.

[Existing technology] The back mullion method is known as one of the methods for attaching glass plates. This method eliminates the part that is visible from the outside when installing the glass plate in the vertical direction, and glues the mullion on the indoor side and the glass plate with a sheet tent made of silicone, which has high weather resistance and adhesive strength. This method uses force to strengthen the glass. FIG. 2 shows a conventional example of such a packed mullion system, in which a glass plate 1 is bonded to a bar or a coumalion 2 using structural silicone 7. In this case, if hard silicone is used, wind pressure strength can be obtained, but as shown in Figure 3, this silicone part undergoes large shear deformation during an earthquake, making it prone to fatigue and breakage. If soft silicone is used, the silicone will easily deform when the glass plate is exposed to wind pressure, making the glass plate susceptible to stress deformation, creating a large stress at the edges of the glass plate and potentially causing it to break. This poses a major obstacle to practical use.

[Means for Solving the Problems] The present invention has been made to solve the above-mentioned problems in the conventional packed mullion system.
It is characterized by absorbing lateral shear deformation occurring between the glass plate and the pack mullion within these double back mullions during an earthquake.

That is, in the present invention, the glass plate is attached by screwing the secondary par 2 mullion to the pack mullion placed on the indoor side along the end surface through a sliding washer and a horizontal loose hole. A novel installation method is provided for adhesively fixing the glass pane to the glass plate with a sealant.

Next, the present invention will be specifically explained with reference to the drawings. FIG. 1 shows a cross section of the glass plate mounting method according to the present invention, where l is a glass plate, 2 is a packed mullion, 3 is a secondary packed mullion, and the glass plate l is a 2 It is then adhesively fixed to the back mullion 3 with a sealant 7, such as structural silicone. Although not shown, the pack mullion 2 is attached to a slab or the like that constitutes a part of the structure of the building, and the glass plate 1 is attached to the indoor side along the end surface. The secondary back mullion 3 is attached to the pack mullion 2 so as to absorb shear displacement in the lateral direction parallel to the glass plate surface during an earthquake, and the two constitute a double pack mullion.

That is, the secondary back mullion 3 is a hollow structure with a rectangular cross section, and a horizontally elongated loose hole 5 is provided on the surface facing the pack mullion 2 so that it can be inserted into the pack mullion 2 through a sliding washer 4. Attached with screw 6,
When a lateral force above a certain level is applied between the pack mullion 2 and the glass plate 1 due to an earthquake or the like, the secondary back mullion 3 moves against the pack mullion 2 within the range of the loose hole 5 in the sliding washer 4. It is possible to slide. In this case, the pack mullion 2 and the secondary back mullion 3 are connected by screws 6 at two or more locations in the longitudinal direction, and the number of screws 6 is appropriately selected within a range that allows the two to be connected with sufficient strength.

In addition, the sliding washer 4 is desirably made of a fluororesin such as Teflon (trade name) so that the secondary back mullion 3 can be displaced relative to the pack mullion 2 when the screw 6 is tightened. 8 is a watertight sealant filled in the joints of the glass plates.

When installing the glass plate l, its upper and lower ends are usually held with sashes, but its left and right ends are adhesively fixed to the secondary back mullion 3 with a sealant 7. In this case, it is desirable to use a hard sealant as the sealant 7 and to bond the glass plate 1 to the secondary back mullion 3 as firmly as possible. This is because the lateral shear displacement during an earthquake can be absorbed between the secondary hexagonal mullion 3 and the pack mullion 2. Therefore, the sealant 7 does not deform when such a lateral shearing force occurs, and only needs to transmit this to the secondary back mullion 3.

On the other hand, by firmly adhesively fixing the glass plate 1 to the secondary back mullion 3 with a hard sealant that does not easily deform,
It is possible to obtain the wind pressure strength of the glass plate l.

[Effects of the Invention] As explained above, the present invention does not directly adhesively fix the glass plate to the back mullion, but screws the secondary back mullion to the conventional pack mullion via a washer and a loose hole. The double packed mullion structure allows relative movement within the range of the loose hole when a fixed lateral shearing force is applied between the two.
Even if the glass plate is firmly adhesively fixed to the next pack mullion with a hard sealant, the lateral shearing force is absorbed within the double back mullion, thereby preventing fatigue rupture of the sealant. And since it is a hard sealant,
Since the sheet tent deforms little when the glass plate is subjected to wind pressure, it is possible to firmly hold the glass plate and eliminate the occurrence of large stress on the glass edges.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of a glass plate mounting section according to the present invention, and FIGS. 2 and 3 are cross-sectional views of a conventional example. In the figure, 1 is a glass plate, 2 is a pack mullion, 3 is a secondary back mullion, 4 is a sliding washer, 5 is a loose hole, and 6 is a screw. Bracket 1 Mouth 2nd close

Claims (1)

[Claims] 1. A secondary back mullion is screwed through a sliding washer and a horizontal loose hole to a back mullion placed on the indoor side along the installation end surface of the glass plate, and the secondary back mullion is A seismic isolation mounting method for a glass plate, characterized by adhesively fixing the glass plate with a sealant. 2. The seismic isolation mounting method of a glass plate according to claim 1, characterized in that the glass plate is adhesively fixed to the secondary back mullion using a hard sealant.