JP2000336805A - Execution work structure of plate glass - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate a problem of damage, etc., of rib plate glass by adhering a height directional intermediate part of a butting part of a face and the rib plate glass by a sealing material of a high modulus, and adhering upper/lower parts by a sealing material of a medium or low modulus. SOLUTION: A modulus of a sealing material is decided by tensile stress of a 50% modulus by a tensile adhesion test stipulated in JIS A 5758. A high modulus is set not less than 4 kgf/cm2, a medium modulus is set not less than 2 kgf/cm2 and less than 4 kgf/cm2, and a low modulus is set not less than 0.5 kgf/cm2 and less than 2 kgf/cm2. A height directional intermediate part of the butt part is formed of a sealing material 3 of a high modulus, wind pressure resistant performance is shared by the part, and part other than the height directional intermediate part is formed on a sealing material 4 of a medium or low modulus to absorb a motional difference between face plate glass 1 and rib plate glass 2 when interlayer displacement is caused in a building frame to thereby reduce bending stress caused in upper/lower end parts of the rib plate glass by an earthquake to impart excellent earthquake resistant performance.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sheet glass construction structure which is hardly damaged by an earthquake or the like.

[0002]

2. Description of the Related Art In recent years, a large number of sheet glass construction structures in which openings of buildings such as buildings are formed by large glass screens have been constructed. As shown in FIG. 6, this construction structure is a sheet glass constituting a wall surface to which upper and lower ends are fixed, that is, face sheet glasses 1, 1,..., And a rib sheet glass 2, which is orthogonal to the face sheet glasses and penetrates between these face sheet glasses.
Are joined by sealing materials 3, 3,. As the sealing material 3, a high modulus sealing material having sufficient tensile strength, shear strength and adhesive strength against a force such as wind pressure acting in the out-of-plane direction of the face sheet glass is used.

The upper ends of the face plate glass 1 and the rib plate glass 2 are fixed by an upper fixing frame 11, and the lower ends thereof are also fixed by a lower fixing frame 12. The upper end of the face glass 1 and the upper fixed frame 11 and the lower end of the face glass 1 and the lower fixed frame 12 are joined by a low modulus sealing material (not shown) over the entire length.

FIG. 7 shows the displacement of the face plate glass 1 and the rib plate glass 2 in such a conventional example when interlayer displacement occurs in the frame due to an earthquake or the like. In the conventional example, since the upper and lower ends of the rib plate glass 2 are completely fixed to the frames 13 and 14 via the upper fixing frame 11 and the lower fixing frame 12, respectively, the upper fixing frame 11 side due to an earthquake or the like. When the frame 13 is displaced in the direction A and the frame 14 on the side of the lower fixed frame 12 is displaced in the direction B, and the interlayer displacement X is generated in the frame, similarly, the interlayer displacement of the displacement X between the upper and lower fixed frames 11 and 12 is similarly obtained. Occurs. That is, interlayer displacement similar to that of the frame occurs at the upper and lower ends of the rib plate glass 2.

On the other hand, since the face glass 1 receives the constraint of the sealing material 3 with the rib glass 2 and an inertial force due to the weight of the glass itself, the interlayer displacement Y of the face glass 1 is smaller than the interlayer displacement X of the frame. Generally try to be smaller. That is, as an original phenomenon, the face plate glass 1 and the rib plate glass 2 tend to move differently during an earthquake.

However, since the face sheet glass 1 and the rib sheet glass 2 are joined by the high modulus sealing material 3, the face sheet glass 1 and the rib sheet glass 2 try to move in the same manner. Since the upper and lower ends move in the same manner as the frames 13 and 14, the difference between the displacements of the face plate glass 1 and the rib plate glass 2 increases near the upper and lower ends.

As a result, the rib sheet glass 2 undergoes a U-shaped deformation 15 as shown in FIG. 7, and a large bending stress is generated at the upper and lower ends C and D of the rib sheet glass 2 so that the rib sheet glass 2 is often damaged.

Japanese Patent Laid-Open Publication No. Sho 56-3784 proposes a method of using a sheet glass construction structure provided with earthquake resistance in order to solve such a problem. FIG. 8 shows a perspective view of the main part. The rib plate glass 2 is attached in a double structure of a movable frame 16 provided at an end portion of the rib plate glass 2 and a fixed frame 17 fixed to the frame, and the rib plate glass 2 and the frame (not shown) are attached. It has a structure that can be separated and slid.

For this reason, it has been confirmed that the rib plate glass 2 moves in the same manner as the face plate glass 1 during an earthquake, no large bending displacement and bending stress occurs in the rib plate glass 2, and the rib plate glass 2 has excellent seismic performance. However, this method
At present, it is not easy to spread because the structure is complicated and it takes time for construction. Therefore, the development of a sheet glass construction structure that is earthquake-resistant and easy to construct has been desired.

[0010]

SUMMARY OF THE INVENTION An object of the present invention is to provide a sheet glass construction structure having earthquake resistance and easy construction.

[0011]

SUMMARY OF THE INVENTION The present invention is directed to an upright plurality.
The face glass sheets are arranged so that they are flush with each other.
Perpendicular to the face glass and between the face glass
Through the glass and extend on both sides of the face glass.
Face plate glass and rib plate glass
Is bonded with a sealing material at the butt
And fixed frames provided at the upper and lower edges of the opening of the skeleton
The upper and lower ends of the face plate glass and rib plate glass
In the construction structure of sheet glass with
The height of the butted portion between the chair plate glass and the rib plate glass
The middle part in the direction is the tensile adhesiveness described in JIS A5758.
50% modulus tensile stress by test is 4kgf / c
m ^TwoThe high modulus sealing material
Butted, face plate glass and rib plate glass
The upper and lower parts except the middle part in the height direction
The tensile stress of 50% modulus is 0.5kgf / cm
^TwoAbove and 4kgf / cm^TwoMedium or low module that is less than
Of glass sheet bonded by lath sealant
Provide a construction structure. With such a configuration,
Rib sheet glass follows interlayer displacement caused by earthquake etc.
And problems such as breakage can be solved.

[0012] The present invention also relates to a face plate glass in which a plurality of upright face plate glasses are arranged so as to be flush with each other, and are orthogonal to the face plate glass, and penetrate between the face plate glasses.
The rib plate glass is arranged so as to extend on both sides of the face plate glass, and the face plate glass and the rib plate glass are bonded by a sealing material at the abutting portion, and a fixed frame provided at the upper and lower edges of the skeleton opening. In the construction structure of the flat glass in which the upper and lower ends of the face glass and the rib glass are fitted, the tensile stress of 50% modulus is obtained by the tensile adhesion test described in JIS A5758 over the entire length of the butted face glass and the rib glass. Is provided with a medium or low modulus sealing material having a thickness of 0.5 kgf / cm ² or more and less than 4 kgf / cm ² .

When the glass size is small and the glass mounting position is low, the interlayer displacement can be followed by using a medium or low modulus sealing material over the entire length of the abutting portion between the face plate glass and the rib plate glass.
Also, the strength is sufficient.

In the present invention, a plurality of setting blocks are provided between the bottom of the fixing frame at the lower edge of the opening of the skeleton and the lower end of the face glass, and the setting block is a rib glass at the lower end of the face glass. It is preferable to interpose so as to be located at one-fifth or more of the width of the face plate glass near the middle portion in the width direction from the orthogonal portion with the above. By interposing the setting block in this way, the bending load on the rib sheet glass due to an earthquake or the like can be effectively reduced.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the present invention, the lower ends of the face plate glass 1 and the rib plate glass 2 are fixed to a lower fixing frame 12.
To be used. When the setting block 18 for supporting the load of the face glass 1 on the lower side is used, the face glass 1 and the rib glass 2 are used.
Is fitted to the lower fixed frame 12, and the sheet glass is placed on the setting blocks 18, 18 installed in the lower fixed frame 12. On the other hand, the upper ends of the face plate glass 1 and the rib plate glass 2 are attached by being fitted to an upper fixed frame 11 attached to the frame 13.

The modulus of the sealing material is JIS A
Determined by a tensile stress of 50% modulus by the tensile adhesion test described in 5758 (meaning a tensile stress when the sealing material has a length of 150%, which is a length that is 50% more than the original length). . High modulus is 4kgf
/ Cm ² or more, medium modulus is 2 kgf / cm ² or more and less than 4 kgf / cm ² , low modulus is 0.5 kg
f / cm ² or more and less than 2 kgf / cm ² .
Here, the sample is a 2-type (H-type) durability test specimen described in the section of preparation of a test specimen of the same JIS, and is produced using a sheet glass as an adherend.

As the material of the sealing material used in the present invention, a silicone-based sealing material such as a deacetic acid type, a deoxime type, and a dealcohol type is preferable. 50% mentioned above
A sealing material having a modulus tensile stress of 0.5 kgf / cm ² or more and less than 4 kgf / cm ² is a sealing material that undergoes sufficient compressive and tensile deformation with respect to a displacement at the time of an earthquake acting in the in-plane direction of the face glass. Is preferred. The compression / tensile strength is evaluated by a two-type (H-type) tensile test in which a sealing material is filled between two glass plates or aluminum or the like.

The failure mode of the sealing material at this time is considered to be cohesive failure in which the sealing material breaks and interfacial peeling in which the bonding surface of the sealing material peels, but the sealing material exhibiting the latter failure mode is inappropriate. It is. Here, the tensile strength refers to a load that can withstand when both ends of the test piece are pulled, and it does not matter whether the fracture is cohesive failure or interface peeling.

The tensile strength of the sealing material is more preferably 2.5 kgf / cm ² or more in consideration of the safety factor. Further, in order to perform sufficient compression and tensile deformation against the displacement at the time of an earthquake acting in the in-plane direction of the face sheet glass, as an empirical value, 1.0% to 2.5 kg at a 50% modulus tensile strength.
f / cm ² is more preferred.

The above-mentioned sealing material having a 50% modulus tensile stress of 4 kgf / cm ² or more is a sealing material having a sufficient shear strength against a force such as a wind pressure acting in an out-of-plane direction of the face glass. Is more preferable,
The content is the same as above, and more preferably 2.5 kgf / cm ² or more.

The destruction of the face plate glass 1 used in the construction structure of the plate glass during the earthquake was caused by the displacement of the rib plate glass 2 due to the movement of the face plate glass 1 in the in-plane direction and the fitting to a fixed frame having a corner. It is normal that the face glazing 1 is caused to collide with the corner portion thereof, and it is hardly observed that the face glazing 1 is caused by an earthquake that moves in the out-of-plane direction. Therefore, it is important to design a strength against an earthquake acting in the in-plane direction of the face glazing 1.

Are fixed at the upper and lower ends so as to be orthogonal to the face glass sheets 1, 1,..., Penetrate between the face glass sheets 1, 1 and extend to both sides of the face glass sheets. Conventionally, in a construction structure in which a face plate glass 1 and a rib plate glass 2 are bonded together with a sealing material, a sealing material at a butt portion between the face plate glass and the rib plate glass is reinforced over the entire length. High modulus is always used, and as described above, there is a problem in seismic performance. In the present invention, an intermediate portion in the height direction of the butted portion is used as a high modulus sealing material 3.
By sharing the wind resistance performance in that portion and making the portion other than the middle portion in the height direction a middle or low modulus sealing material 4, the face plate glass 1 and the rib plate glass 2 when interlayer displacement occurs in the frame. A function to absorb differences in movement has been added to improve seismic performance.

That is, the middle or low modulus sealing material 4 in the present invention is used to reduce bending stress generated at the upper and lower ends of the rib sheet glass 2 due to an earthquake and to prevent the rib sheet glass 2 from being damaged. In the present invention, the position of the boundary between the middle portion in the height direction of the butted portion of the face plate glass 1 and the rib plate glass 2 and the upper portion or the lower portion varies depending on the size, plate thickness, etc. of the plate glass. In the case of a face plate glass, the position is preferably 1/8 to 1/4 from the upper and lower ends in the height direction.

When a large wind pressure is not applied to the sealing material, such as when the glass size is small and the glass mounting position is low, the face glass and the rib glass are replaced with a medium or low modulus sealing material 4 over the entire length of the butted portion. It may be bonded by using. In this case, it is possible to follow the interlayer displacement between the face plate glass and the rib plate glass, and the strength is sufficient.

[0025]

FIG. 1 is a perspective view of an essential part of an embodiment of a plate glass construction structure of the present invention, and FIG. 2 is a perspective view of a butted portion of a face plate glass 1 and a rib plate glass 2 of the plate glass construction structure of the invention. Is shown. A face plate glass 1 having upper and lower ends fixed thereto, and a rib plate glass 2 which is perpendicular to the face plate glass 1, penetrates between the face plate glasses 1, 1 and extends on both sides of the face plate glass are joined by a sealing material. The face glass 1 and the rib glass 2 have the same height.

A high modulus sealing material 3 having sufficient shear strength against a force such as a wind pressure acting in an out-of-plane direction of the face sheet glass 1 is used in a middle portion in a height direction of the sealing material. Except for the middle part in the direction, a middle or low modulus sealing material 4 that can absorb the difference in interlayer displacement between the face plate glass and the rib plate glass during an earthquake is used.

Face glass 1 and rib glass 2
Of the lower fixed frame 1 is fitted to the lower fixed frame 12.
A plurality of setting blocks 1 installed at the bottom of the groove 2
The face plate glass 1 is placed on 8, 18
The lower fixed frame 12 is embedded in the floor surface forming the frame 14. The setting block 18 is for supporting the own weight of the face plate glass 1 and is preferably made of a material having sufficient strength to withstand this. For example, chloroprene rubber can be used. Also, the width of the setting block 18 needs to be a size that fits in the lower fixed frame 12. The number is required to be two or more and can be selected according to the weight of the face plate glass 1.

The setting block 18 is installed so as to be located at a position closer to the widthwise middle portion in the width direction of the face glass 1 from the lower end of the face glass 1 by one fifth or more of the width of the face glass 1. As a preferred embodiment, for example, when two setting blocks are used, the face plate glass 1 is located near the middle in the width direction of a quarter of the width of the face plate glass 1. The upper ends of the face plate glass and the rib plate glass are fitted to the upper fixed frame 11.

FIG. 3 is an explanatory view of the state of displacement occurring in the face plate glass 1 and the rib plate glass 2 when an interlayer displacement occurs due to an earthquake or the like in the plate glass construction structure of the present invention. In the above-described conventional example (FIG. 7), since the face glass 1 and the rib glass 2 are joined by the high modulus sealing material 3, when the in-plane displacement occurs in the frame, the face glass 1 and the rib glass 2 are different. Due to the movement, the rib plate glass caused a U-shaped displacement 15, and a large bending stress was generated in the rib plate glass 2 at the upper and lower ends of the rib plate glass 2, and the glass was often damaged.

On the other hand, when interlayer displacement occurs in the frame due to an earthquake or the like in the plate glass construction structure of the present invention, even if interlayer displacement X occurs in the frame, the abutting portion between the face plate glass 1 and the rib plate glass 2 will By using a medium- or low-modulus sealing material 4 that provides sufficient shear displacement against displacement during an earthquake other than the middle part in the height direction, the face plate glass 1 and the rib plate glass 2 are not much restrained from each other during the earthquake. The mechanism can be configured so as to move independently and not generate large bending displacement and bending stress in the rib sheet glass 2, thereby improving the seismic performance.

The setting blocks 18, 18
Is disposed so as to be located closer to the widthwise middle portion of the lower end of the face glass 1, so that the interlayer displacement of the upper and lower ends of the face glass 1 with respect to the interlayer displacement of the fixed frames 11 and 12 can be synchronized. Can be

FIG. 4 is an explanatory view showing a state of displacement generated in the face plate glass when the construction structure of the plate glass of the present invention receives the wind pressure F. For the above reason, even if a high modulus sealing material 3 is used in the middle part in the height direction, an excessive force due to interlayer displacement during an earthquake or the like does not act between the face plate glass 1 and the rib plate glass 2, so that Only that part is a high modulus sealing material 3 having sufficient shear strength and adhesive strength against the force such as wind pressure acting in the out-of-plane direction of the sheet glass, and the wind pressure F received by the face sheet glass 1 is changed by the rib sheet glass at that part. 2 to provide wind pressure resistance.

FIG. 5 is a perspective view of a main part of another embodiment of the sheet glass construction structure of the present invention. In this embodiment, a middle or low modulus sealing material 4 is used over the entire length of the butted portion between the face plate glass 1 and the rib plate glass 2. When the wind force F is not so large applied to the face glass 1 such as when the glass size is small and the glass mounting position is low, the sealing material 4 having a medium or low modulus over the entire length of the butted portion between the face glass 1 and the rib glass 2. Can be used.

In addition, as an example of the use of the above-mentioned plate glass construction structure, two sets of plate glass construction structures are prepared, and a face plate glass disposed at an end of one set of construction structures and another part. It is also conceivable to use one set of face plate glasses in such a manner as to be orthogonal to each other, and to join both orthogonal corners using a sealing material or the like.

[0035]

According to the present invention, by using a middle or low modulus sealing material at a portion other than the center in the height direction of the sealing material, bending stress generated at the upper and lower ends of the rib sheet glass due to an earthquake is reduced. Excellent seismic performance can be provided.

When the glass size is small and the glass mounting position is low, the face plate glass and the rib plate glass can follow the interlayer displacement by using a middle or low modulus sealing material over the entire length of the abutting portion, so that excellent seismic performance can be achieved. Can be provided.

[Brief description of the drawings]

FIG. 1 is a perspective view of a main part of a sheet glass construction structure according to an embodiment of the present invention.

FIG. 2 is a perspective view of a butt portion between a face plate glass and a rib plate glass according to the embodiment of the present invention.

FIG. 3 is an explanatory view of a displacement caused by an earthquake or the like in the sheet glass construction structure of the embodiment of the present invention.

FIG. 4 is an explanatory diagram of a displacement generated when a sheet glass construction structure of the embodiment of the present invention receives wind pressure.

FIG. 5 is a perspective view of a main part of a sheet glass construction structure according to another embodiment of the present invention.

FIG. 6 is a perspective view showing an example of a conventional plate glass construction structure.

FIG. 7 is an explanatory diagram of a displacement generated in a conventional plate glass construction structure due to an earthquake or the like.

FIG. 8 is a perspective view showing an example of a conventional sheet glass construction structure with improved earthquake resistance.

[Explanation of symbols]

 1: face glass 2: rib glass 3: high modulus sealing material 4: medium or low modulus sealing material 11: upper fixed frame 12: lower fixed frame 13: upper frame 14: lower frame 15: U-shaped deformation of rib glass 16: Movable frame 17: Fixed frame 18: Setting block

Claims (3)

[Claims] 1. A plurality of upright face glass sheets are flush with each other.
The face glass is orthogonal to the face glass and the face glass
So that it extends through both sides of the face glass
The rib plate glass is arranged, and the face plate glass and the rib plate glass match
At a fixed frame provided at the upper and lower edges of the opening of the skeleton.
Upper and lower ends of face glass and rib glass are fitted
In the flat glass construction structure, the butt portion between the face glass and the rib glass is
The middle part in the height direction is the tensile contact described in JIS A5758.
Tensile stress of 50% modulus by adhesion test is 4kgf
/ Cm^TwoThe high modulus sealing material
Of the butt portion between the face plate glass and the rib plate glass
The upper and lower parts excluding the middle part in the height direction are 50
% Modulus tensile stress is 0.5kgf / cm ^TwoOr more
4kgf / cm^TwoMedium or low modulus less than
Construction structure of sheet glass bonded by sealing material
Structure. 2. A plurality of upright face glass sheets are arranged so as to be flush with each other, and a rib sheet glass is arranged so as to be orthogonal to the face glass sheet, penetrate between the face glass sheets, and extend on both sides of the face glass sheet. The face plate glass and the rib plate glass are adhered to each other by a sealing material at their abutting portions, and the upper and lower ends of the face plate glass and the rib plate glass are fitted to fixed frames provided at the upper and lower edges of the skeleton opening. A 50% modulus tensile stress of 0.5 kgf according to a tensile adhesion test described in JIS A5758 is applied to the entire surface of the butted face glass and rib plate glass in the plate glass construction structure.
/ Cm ² or more and construction structure of the glass sheet are bonded by in less than 4 kgf / cm ² or low modulus sealant. 3. A plurality of setting blocks between a groove bottom of a fixed frame at a lower edge of a frame opening and a lower end of the face plate glass, wherein the setting block is connected to a rib plate glass at a lower end of the face plate glass. The plate glass construction structure according to claim 1 or 2, wherein the structure is interposed so as to be located closer to an intermediate portion in the width direction than at least one-fifth of the width of the face plate glass from the orthogonal portion.