JPH0913831A - Earthquake resistant door - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an earthquake resistant door that can be deformed according to the destructed and deformed state of a door opening frame so as to be opened/closed in that state when the door opening frame being torsionally deformed by shock at the time of an earthquake being generated. SOLUTION: An earthquake resistant door consists of a door internal frame member A formed of upper and lower frames 1, 2 and both longitudinal frames, and surface material B with a bent piece 7 formed around a panel part 6. Both faces of the door internal frame member A are covered with the surface material, and shock absorbing parts 5 are provided in the appropriate places of at least either one pair between the upper and lower frames and both longitudinal frames 3, 4. A cutout 8 is formed at the bent piece in the place corresponding to the shock absorbing part 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention, when an earthquake occurs, when the door opening frame is distorted and deformed, the door opening frame can be deformed in accordance with the breaking deformation state of the door opening frame. A seismic resistant door that can be opened and closed.

[0002]

In the above-mentioned conventional type, when the door opening frame is deformed by the horizontal load at the time of an earthquake and the width of the door opening frame is reduced, or more than the above assumptions are made. It cannot be opened or closed when it is deformed (the body itself collapses). Further, as described above, most of the seismic resistant door devices are provided with earthquake countermeasures for the door opening frame, and almost none of the doors themselves are provided with earthquake countermeasures. To construct the door opening frame, there is a drawback that the construction is troublesome and the construction cost is expensive in a new construction or a used construction. There is a demand for inexpensive door construction that can easily take measures against earthquakes even in new or used buildings.

[0003]

Therefore, as a result of intensive studies, the inventor of the present invention has found that the present invention can be applied to a door interior frame member composed of upper and lower frames and both vertical frames and a panel portion. It consists of a surface material with bent pieces formed around it, and both sides of the door interior frame material are covered with the surface material, and shock absorption is carried out at an appropriate location of at least one of the upper and lower frames or both vertical frames. Part,
By forming a notch in the bent piece at the location corresponding to the shock absorbing part, at the time of an earthquake,
When the door opening frame is distorted and deformed due to impact, it can be deformed according to the breaking deformation state of the door opening frame, and it can be opened and closed in that state. It is possible to provide a thing that can be installed easily for earthquake resistance immediately, achieve the above-mentioned object, and solve the drawbacks and the like.

[0004]

2. Description of the Related Art Conventionally, various types of seismic resistant door devices have been developed. That is, there is a structure in which the upper frame of the door opening frame is movable and is deformed when a vertical load is applied so that the door can be opened and closed. Further, there are structures in which the flexible strike is deformed even if the clearance between the vertical frame and the door becomes small, or a structure in which the clearance between the skid and the door is appropriately secured.

[0005]

Embodiments of the present invention will be described below with reference to the drawings. First, the seismic resistant door of the first embodiment of the present invention is shown in FIGS. 1 to 7. In particular,
As shown in FIGS. 1 to 3, the earthquake-proof door is mainly composed of a door interior frame material A, a surface material B, and shock absorbing parts 5 and 5 composed of sliding type shock absorbing pieces 5a and 5a. The door interior frame material A is configured as the interior core member of the seismic resistant door of the present invention together with the shock absorbing portion 5, and the door interior frame material A is also included.
Is a structure that contracts in the door width direction through the sliding type shock absorbing pieces 5a, 5a. The structure that contracts in the horizontal direction, which is the width direction, has conventionally been compatible with the rolling of an earthquake. The door interior frame material A is made of a metal plate material having a U-shaped cross section. Inside the door interior frame material A, a core material E which is a core material having a honeycomb structure or the like is installed (see FIG. 1), but it is omitted in other drawings.

As shown in FIG. 4, the door interior frame material A is composed of an upper frame 1, a lower frame 2, a vertical frame 3 on the hanging side, and a vertical frame 4 on the door end side. In the embodiment, the upper frame 1, the lower frame 2, the vertical frame 3 on the hanging side, and the vertical frame 4 on the door end side are basically composed of the same material with the same cross section, but the present invention is not limited to this. Not done. The door interior frame material A is divided into two parts to the left and right from the approximate center in the width direction, and the hanging side (opening / closing center side of the door) is taken as the hanging side frame portion A ₁ , and the open / close free end side is the door end side frame portion A. _Set to ₂ .

The hanging side frame portion A ₁ and the door end side frame portion A ₂ are slidable shock absorbing pieces 5 at the upper and lower portions.
They are connected via a and 5a. That is, upper frame 1
Sliding type shock absorbing pieces 5a, which are the shock absorbing portions 5, are provided at appropriate positions of a pair of the lower frame 2 and the lower frame 2. The appropriate location is preferably the central location of each of the upper frame 1 and the lower frame 2, but is not limited to this and may be provided near the ends. In the structure in which the door interior frame material A is divided into two parts, the suspension side frame part A ₁ and the door end side frame part A ₂ , the upper frame 1 and the lower frame 2 are also respectively divided in the longitudinal direction. Specifically, the divided portion of the upper frame ₁ in the hanging source side frame portion A ₁ is called the hanging source side upper frame 1a, and the divided portion of the lower frame 2 is called the hanging source side lower frame 2a. Similarly, the divided portion of the upper frame 1 in the door-end side frame portion A ₂ is a door-end side upper frame 1b,
The divided portion of the lower frame 2 is referred to as a door end side lower frame 2b.

The hanging base side upper frame 1a and the door end side upper frame 1b are connected by a shock absorbing portion 5 which is a sliding type shock absorbing piece 5a, and similarly, the hanging base side lower frame 2a and the door end side lower frame. 2b and a shock absorbing portion 5 which is a sliding type shock absorbing piece 5a
And a door interior frame member A composed of a hanging side frame part A ₁ and a door end side frame part A ₂ . The sliding-type shock-absorbing strips 5a, as shown in FIGS. 2 to 4, etc., Tsumoto side on the frame 1 of Tsumoto side frame portion A ₁
a and the door-end-side upper frame 1b of the door-end-side frame portion A ₂ are provided so as to project toward the other side, and the other side slides with respect to the sliding-type impact absorbing piece 5a. It can be installed as much as possible. That is, one end of the sliding type shock absorbing piece 5a is fixed to one side of an appropriate portion of the upper frame 1 and the lower frame 2 by spot welding or the like,
The other ends are slidably provided on the other side of the appropriate portions of the upper frame 1 and the lower frame 2 so as to be slidable, and a clearance C is formed between the appropriate portions. Specifically, the clearance C is, as shown in FIG. 1 to FIG. 3, between the end of the suspension upper side frame 1a and the end of the door end side upper frame 1b, and the end of the suspension lower side frame 2a. It is between the door end side lower frame 2b end.

As shown in FIG. 4, the sliding type shock absorbing piece 5a includes a hanging base side upper frame 1a and a door end side upper frame 1b.
And the lower frame 2a on the hanging base side and the lower frame 2b on the door end side are formed by slightly reducing their cross-sections in a substantially similar shape,
It is formed in a substantially U-shaped cross section. Sliding type shock absorbing piece 5
a forms a pair with upper and lower two portions, the upper sliding type shock absorbing piece 5a is Tsumoto side upper frame 1a of Tsumoto side frame portion A ₁
Is fixed by spot welding or the like so that a part thereof protrudes from the end portion, and the other door-end-side upper frame 1b is slidable on the protruding portion of the shock absorbing portion 5 from the hanging-side upper frame 1a. It is installed. Similarly, the sliding-type shock absorbing piece 5a on the lower side corresponds to the lower frame 2 on the hanging side of the hanging side frame portion A _1.
The door end side lower frame 2b on the other side is fixed by welding means so that a part of the sliding type impact absorbing piece 5a protrudes from the hanging side lower frame 2a. It is slidably mounted on.

Therefore, in a normal state, the clearance C is secured as shown in FIG. 5, but when an impact due to an earthquake is applied, as shown in FIGS. 6 and 7,
The clearance C portion between the hanging side frame portion A ₁ and the door end side frame portion A ₂ contracts to become substantially zero, and both frame ends contact each other. Specifically, the clearance C portion between the suspension base side upper frame 1a and the door tip side top frame 1b contracts and becomes zero, and at the same time, the clearance C of the lower frame 2 also becomes zero, and the suspension base side upper frame 1a and the door top side. Both ends with the upper frame 1b, the lower frame 2a on the hanging side and the lower frame 2 on the door end side
Both ends with b are brought into contact with each other so that the widthwise dimension of the door interior frame material A is reduced as a whole.

In the embodiment, the sliding type shock absorbing piece 5a is fixed to the hanging side upper frame 1a and the hanging side lower frame 2a of the hanging side frame portion A ₁ , as shown in FIG.
The door-end side frame portion A with respect to the sliding type shock absorbing piece 5a
₂ of door end side on the frame 1b and the door leading side lower frame 2b is configured to slide, but on the contrary, door sliding-type shock absorbing piece 5a of the door end side frame section A ₂ It is fixed to the front side upper frame 1b and the door front side lower frame 2b, and the suspension source side upper frame 1a and the suspension source side lower frame 2a of the suspension source side frame portion A ₁ are opposed to the protruding portions of the sliding type shock absorbing piece 5a. The same effect is achieved as a sliding mechanism.

Next, in the first embodiment, the sliding type shock absorbing piece 5a as the shock absorbing portion 5 is attached to the suspension side frame portion A.
₁ or a separate member from the door-end side frame portion A ₂ , but as shown in FIGS. 8 (A) and 8 (B), the sliding-type impact absorbing piece 5 a is attached to the hanging-side frame portion A ₁ (or There is also an embodiment in which the door end side frame portion A ₂ ) is integrally formed by press working or the like. That is, the sliding-type shock absorbing piece 5a is press-molded so as to have a substantially similar cross-section to the suspension-source-side upper frame 1a of the suspension-source-side frame portion A ₁ and to be slightly smaller than the suspension-source-side upper frame 1a. The door-end side frame portion A ₂ can be freely inserted into the door-end side upper frame 1b [see FIG. 8 (B)]. Similarly, the sliding type shock absorbing piece 5a
Is also provided on the lower frame 2a on the hanging side of the hanging side frame A ₁ . In this way, the integral sliding-type shock absorbing piece 5
By setting it as a, the door interior frame material A can be configured more firmly.

Further, as a modification of the sliding type shock absorbing piece 5a, as shown in FIG. 9, it is turned upside down from the case of the first embodiment (see FIG. 4), and the upper door frame 1b and The open side of the door-end side lower frame 2b is directed upward, and the open side of the sliding type shock absorbing piece 5a is directed downward so that one end is fixed and the other end is slidable while securing the clearance C. It may be provided. In such a case, the sliding type shock absorbing piece 5a does not drop downward and can be slid for a long period of time.

Next, the surface material B is one in which bent pieces 7, 7, ... Are formed around the panel portion 6 and serves as a decorative outer plate of the door. The panel portion 6 serves as a surface plate on the outdoor side or the indoor side of the door, and as shown in FIG. 1 (A), various portions such as a door handle 10, a lock 11 and a post 12 are provided. The bent piece 7 supports the surface material B while surrounding the outer periphery of the door interior frame material A by the peripheral edge of the panel portion 6 when the surface material B is attached to the door interior frame material A.

The bending piece 7 includes a top bending piece 7a, a lower bending piece 7b, and both side bending pieces 7c, 7c. The top bending piece 7a abuts on the upper frame 1 of the door interior frame material A to make a lower bending. The piece 7b comes into contact with the lower frame 2, the both side bent pieces 7c and 7c come into contact with the vertical frames 3 and 4, and the surface material B covers the door interior frame material A.
Since the sliding type shock absorbing piece 5a is slightly shrunk from the cross section of the frame, that is, the upper frame 1, the lower frame 2, the vertical frames 3 and 4, the surface material B is changed to the door interior frame material A. Even if it is covered with and fixed with an adhesive, it is always in a slidable state. Further, the surface material B is provided on both sides of the door interior frame material A, and in reality, the surface material B exists on the outdoor side and the indoor side, and the surface shapes are different from each other.

The bent piece 7 of the surface material B is provided with notches 8 and 8 corresponding to the installation locations of the shock absorbing portions 5 and 5 of the door interior frame material A. Specifically, as shown in FIGS. 2 and 3, when the sliding type shock absorbing piece 5a is installed on the upper frame 1 of the door interior frame material A, the sliding type shock absorbing piece 5a The notch 8 is formed in the top bent piece 7a of the surface material B at a corresponding position. Similarly, when the sliding type shock absorbing piece 5a is installed on the lower frame 2, a notch 8 is formed in the lower bending piece 7b at the corresponding position.

Next, as a second embodiment of the present invention,
As shown in FIG. 10, the door is capable of contracting in the vertical direction, and the configuration in which the door contracts in the vertical direction corresponds to the vertical pitching of a recent earthquake. Therefore, the door interior frame material A is composed of the upper side frame portion A ₃ and the lower side frame portion A ₄ . Specifically, the upper side portion of the door interior frame material A in the vertical direction is the upper side frame portion A ₃ , and the lower side portion is the lower side frame portion A ₄ . In this embodiment, the upper frame 1 and the lower frame 2
Is used as it is, and the vertical frame 3 on the hanging side and the vertical frame 4 on the door end side are each vertically divided into two parts.

Specifically, the vertical frame 3 on the suspension base side serves as a vertical suspension frame 3a at the upper side frame part A ₃ , and a vertical lower frame 3b at the suspension base side at the lower side frame part A ₄ . Similarly vertical frame 4 of the door end side door leading side vertical upper frame 4a next to the upper side frame portion A _3, the door end side longitudinal lower frame 4b in the lower side frame portion A _4. The upper frame portion A ₃ and the lower frame portion A ₄ are connected to each other by the slidable impact absorbing piece 5a, which is the suspension-side vertically upper frame 3a and the suspension-side vertically lower frame 3b. Vertical top frame 4a and door end side vertical bottom frame 4b
And are connected by a sliding type shock absorbing piece 5a. In the case of this type that contracts in the vertical direction, the pivot pin 1
It is preferable to carry out construction at 3,13. The mounting structure of the sliding type shock absorbing piece 5a is the same as that of the first embodiment, and the description thereof will be omitted.

Further, as a third embodiment of the present invention, it is capable of contracting in both the width direction and the vertical direction. That is, the structure that contracts in the horizontal direction in the width direction and in the vertical direction in the vertical direction at the same time is for simultaneously responding to the conventional rolling motion and the vertical motion of the recent earthquake. In the third embodiment, as shown in FIG. 11, the contraction structure in the width direction is provided with sliding type shock absorbing pieces 5a, 5a on the upper frame 1 and the lower frame 2, and the contraction structure in the vertical direction is both vertical. Sliding type shock absorbing pieces 5a, 5 on the frames 3, 4
a is installed. Also in the third embodiment, the pivot pins 13 and 13 are suitable. Further, the mounting structure of the sliding type shock absorbing piece 5a is also similar to that of the first embodiment, and the description thereof will be omitted.

Next, another embodiment of the shock absorbing portion 5 is a bent type shock absorbing member 5b which is deformable when a shock load of a certain level or more is applied. As shown in FIG. 12 (A), the folding type shock absorbing member 5b is
The frame is formed by cutting off the side portion of the frame and bent into a substantially V-shape as an integrated type. When a certain load or more is applied, the opening angle of the V-shape decreases and the upper frame 1 contracts in the longitudinal direction. [See the solid line in FIG. 12 (B)]. In this configuration, the hanging-side frame portion A ₁ and the door-end side frame portion A ₂ are bent at the upper and lower portions, and the bending-type impact absorbing member 5
It is connected via b and 5b. That is, upper frame 1
A bent type shock absorbing member 5b serving as the shock absorbing portion 5 is provided at an appropriate position of the pair of the lower frame 2 and the lower frame 2. Similar to the attachment of the sliding type shock absorbing piece 5a described above, the appropriate location is preferably the central location, but is not limited to this and may be provided near the end.

The bent type shock absorbing member 5b is used as appropriate in place of the sliding type shock absorbing piece 5a. In some cases, the shock absorbing portion 5 is replaced with the sliding type shock absorbing piece 5a. Both the folding type shock absorbing member 5b may be used. That is, the sliding type shock absorbing piece 5a having a small clearance C is used in an area where rolling or pitching is small, and an area where rolling or pitching is large (for example, an active fault area or the like). In (), a bent type shock absorbing member 5b that can obtain a relatively large shrinkage may be used, or a mixed type may be used. Further, as a modification of the folding type shock absorbing member 5b, as shown in FIG. 15, a door interior frame material A is divided into two parts, a suspension source side frame portion A ₁ and a door end side frame portion A ₂ (see FIG. 4). Both), the two mounting pieces of the folding type shock absorbing member 5b in which the mounting pieces are provided at the respective middles of the upper frame 1 and the lower frame 2 in the longitudinal direction from the upper ends of the V-shaped piece as separate members. There is also a case where each of them is fixed. In this case, the same operation as the integrated type is performed, but the bending type shock absorbing member 5b which is a separate member can be manufactured at a relatively low cost.

Also in the case where the shock absorbing portion 5 which is the bent type shock absorbing member 5b is used, the first embodiment in which the sliding type shock absorbing piece 5a is used and which is contractible in the width direction (see FIG. 1), There is a second embodiment (see FIG. 10) that can be contracted in the vertical direction, and a third embodiment (see FIG. 11) that can be contracted in both the width direction and the vertical direction. The sliding type shock absorbing piece 5a is only replaced with the folding type shock absorbing member 5b, and the other constituent members are the same as those in the first to third embodiments, and the same reference numerals are given. Is omitted.

As described above, the seismic resistant door is installed in the door opening frame D. This is similar to a normal door. The opening width of the normal door opening frame D is W, and the opening width when the door opening frame D is destroyed and deformed by an impact load due to an earthquake is W ₁ . Also,
In the embodiment of the shock absorbing portion 5 described above, the sliding type shock absorbing piece 5a and the bending type shock absorbing member 5b have been described, but the contraction is limited to these as long as the contraction can be obtained in the length direction. Of course, other configurations are also included.

[0024]

The normal state in which no load is applied to the door opening frame D is shown in FIG. Next, when a horizontal impact load due to an earthquake is applied to the door opening frame D, and the door opening frame D is destroyed and deformed and contracted in the width direction, the door opening frame D impacts the earthquake resistant door in a substantially horizontal direction. Will be added. This state is shown in FIGS. 6 and 7. And the door opening frame D
Impact load (pressure) so that the earthquake-proof door shrinks in the width direction
Upon receiving, the surface materials B, B first shrink in the width direction. Then, the upper frame 1 and the lower frame 2 of the door interior frame material A are contracted together with the surface materials B, B via the shock absorbing parts 5, 5, and at the same time, pressure is applied to the notches 8, 8 of the surface materials B, B. It acts intensively and deforms intensively on the line connecting the notches 8 on the upper and lower sides of the seismic door. Thus, even if the door opening frame D is destroyed and deformed due to an earthquake, the earthquake-resistant door is deformed following the deformation of the door opening frame D. As a result, the door is in a contracted state, and unlike the state in which the door is sandwiched by the door opening frame D, it is necessary to apply a force to open the door to some extent, but the opening and closing of the seismic door can be ensured.

[0025]

According to the first aspect of the present invention, the door interior frame material A composed of the upper and lower frames 1 and 2 and the vertical frames 3 and 4 and the surface material B having the bent piece 7 formed around the panel portion 6 are provided. Both sides of the door interior frame material A are covered with the surface materials B and B, and shock absorption is performed at an appropriate position of at least one of the upper and lower frames 1 and 2 or both vertical frames 3 and 4. By providing the portion 5 and forming the notch 8 in the bent piece 7 at the portion corresponding to the shock absorbing portion 5, the door opening frame D which is deformed and destroyed by the impact of the earthquake is firstly provided. It can be opened / closed by being deformed according to the deformed state. Secondly, the size of the deformation can be increased by appropriately changing the length of the shock absorbing portion 5, etc. Yes, there is no change in appearance,
Compared to the case where the frame is deformed as in the conventional case, large deformation can be coped well, and thirdly, the structure can be simplified,
Since it can be provided at a relatively low price, and fourthly, the door of the present invention is deformed, the clearance between the door opening frame D and the earthquake-proof door of the present invention can be minimized as in the conventional case, and the present invention can be installed in a very orderly manner. There are advantages.

To explain this function and effect in detail, the seismic resistant door of the present invention can be readily installed as a seismic resistant structure for a newly built or used (currently used) building immediately.
Further, in order to construct the door opening frame, there is a drawback that the construction is troublesome and the construction cost is expensive in a new construction or a used building, but in the present invention, only the seismic resistant door is used and it is against earthquake resistance. Therefore, it is possible to easily take earthquake countermeasures even for new or used buildings, and it is possible to take inexpensive earthquake resistance measures.

According to the second aspect of the invention, in the first aspect, a clearance C is provided at an appropriate position of the frame, and the shock absorbing portion 5 is slightly reduced in a shape similar to that of the frame in sliding direction. Type shock absorbing piece 5a, one end of the sliding type shock absorbing piece 5a is provided at the frame end on one side of the clearance C, and the other end is loosely inserted at the frame end on the other side of the clearance C. By using the door, it can be deformed well in the event of an earthquake and can absorb the impact load. In particular, since the sliding type shock absorbing piece 5a is made smaller than the frame cross section, even if the surface material B is fixed to the frame with an adhesive, the sliding type shock absorbing piece 5a is fixed to the frame. Therefore, in the event of an emergency earthquake, the sliding action starts immediately and the shrinkage can be handled very well. Further, the sliding-type shock absorbing piece 5a has an advantage that it is simple in construction and can be made inexpensive.

Next, in the invention of claim 3, in claim 1, the impact absorbing portion 5 is a bendable impact absorbing member 5b which can be bent, and the bend impact absorbing member 5b is appropriately formed on the frame. Since it is an earthquake-proof door provided between the parts, it can be bent by an impact, and at the normal time, both ends of the bent type shock absorbing member 5b are fixed, and it can function as a normal member. It has an effect that it can be used as a frame.

[Brief description of the drawings]

FIG. 1A is a partially cutaway perspective view of a first embodiment of the present invention composed of a sliding type shock absorbing piece, and FIG. 1B is a cross-sectional view of a main part of FIG. 1A.

FIG. 2 is an exploded perspective view of an essential part of the first embodiment of the present invention configured by a sliding type shock absorbing piece.

FIG. 3 is a perspective view of an essential part of a first embodiment of the present invention configured by a sliding type shock absorbing piece.

FIG. 4 is an exploded perspective view of a door interior frame member according to the first embodiment of the present invention.

FIG. 5 is a perspective view showing a partial cross section of a first embodiment of the present invention constituted by a sliding type shock absorbing piece in a door opening frame in a normal state.

FIG. 6 is a perspective view showing a partial cross-section of a state in which the first embodiment of the present invention constituted by a sliding type shock absorbing piece is installed in a door opening frame and deformed during an earthquake.

FIG. 7 is a perspective view of an essential part in the state of FIG.

FIG. 8A is an exploded perspective view of essential parts of a modified example of the first embodiment of the present invention configured with a sliding type shock absorbing piece, and FIG. 8B is a book configured with a sliding type shock absorbing piece. Sectional drawing of the principal part of the modification of 1st Embodiment of invention.

FIG. 9 is an exploded perspective view of a main part of another modification of the first embodiment of the present invention configured by a sliding type shock absorbing piece.

FIG. 10 shows a second embodiment of the present invention constituted by a sliding type shock absorbing piece.
Schematic view of the embodiment seen from the front

FIG. 11 is a third aspect of the present invention constituted by a sliding type shock absorbing piece.
Schematic view of the embodiment seen from the front

FIG. 12 (A) is an exploded perspective view of an essential part of the first embodiment of the present invention composed of a bent type shock absorbing member, and FIG. 12 (B) is a door interior frame member of (A) deformed by an earthquake. Main part perspective view showing the state

FIG. 13 is a partially cut-away perspective view of a first embodiment of the present invention, which is configured by a folding-type shock absorbing member, installed inside a door opening frame in a normal state.

FIG. 14 is a partially cut-away perspective view of a state in which the first embodiment of the present invention constituted by a bent type shock absorbing member is installed in a door opening frame and is deformed during an earthquake.

FIG. 15 is a perspective view of a door interior frame member according to the first embodiment of the present invention in which a folding shock absorbing member is used as a separate member.

[Explanation of symbols]

 A ... Door interior frame material B ... Surface material C ... Clearance 1 ... Upper frame 2 ... Lower frame 3, 4 ... Vertical frame 5 ... Impact absorbing part 5a ... Sliding type impact absorbing piece 5b ... Bending type impact absorbing member 6 ... Panel part 7 ... Bending piece 8 ... Notch

Claims (3)

[Claims] 1. A door interior frame material composed of upper and lower frames and both vertical frames, and a surface material in which bent pieces are formed around a panel portion. Both surfaces of the door interior frame material are covered with the surface material. A shock absorbing portion is provided at an appropriate position of at least one pair of the upper and lower frames or both vertical frames, and a cutout is formed in a bending piece at a position corresponding to the shock absorbing portion. Earthquake resistant door. 2. The sliding shock absorbing piece according to claim 1, wherein a clearance is provided at an appropriate position of the frame, and the shock absorbing portion is a sliding type shock absorbing piece slightly reduced in a shape similar to the frame in cross section. A seismic resistant door, characterized in that one end of a mold impact absorbing piece is provided at a frame end on one side of the clearance place and the other end is loosely inserted at a frame end on the other side of the clearance place. 3. The shock absorbing portion according to claim 1,
An earthquake-proof door, which is a bendable shock absorbing member that can be bent, and is provided between appropriate portions of the frame.