JP2021152285A - Cold bend glass unit using metal frame - Google Patents

Abstract

To provide a cold bend glass unit using a metal frame, which is manufactured in a cold bend method while the peripheral edge of the glass plate is held by a metal frame made of metal (for example, an aluminum frame), which is free from cracking or breaking even when the glass plate is twisted or bent.SOLUTION: A cold bend glass unit 1 includes: a glass plate 2 to be twisted or bent in the cold bend method; a metal frame 3 arranged along at least one side of the glass plate 2 sandwiching the periphery of the glass plate 2; and a frame holder 4 attached to a building frame 5 covering and holding the metal frame 3. The metal frame 3 has notches 7 arranged along the longitudinal direction at intervals and formed in a direction intersecting the longitudinal direction.SELECTED DRAWING: Figure 1

Description

The present invention relates to a cold bend glass unit using a metal frame as a frame for holding the peripheral edge of a glass plate.

A cold bend method is known in which a glass plate is attached to the building frame at the site while twisting (bending) the glass plate together with the sash (frame) or only the glass plate little by little. In particular, as a material for bending only a glass plate, for example, Patent Document 1 is known.

JP-A-2017-121804

However, when an aluminum frame made of aluminum is used as the frame of the glass plate and the glass plate with the frame is made of cold bend glass, it is difficult for the aluminum frame to be deformed in accordance with this. That is, glass can withstand a certain amount of stress and therefore twists and bends, but since the aluminum frame is made of metal made of aluminum, it cannot follow this twist and bend, and the aluminum holder breaks first. Or it will be damaged.

The present invention has been made in consideration of the above-mentioned prior art, and the glass plate is twisted or bent by the cold bend method while the peripheral edge of the glass plate is held by a metal metal frame (for example, an aluminum frame) to perform cold bend. It is an object of the present invention to provide a cold bend glass unit using a metal frame in which the metal frame does not crack or break following the twisting or bending even if it becomes glass.

In order to achieve the above object, in the present invention, a glass plate to be twisted or bent by a cold bend method and a metal material arranged along at least one side of the glass plate and sandwiching the peripheral edge of the glass plate. A metal frame and a frame holder that covers and holds the metal frame and should be attached to the building frame are provided, and the metal frames are arranged at intervals along the longitudinal direction thereof and intersect with the longitudinal direction. Provided is a cold bend glass unit using a metal frame characterized by having a notch formed in a direction.

Preferably, the cut portion is formed in the entire circumferential direction so as to divide the metal frame, and the metal frame is formed by arranging a plurality of frame segments in the longitudinal direction.

Preferably, the notch is formed with a predetermined thickness.

Preferably, the metal frame has an arcuate outer peripheral surface in cross-sectional view, the frame holder has an inner peripheral surface along the arcuate outer peripheral surface of the metal frame, and the metal frame has an arcuate outer peripheral surface. It can rotate in the frame holder.

According to the present invention, since the metal frame has a notch, the glass plate is twisted (twisted) or bent by the cold bend method to become cold bend glass, and at that time, along the longitudinal direction of the metal frame. Even if a force acts in the twisting direction, the metal frame can easily follow the shape of the cold bend glass by gradually turning the angle toward the twisting direction at the notched portion. Therefore, even if a twisting force is applied to the metal frame, the metal frame will not be cracked or damaged.

If the cut portion is formed entirely along the circumferential direction of the metal frame so as to divide the metal frame, the metal frame will be formed by a plurality of frame segments, so that each frame segment is formed by the cold bend method. Further followed by twisting and bending.

Further, it is assumed that a predetermined thickness is provided in the cut portion, that is, a gap is provided between the metal frames (frame segments) via the cut portion, so that a force acts on the metal frame in the bending direction by the cold bend method. However, the thickness (gap) of the cut portion can accept the change in the angle of the metal frame due to bending. That is, even if a force is applied in such a bending direction due to the shape of the cold bend glass, the metal frame will not be cracked or damaged.

Further, by forming both the inner peripheral surfaces of the frame holder as the outer peripheral shape of a circle in a cross-sectional view corresponding to the outer peripheral surface of the metal frame, the outer peripheral surface of the metal frame slides on the inner peripheral surface of the frame holder. The metal frame can be rotated in the frame holder. Therefore, when the glass plate is twisted (twisted) or bent by the cold bend method, it is possible to suppress the application of a load due to deformation to the metal frame, and it is possible to prevent the metal frame from being damaged.

It is a schematic external view of the cold bend glass unit using the metal frame which concerns on this invention. It is a schematic detailed view of the cold bend glass unit using the metal frame which concerns on this invention. It is a schematic cross-sectional view which shows the relationship between a metal frame and a frame holder. It is a schematic cross-sectional view which shows the relationship between a metal frame and a frame holder. It is a schematic cross-sectional view which shows the relationship between a metal frame and a frame holder. It is a schematic external view when a glass plate becomes cold bend glass. It is the schematic which shows the frame segment. It is a schematic external view when the glass plate becomes another cold bend glass.

As shown in FIGS. 1 and 2, the cold bend glass unit 1 using the metal frame according to the present invention has a glass plate 2 to be twisted or bent by the cold bend method and along at least one side of the glass plate 2. It is provided with a metal frame 3 made of metal, which is arranged in a row. As a specific material, aluminum can be used. The metal frame 3 sandwiches the peripheral edge of the glass plate 2. Specifically, a seal body 6 made of an elastic material is interposed between the metal frame 3 and the glass plate 2, the seal body 6 sandwiches the peripheral edge of the glass plate 2, and the metal frame 3 further holds the peripheral edge of the glass plate 2. The seal body 6 is covered and sandwiched. Therefore, the seal body 6 has a concave shape that sandwiches the peripheral edge of the glass plate 2, and the peripheral edge of the glass plate 2 is fitted into the recessed portion. The metal frame 3 also has a concave shape that sandwiches the seal body 6, and the seal body 6 is fitted together with the glass plate 2 in the recessed portion.

In the example of the figure, the metal frame 3 is arranged so as to extend in the vertical direction with respect to the left and right side sides of the glass plate 2. The glass plate 2 used in the present invention may be any glass plate to which the cold bend method is applied, and in addition to the paired glass as shown in the figure, a single plate glass or a laminated glass can also be applied. Since the pair glass is shown as the glass plate 2 in the figure, two single glass plates are arranged via an air layer, and a spacer (not shown) and a sealing material (not shown) are arranged around the pair glass. There is. Further, the cold bend glass unit 1 further includes a frame holder 4 that covers the metal frame 3. The frame holder 4 should hold the metal frame 3 and be attached to the building skeleton 5 (H steel is shown as an example of the building skeleton 5 in the figure).

A cut portion 7 is formed in the metal frame 3. The cut portions 7 are arranged at intervals along the longitudinal direction of the metal frame 3 and are formed in a direction intersecting the longitudinal direction of the metal frame 3 (horizontal direction in the drawing). In the example of the figure, the cut portion 7 is formed in the entire circumferential direction of the metal frame 3 so as to divide the metal frame 3. As a result, the metal frame 3 is formed with a plurality of frame segments 8 arranged side by side in the longitudinal direction. By connecting such frame segments 8, a long metal frame 3 is formed. By forming the metal frame 3 with a plurality of frame segments 8 in this way, each of the frame segments 8 can be arranged so as to face different angles. That is, the frame segments 8 can take different rotation angles one by one with the longitudinal direction of the metal frame 3 as the axial direction. As a result, even if the glass plate 2 becomes cold bend glass by the cold bend method, the metal frame 3 itself can follow the twist of the glass plate 2 so as to allow it.

The cut portion 7 may be formed only in a part of the metal frame 3 without being formed over the entire circumference. That is, even if the metal frame 3 is not completely divided to form the frame segment 8, the metal frame 3 is deformed by following the twist (twist) of the cold bend glass by forming the cut portion 7 within a certain range. be able to. This prevents the metal frame 3 from being cracked or damaged.

As described above, if the metal frame 3 is provided with the cut portion 7 as in the cold bend glass unit 1 using the metal frame according to the present invention, the glass plate 2 is twisted (twisted) or bent by the cold bend method. Even if a force is applied in the twisting direction along the longitudinal direction of the metal frame 3, the metal frame 3 can easily be twisted in the direction of twisting at the notch 7. It can be made to follow the shape of the cold bend glass so as to face. Therefore, even if a twisting force is applied to the metal frame 3, the metal frame 3 is not cracked or damaged. Further, if the cut portion 7 is formed entirely along the circumferential direction of the metal frame 3 so as to divide the metal frame 3, the metal frame 3 is formed by a plurality of frame segments 8, so that each of the metal frames 3 is formed. The frame segment 8 is further followed by twisting and bending of the cold bend method.

Further, as shown in FIGS. 3 to 5, the metal frame 3 has an arc-shaped outer peripheral surface 3a in a cross-sectional view (viewed from a direction orthogonal to the longitudinal direction). On the other hand, the frame holder 4 has an inner peripheral surface 4a that follows the arc shape of the outer peripheral surface 3a of the metal frame 3. Therefore, the outer peripheral surface 3a and the inner peripheral surface 4a have a concentric circle and an arc shape along the circumference of substantially the same diameter (the inner peripheral surface 4a has a diameter slightly larger than the outer peripheral surface 3a). The outer peripheral surface 3a and the inner peripheral surface 4a are slidable with each other, so that the metal frame 3 can rotate in the frame holder 4. In the figure, the state of FIG. 4 is a state in which the glass plate 2 is parallel to the building skeleton 5, the glass plate 2 is bent by the cold bend method, and the glass plate 2 is screwed outward with respect to the building skeleton 5. An example of this is shown in FIG. 3, and an example of being twisted inward with respect to the building skeleton (on the side of the building skeleton 5) is shown in FIG.

In this way, by forming both the inner peripheral surface 4a of the frame holder 4 as the outer peripheral shape of a circle in a cross-sectional view corresponding to the outer peripheral surface 3a of the metal frame 3, the outer peripheral surface 3a of the metal frame 3 becomes the frame holder. The metal frame 3 can rotate in the frame holder 4 by sliding on the inner peripheral surface 4a of 4. Therefore, when the glass plate 2 is twisted (twisted) or bent by the cold bend method, it is possible to suppress the application of a load due to deformation to the metal frame 3 and prevent the metal frame 3 from being damaged. Can be done. This, in combination with forming the notch portion 8 in the metal frame 3 as described above, can be said to be a further ingenuity to correspond to the cold bend method. By doing so, as shown in FIG. 6, even if the glass plate 2 is twisted or bent to become cold bend glass, the metal frames 3 (frame segments 8) having the cut portions 8 are respectively. Since the metal frame 3 itself is rotated and followed in the frame holder 4 by being twisted following this, an unreasonable force is not applied to the metal frame 3 and damage to the metal frame 3 can be prevented. The frame holder 4 is securely fixed to the building frame 5 by the bolt 9. Further, a sealing material 10 for preventing the intrusion of dust and the like is formed between the outer surface of the glass plate 2 and the frame holder 4. The metal frame 3 is exposed from between the inner surface of the glass plate 2 and the frame holder 4. By widening the frontage of the frame holder 4 in this way, it is possible to prevent the frame holder 4 and the glass plate 2 from coming into contact with each other when the glass plate 2 is deformed. Further, in the case where the glass plates 2 as shown in this example are arranged side by side to form the outer wall of the building, the frame holder 4 holding the peripheral edge of the adjacent glass plates 2 in order to prevent the intrusion of dust and the like. A sealing material 11 is arranged between them.

As is clear from FIG. 7, the cut portion 7 may be formed having a predetermined thickness. Here, the predetermined thickness of the cut portion 7 is to provide a gap 12 between the metal frames 3 (frame segments 8) via the cut portion 7. The gap 12 is formed so as to gradually widen toward one side of the metal frame 3 (extending from the side surface of one side of the metal frame 3 toward the side surface of the other side, and the thickness toward the tip thereof. 7) A notch formed so as to gradually narrow. That is, the gap 12 has a so-called wedge shape when viewed from the side. As a result, even if a force acts on the metal frame 3 in the bending direction by the cold bend method, the thickness (gap 12) of the cut portion 8 can accept the change in the angle of the metal frame 3 due to bending. That is, even if a force is applied in such a bending direction due to the shape of the cold bend glass, the metal frame 3 is not cracked or damaged. Specifically, if the gap 12 is formed so as to expand outward with respect to the building skeleton 5, as shown in FIG. 8, when a cold bend method is used in which the gap 12 is bent outward with respect to the building skeleton 5. Will also be available.

In the present invention, when the glass plate 2 is twisted by the cold bend method, the metal frame 3 is twisted or rotated to follow it, and when it is bent, the gap 12 is shrunk to follow it. Is to be realized. As described above, the present invention is a very useful technique when constructing a curtain wall or various buildings by cold bend glass using the cold bend method.

1: Cold bend glass unit using a metal frame 2: Glass plate 3: Metal frame, 3a: Outer surface of the metal frame 4: Frame holder, 4a: Inner peripheral surface of the frame holder 5: Building frame, 6 : Seal body, 7: Notch, 8: Frame segment, 9: Bolt, 10: Seal material, 11: Seal material, 12: Gap

Claims (4)

A glass plate that should be twisted or bent by the cold bend method,
A metal frame arranged along at least one side of the glass plate and sandwiching the peripheral edge of the glass plate, and a metal frame made of metal.
It is provided with a frame holder that covers and holds the metal frame and should be attached to the building frame.
The metal frame is cold bent using the metal frame, which is arranged at intervals along the longitudinal direction and has notches formed in a direction intersecting the longitudinal direction. Glass unit. Claim 1 is characterized in that the cut portion is formed in all directions in the circumferential direction so as to divide the metal frame, and the metal frame is formed by arranging a plurality of frame segments in the longitudinal direction. Cold bend glass unit using the metal frame described in. The cold bend glass unit using the metal frame according to claim 1 or 2, wherein the cut portion is formed having a predetermined thickness. The metal frame has an arc-shaped outer peripheral surface in cross-sectional view.
The frame holder has an inner peripheral surface along the arc shape of the outer peripheral surface of the metal frame.
The cold bend glass unit using the metal frame according to any one of claims 1 to 3, wherein the metal frame can be rotated in the frame holder.

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