JP7245406B1 - Seismic unit hinge - Google Patents

Abstract

[Problem] At present, when the possibility of a Nankai Trough earthquake is increasing, there is concern that people will be trapped indoors and will not be able to escape from their homes. To provide an anti-earthquake unit hinge for preventing delay in escaping from a house when an earthquake occurs. A first anti-seismic hinge (10) and a second pipe (16) are slidable in the first pipe by means of a first pipe (16) and a first shaft (15). and a second shaft (25) to provide an anti-seismic unit hinge (30) comprising both a second anti-seismic hinge (20) which is movable within said second pipe portion and installed in the door. Therefore, it is possible to provide a structure that can maintain the original function of the door without being interfered with by the movement of the surrounding structure (3), making it possible to escape to a safe place. [Selection drawing] Fig. 1

Description

To provide an earthquake-resistant unit hinge having a mechanism for opening a door even when a structure around a building is distorted by an earthquake.

A conventional door fixed to a building's surrounding structure deforms in whole or in part due to deformation of the surrounding structure due to an earthquake, which hinders the door's opening/closing function and impairs the original opening/closing function of the door. Countermeasures against this deformation include: (a) doors that consist of earthquake-resistant hinges and latch receivers, (b) metal fittings with rollers attached to the ends of the doors to reduce interference resistance due to deformation, and (c) surrounding structures. There is known one that has a function to prevent deformation from interfering with the door frame and the door. Patent document 1 is (c), and it is known that the opening and closing function is achieved by the clearance between the peripheral structure and the door frame and the self-supporting mechanism.

In Non-Patent Document 1, the inter-story displacement angle after the occurrence of an earthquake is 1/60 or less as A rank, more than 1/60 and 1/20 or less as B rank, and more than 1/20 as C rank. There is no fear of collapse.
In the case of B rank, since it is 1/60 to 1/20, the horizontal movement deformation is
If the door height is 2000 mm, 1/60 is 33 mm (2000 x 1/60 = 33), 1/20 is 100 mm (2000 x 1/20 = 100), and the horizontal displacement is from 33 mm to 100 mm. It is reported that the collapse of the building can be avoided if the movement deformation is up to 100 mm.
Story drift angle is defined as the ratio of lateral slip to the height of the ground floor of a building expressed in radians.

Patent application 2016-098284

Emergency Risk Judgment Manual for Damaged Buildings published by the Japan Building Disaster Prevention Association

In the conventional technology, there is no structure that functions to deform (change) all the front, rear, left, and right inter-story displacement angles due to the inter-story displacement angle deformation (movement) of 1/20 of the B rank in Non-Patent Document 1 after the occurrence of an earthquake.

The present invention functions on all front, rear, left, and right inter-story displacements of B rank 1/20 in Non-Patent Document 1, until the building collapses, such as movement due to external forces during earthquakes, normal use, and intentional external forces. The door opens without being interfered with by the deformation of
It provides a hinge with a mechanism.

Now that the possibility of a Nankai Trough earthquake is increasing, there are fears that people will be trapped indoors and will not be able to escape from their homes. To provide an anti-earthquake unit hinge for preventing delay in escaping from a house when an earthquake occurs.
In addition, we provide anti-earthquake unit hinges not only for installing new doors in newly built or renovated homes, but also for installing existing door hinges as an anti-earthquake so that they will spread to existing houses. To provide an escape unit door for preventing delay in escaping from a house when an earthquake occurs only by changing to a unit hinge, and to prepare for the occurrence of an earthquake relatively easily at a low cost.

Even in a small earthquake, if the surrounding structure is deformed and the door becomes difficult to open, we have installed an anti-earthquake unit hinge that adjusts the positional relationship between the surrounding structure and the door with hinges so that the door can be opened and closed smoothly. The task is to provide

As a means for solving the above problems, in claim 1, a first upper wing (11) attached to the upper part of the door (1) and the upper part of the frame body (2) are attached to the first upper wing a first anti-seismic hinge (10) comprising a first lower wing (12) engaging with (11);
A second upper wing (21) attached to the lower part of the door (1) and a second lower wing (22) attached to the lower part of the frame (2) and engaged with the second upper wing (21) A second anti-earthquake hinge (20) consisting of
an anti-seismic unit hinge (30) comprising
The first upper blade (11) includes a first upper blade plate (13) and a first shaft (15) integrated with the first upper blade plate (13),
The first lower blade (12) includes a first lower blade plate (14) and a first tube portion (16) integrated with the first lower blade plate (14),
By inserting the lower side of the first shaft (15) into the first tube portion (16), the first upper blade (11) is rotatably engaged with the first lower blade (12). has been
The second upper blade (21) comprises a second upper blade plate (23) and a second shaft (25) integrated with the second upper blade plate (23),
The second lower blade (22) includes a second lower blade plate (24) and a second tube portion (26) integrated with the second lower blade plate (24),
By inserting the lower side of the second shaft (25) into the second pipe portion (26), the second upper blade (21) is rotatably engaged with the second lower blade (22). The shape of the first tube (16) is such that the first shaft (15) can slide in the first tube (16),
The shape of the second pipe portion (26) is such that the second shaft (25) can move within the second pipe portion (26). )I will provide a.

As means for solving the above problems, in claim 2, the first shaft (15) includes a first columnar portion (151) integrated with the first upper blade plate (13) and the first columnar portion (151). a first shaft (152) extending from the bottom surface of (151);
A pipe is provided at a position that covers the periphery of the lower part of the first cylindrical part (151), and the pipe is composed of a notch part (153) that cuts the lower part and a pipe part (154),
The first tube portion (16) has a substantially U-shape in plan view, and a rectangular protruding plate (163) projecting upward from the first tube portion (16) is attached to the first lower blade plate (14). ready on the side,
When the door (1) is closed, the protruding plate (163) is positioned and engaged with the notch (153) of the pipe, and when the door (1) is open, the protruding plate (163) is located in and engaged with the pipe section (154);
There is provided an anti-seismic unit hinge (30) according to claim 1, characterized in that:

As a means for solving the above-mentioned problems, in claim 3, the first pipe portion (16) has a generally U-shaped shape in plan view, and the first pipe portion (16) in the normal time An anti-seismic unit hinge (30) according to claim 1, characterized in that it comprises a locking part for stopping the sliding of the single shaft (15).

As a means for solving the above problems, in claim 4, the first pipe portion (16) has a structure in which the tip of the substantially U-shaped shape in plan view is bent inward. An anti-seismic unit hinge (30) according to either claim 2 or claim 3 is provided.

As means for solving the above problems, in claim 5, the second shaft (25) includes a second columnar portion (251) integrated with the second upper blade plate (23) and the second columnar portion (251). A second shaft (252) extending from the bottom surface of (251) is provided, and the second shaft (252) has a pencil-shaped truncated conical portion (259) at its tip. ) has a cylindrical shape such that the opening diameter widens from the bottom surface toward the top opening, and the bottom surface of the second pipe portion (26) is provided with a second groove portion (261). 5. The anti-earthquake structure according to claim 4, characterized in that said frusto-conical portion (259) fits into said second groove portion (261) in a state in which (21) is engaged with said second lower blade (22). Provide the unit hinge (30).

As means for solving the above problems, in claim 6, the first shaft (15) includes a first cylindrical portion (155) integrated with the first upper blade plate (13) and the first cylindrical portion (155). (155) and a first eccentric shaft (156) that is rotatably held in the first cylindrical portion (155). A first columnar portion (157) fitted to the cylindrical portion (155), and a position extending from the bottom surface of the first columnar portion (157) and eccentric to the bottom surface of the first columnar portion. and a first eccentric shaft (158) located in the .
The second shaft (25) is fitted with a second cylindrical portion (253) integrated with the second upper blade plate (23) and the second cylindrical portion (253) to form a second cylindrical portion (253). 253), the second eccentric shaft (254) is rotatably held within the second cylindrical portion (253). (255) and a second eccentric shaft (256) extending from the bottom surface of the second cylindrical portion (255) and arranged at a position eccentric to the bottom surface of the cylindrical portion (255). An anti-seismic unit hinge (30) according to claim 5, characterized in that it comprises:

Provide a structure that can maintain the original function of the door without interference with the movement of the surrounding structure (3) by the door (1) using the anti-seismic unit hinge (30) of the present invention. It is possible to escape to a safe place.

In addition, it is possible to provide a door that has the function of escaping from a house by simply changing the hinge of the existing door to an anti-seismic unit hinge (30) in addition to installing it in a newly built house or a renovated house. It becomes possible. In addition, this reduces the burden of costs and makes it possible to prepare for earthquakes relatively easily.

Provide a structure that can maintain the original function of the door without interference with the movement of the surrounding structure (3) by the door (1) using the anti-seismic unit hinge (30) of the present invention. Even if the positions of the door (1) and the frame body (2) are misaligned due to an earthquake, the door can be opened and closed in the same way as before the earthquake by adjusting the hinge with the eccentric shaft. repair becomes possible.

Perspective view showing an example of an escape unit door Perspective view of the first anti-seismic hinge showing an example of the first upper blade and the first lower blade The perspective view which shows an example of the latching|locking part of a 1st pipe part. Perspective view before and after movement of the first and second anti-seismic hinges Perspective view of the first anti-seismic hinge showing an example of the first upper blade and the first lower blade The perspective view which shows an example of a 2nd shaft and a 2nd pipe part. The perspective view which shows an example of the 1st shaft provided with the eccentric shaft. Perspective view of the escape unit door when the surrounding structure is tilted in the direction of A Escape unit door perspective view when the surrounding structure is tilted in the direction of B Perspective view of the escape unit door when the surrounding structure is tilted in the direction of C Perspective view of the escape unit door when the surrounding structure is tilted in the direction of D

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiments shown below are examples of configurations for embodying the technical idea of the present invention, and the present invention is not limited to the following.
FIG. 1 shows a configuration diagram in which an anti-seismic unit hinge (30) according to an embodiment of the present invention is attached to a door (1) or a frame (2) of a peripheral structure (3).
A first upper slat (13) is attached to the upper side of the door (1) with screws, and a first lower slat (14) is attached to the upper part of the frame (2) with screws. Further, by inserting the first shaft (15) integrated with the first upper blade plate (13) into the first tube portion (16), the first upper blade (11) can move to the first Attached to the lower blade (12), the engagement between the door (1) or frame body (2) and the first anti-seismic hinge (10) is completed.
Further, a second upper blade plate (23) is attached to the lower side surface of the door (1) with screws, and a second lower blade plate (24) is attached to the lower portion of the frame body (2) with screws. Further, the lower side of the second shaft (25) integrated with the second upper blade plate (23) is inserted into the second pipe portion (26) integrated with the second lower blade plate (24). By inserting it, it is attached to the second upper blade (21) and the second lower blade (22), and the door (1), the frame body (2) and the second anti-seismic hinge (20) Engagement is complete.
An anti-seismic unit hinge (30) that combines the first anti-seismic hinge (10) and the second anti-seismic hinge (20) is attached to the door (1), and the first shaft (15) and the second shaft The body (25) has a mechanism for rotating the door (1).
An escape unit door (31) is a structure in which the anti-seismic unit hinge (30) is attached to the door (1), and is attached to the frame (2) fixed to the surrounding structure (3).

A first shaft (15) constituting a first anti-seismic hinge (10) according to one embodiment of the present invention
and the first tube portion (16) are taken as an example and explained with reference to FIG.
A pipe (20 mmφ) with a notch (153) was welded to a position covering the lower part of the first cylindrical part (151) of the first shaft (15). The first pipe portion (16) has a substantially U-shaped shape in plan view, and a rectangular protruding plate (163) is provided inside the first pipe portion (16) on the side of the first lower blade plate. was installed so as to protrude above the first pipe portion (16). The protruding height of the ejector plate (163) is set so that it overlaps the notch (153) of the pipe by 3 mm, and the width of the notch (153) of the pipe is 10mm, which is longer than the width of the ejector plate (163) of 5mm. bottom.
When the first shaft (15) and the first pipe (16) are attached, the tip of the protruding plate (163) is inserted into the pipe (154) to allow the first pipe to move. Along with the rotation of (16), it moves on the inner surface along the pipe portion (154).
When the door (1) is closed, the notch (153) of the pipe and the protruding plate (163) are set to overlap and engage, and when the door is open, the pipe (154) and the protruding plate (163) are engaged. The protruding plate (163) is set and engaged in an overlapping position.
As a result of the above,
When the door (1) is open, the protruding plate (163) attached inside the first pipe (16) is held down by the pipe (154) attached to the first shaft (15), thereby The first shaft (152) of the one-axis body (15) has a structure that prevents sliding in the first tube portion and prevents the door (1) from coming off.
Also, when the door (1) is closed, the tip of the projecting plate (163) overlaps the notch (153) of the pipe by 3 mm, so the engaged state is maintained, but an earthquake occurs. However, when the first lower blade (12) moves, the protruding plate (163) is disengaged from the notch (153) of the pipe, which is the engaging portion, so that the first shaft (15) is moved. One shaft (152) slides in the first tube (16) and the first shaft (15) stays in its original position. Since the first upper slat (13) included in the first shaft (15) is attached to the door (1), the door (1) does not move and the door (1) can be easily opened. be able to.

An example of the engaging portion of the first pipe portion (16) constituting the first anti-seismic hinge (10) according to one embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 3(a) or FIG. 3(b), the first pipe portion (16) has a generally U-shaped shape in plan view, and is locked inside the first pipe portion (16). A protrusion (165) or a curved portion (166) is provided as a portion, and normally supports the first shaft (15), but the first lower blade (1) attached to the frame (2) 12) moves, the first shaft (15) climbs over the protruding portion (165) and the curved portion (166) so that the first pipe portion (16) slides.
As another method, as shown in FIG. 3(c), by providing a first groove (167) as a locking portion in the bottom of the first tube (16), the first shaft (15) is normally engaged. ) is fitted in the first groove to support the first shaft (15), but if the first lower blade (12) attached to the frame (2) moves, the bottom The first pipe portion (16) slides as the first shaft (15) rides over the first groove portion (167).

The first seismic hinge (10) of the seismic unit hinge (30) according to one embodiment of the present invention and
The behavior when the surrounding structure (3) and the frame (2) move due to an earthquake or the like with the second earthquake-resistant hinge (20) attached will be described with reference to FIG.
If the frame (2) of the surrounding structure (3) moves due to an earthquake, etc., the first pipe (16) attached to the frame (2) and the first shaft attached to the door (1) In the relationship (15), the first shaft (15) moves beyond the locking portion in the first pipe portion (16), thereby moving the first pipe portion (16). As a result, the first shaft (15) attached to the door (1) does not move and can maintain its original position.
At the same time, the lower side of the frame (2) also moves, and the relationship between the second pipe (26) attached to the frame (2) and the second shaft (25) attached to the door (1) The second pipe portion (26) moves due to the cylindrical shape in which the opening diameter widens from the bottom surface of the second pipe portion (26) toward the top opening.
FIG. 4(a) shows the state before movement, and FIG. 4(b) shows the state after movement.
As a result, since the door (1) attached to the first shaft (15) and the second shaft (25) does not move, the door can be opened.

An example of the first shaft body (15) and the first pipe portion (16) constituting the first anti-seismic hinge (10) according to one embodiment of the present invention will be described with reference to FIG.
The first shaft (15) slides in the first tube (16) by providing the tip (164) formed by bending the U-shaped tip of the first tube (16) inward. However, the first shaft (15) stays in the first tube (16), and the first shaft (15) and the first tube (16) are not completely separated. and As a result, even if the first pipe portion (16) slides, the frame portion (2) and the door (1) are kept in a state in which the door (1) and the frame portion (2) are completely separated. It is possible to prevent damage accidents caused by

An example of the second shaft body (25) and the second pipe portion (26) constituting the second anti-seismic hinge (20) according to one embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 6(a), in the second shaft (25), the second shaft portion (252) extending from the bottom surface of the second columnar portion (251) has a truncated cone shape with a pencil-like tip. truncated cone (259). On the other hand, the second pipe part (26) has a cylindrical shape such that the opening diameter widens from the bottom surface toward the top opening. It has a structure that takes shape. Alternatively, as shown in FIG. 6(b), the shape of the bottom surface may be square, and the opening may be a rectangle that expands toward the top surface.
Further, as shown in FIG. 6(c), the bottom surface of the second pipe portion has a second groove portion (261), and when the second upper blade is engaged with the second lower blade, the second shaft The truncated cone part (259) at the tip of the second shaft (252) of the body (25) fits into the second groove part (261) on the bottom surface of the second pipe part (26) to form the rotation axis of the door (1). becomes.
In the event of an earthquake, the second shaft (252) of the second shaft (25) moves along with the sliding of the first shaft (15) on the first pipe (16). It is structured so that it moves inside the part (26) and the rotating shaft of the door moves.

After an earthquake occurs, even if the shaking is slight, the door (1) may come into contact with the frame (2) and the door (1) may not open or close easily.
In such a case, using the anti-seismic unit hinge (30) with the first eccentric shaft (156), the position of the frame (2) and the door (1) is adjusted by the eccentric shaft (158). By adjusting, the contact between the frame body (2) and the door (1) can be released, and the door (1) can be opened and closed smoothly. A specific structure and adjustment will be described below with reference to FIG.
The first shaft (15) is fitted in the first cylindrical portion (155) integrated with the first upper blade plate (13) and can freely rotate inside the first cylindrical portion (155). It has a double structure with an eccentric shaft (156). Furthermore, the first eccentric shaft (156) is located eccentrically with respect to the cylindrical portion (157) which can freely rotate inside the first cylindrical portion (155) and the bottom surface of the cylindrical portion (157). A first eccentric shaft (158) is provided.
FIG. 7(a) shows the first eccentric shaft (156) fitted inside the first cylindrical portion (155). It shows a situation where the core shaft (158) is eccentric.
FIG. 7(b) is a diagram of the first eccentric shaft (156) separated from the first cylindrical portion (155). A first cross-shaped groove (17) is formed in the head of the first eccentric shaft (156), and a first set bolt (159) is formed in the central portion of the outer surface of the first cylindrical portion (155). is attached, and the tip of the first set bolt (159) reaches the first fixing groove (168) installed on the surface of the first cylindrical part (157) and is fixed. .
When the door (1) does not open and close due to contact between the frame (2) and the door (1), first, the first set bolt (159) on the first cylindrical part (155) is ). To move the first eccentric shaft (156), insert a screwdriver into the first cross-shaped groove (17) on the head and rotate the first eccentric shaft (156) to move the first eccentric shaft. (158) can move back and forth and left and right to adjust the vertical and horizontal positions of the first shaft (15) and the first tube (16).
After adjusting the position, the first set bolt (159) on the first cylindrical portion (155) is tightened to fix it.
The second cylindrical portion (251) is similar to the first cylindrical portion (151),
It has a double structure of a second eccentric shaft (254) that fits into the second cylindrical portion (253) and can freely rotate inside the second cylindrical portion (253). Furthermore, the second eccentric shaft (254) is eccentric with respect to the bottom surface of the second cylindrical portion (255) and the second cylindrical portion (255) that can freely rotate inside the second cylindrical portion (253). It has a second eccentric shaft (256) that is in the closed position.
A second cross-shaped groove (27) is formed in the head of the second eccentric shaft (254), and a second set bolt ( 257) is attached, and the tip of the second set bolt (257) reaches the second fixing groove (258) provided on the surface of the second cylindrical portion (255) and is fixed. ing.
Since the second columnar portion (251) has the same structure as the first columnar portion (151), illustration of the second columnar portion (251) is omitted.
By adjusting the position of the frame (2) and the door (1) using both the first anti-seismic hinge (10) and the second anti-seismic hinge (20) with an eccentric mechanism. , the door (1) can be opened and closed smoothly.

The behavior of the escape unit door (31) when an earthquake occurs and the surrounding structure (3) moves will be described below.
As shown in Figures 8, 9, 10 and 11, the escape unit door (31) is assumed as follows when the surrounding structure (3) moves in four directions.
Assuming that the escape unit door (31) is located outside the surrounding structure (3), the relationship between the escape unit door (31) and the surrounding structure (3) is as follows: The tilted directions are assumed as A, B, C, and D below.
In this case, when the escape unit door (31) is viewed from the outside, it is assumed that the hinge (30) of the anti-seismic unit on the right side of the door (1) opens to the outside of the room.

A. When tilted to the indoor side B. When deformed to the right when viewed from the outside C. When deformed to the left when viewed from the outside D. When tilted to the outdoor side

In the case of A, the escape unit door (31) moves to the indoor side together with the surrounding structure (3) as shown in FIG. The escape unit door (31) moves to the indoor side, but there is nothing that interferes with the escape unit door (31), so the escape unit door (31) can be opened as usual, and escape from the room (indoor). can do.

In the case of B, the escape unit door (31) moves to the right along with the surrounding structure (3) as shown in FIG. Since the surrounding structure (3) and the floor (4) do not interfere with each other, the escape unit door (31) can be opened normally, and the room (interior) can be escaped.

In the case of C, when the surrounding structure (3) moves to the left as shown in FIG. 10, as shown in FIG. and the second pipe part (26) move together with the frame part (2), but the first shaft body (15) and the second shaft body (25) do not move, and the escape unit door (31) , can be kept horizontal, can be opened normally, and can escape from the room (interior).

In the case of D, the escape unit door (31) moves to the outdoor side together with the surrounding structure (3) as shown in FIG. The escape unit door (31) moves to the outdoor side, but nothing interferes with the door (1) when it is closed. When the door (1) is opened, the bottom left side of the door (1) interferes with the floor (4) and a force is applied to move the door (1) to the right. As shown in FIG. 4, the first shaft (15) and the second shaft (25) of the hinge described in (0023) move inside the first pipe (16) and the second pipe (26). By sliding and moving, the door (1) moves to the right, making it possible to open the door (1). As a result, it is possible to escape from the room (inside the room).

When the door is large or the door is heavy, it is assumed that the hinges are installed in three places because the hinges in two places are not durable. In this case, the structure should have the first anti-seismic hinge (10) in the upper part, the first anti-seismic hinge (10) in the central part, and the second anti-seismic hinge (20) in the lower part. In addition, grooves (167, 167, 261), the same function as when two hinges are installed can be obtained, and even if an earthquake occurs, the escape unit door (31) can be opened normally, and the room ( You can escape from the room).
Furthermore, even when hinges are installed in four or more places, the structure will have the second anti-earthquake hinge installed in the lower part in the same way as when the hinges are installed in three places, and the other hinges will be the first anti-earthquake hinge. By using hinges, it is possible to obtain the same function as when two hinges are installed.

1 door 2 frame body 3 peripheral structure 4 floor 10 first anti-seismic hinge 11 first upper blade 12 first lower blade 13 first upper blade plate 14 first lower blade plate 15 first shaft 151 second 1 cylindrical portion 152 first shaft 153 notch portion 154 pipe portion 155 first cylindrical portion 156 first eccentric shaft 157 first cylindrical portion 158 first eccentric shaft 159 first set bolt 16 first pipe portion 163 projecting plate 164 Tip 165 Projection 166 Curved portion 167 First groove 168 First fixed groove 17 First cross-shaped groove
20 Second anti-seismic hinge 21 Second upper blade 22 Second lower blade 23 Second upper blade plate 24 Second lower blade plate 25 Second shaft 251 Second cylindrical portion 252 Second shaft portion 253 Second cylinder Part 254 Second eccentric shaft 255 Second cylindrical portion 256 Second eccentric shaft 257 Second set bolt 258 Second fixed groove 259 Second truncated cone portion 26 Second pipe portion 261 Second groove portion 27 Second cross-shaped portion Groove 30 Anti-earthquake unit hinge 31 Escape unit door

Claims (6)

a first anti-seismic hinge composed of a first upper wing attached to the upper part of the door and a first lower wing attached to the upper part of the frame and engaged with the first upper wing;
a second anti-seismic hinge composed of a second upper wing attached to the lower portion of the door and a second lower wing attached to the lower portion of the frame and engaged with the second upper wing;
An anti-seismic unit hinge comprising
The first upper blade includes a first upper blade plate and a first shaft integrated with the first upper blade plate,
The first lower blade includes a first lower blade plate and a first tube portion integrated with the first lower blade plate,
The first upper blade is rotatably engaged with the first lower blade by inserting the lower side of the first shaft into the first tube,
The second upper blade comprises a second upper blade plate and a second shaft integrated with the second upper blade plate,
The second lower blade includes a second lower blade plate and a second tube portion integrated with the second lower blade plate,
The second upper blade is rotatably engaged with the second lower blade by inserting the lower side of the second shaft into the second tube,
The shape of the first tube is such that the first shaft can slide in the first tube,
The earthquake-resistant unit hinge, wherein the shape of the second pipe portion is such that the second shaft body is movable within the second pipe portion.
The first shaft includes a first cylindrical portion integrated with the first upper blade plate and a first shaft extending from the bottom surface of the first cylindrical portion,
A pipe is provided at a position covering the periphery of the lower part of the first cylindrical part, and the pipe is composed of a notch part that cuts the lower part and a pipe part,
The first tube portion has a substantially U-shaped shape in plan view, and has a rectangular protruding plate protruding upward from the first tube portion on the side of the first lower blade plate,
When the door is closed, the projecting plate is positioned and engaged with the cutout portion of the pipe, and when the door is open, the projecting plate is positioned and engaged with the pipe portion of the pipe. are in agreement,
The anti-seismic unit hinge according to claim 1, characterized in that:
2. The first pipe portion has a generally U-shaped shape in a plan view, and is provided with an engaging portion that normally stops the sliding of the first shaft within the first pipe portion. The anti-earthquake unit hinge shown.

4. The anti-seismic unit according to claim 2 or 3, wherein the first pipe portion has a substantially U-shaped tip in a plan view and has a structure in which the tip is bent inward. turn.
The second shaft includes a second cylindrical portion integrated with the second upper blade plate and a second shaft extending from the bottom surface of the second cylindrical portion,
The second shaft has a truncated conical portion sharpened like a pencil at its tip,
The second pipe portion has a cylindrical shape such that the opening diameter widens from the bottom surface toward the top opening,
A bottom surface of the second tube portion is provided with a second groove portion, and in a state in which the second upper blade is engaged with the second lower blade,
the frusto-conical portion mates with the second groove;
The anti-earthquake unit hinge according to claim 4, characterized in that:

The first shaft body is composed of a first cylindrical portion integrated with the first upper blade plate and a first eccentric shaft fitted in the first cylindrical portion and held rotatably in the first cylindrical portion. ,
The first eccentric shaft extends from a first cylindrical portion fitted to the first cylindrical portion and from the bottom surface of the first cylindrical portion, and is eccentric with respect to the bottom surface of the first cylindrical portion. and a first eccentric shaft arranged at a position where the
The second shaft body is composed of a second cylindrical portion integrated with the second upper blade plate and a second eccentric shaft fitted in the second cylindrical portion and held rotatably in the second cylindrical portion. ,
The second eccentric shaft extends from a second cylindrical portion fitted to the second cylindrical portion and from the bottom surface of the second cylindrical portion, and is eccentric with respect to the bottom surface of the second cylindrical portion. and a second eccentric shaft arranged at a position where
The anti-earthquake unit hinge according to claim 5, characterized in that:

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