KR102047190B1 - Explosion proof door - Google Patents

Abstract

The present invention relates to an explosion proof door which is installed at an entrance of a shelter such as a refuge such as a shelter or a bunker, and is provided with functions of external impact absorption for a strong hit, an explosion, or the like, protection, prevention of explosion, prevention of water, airtightness, and protection against bullets, or the like, and comprises: a frame formed to support an entrance formed in a wall of a structure; a door installed to be opened and closed on an internal side surface of the frame; a hinge unit interposed between the frame and the door for the door to rotate; and a locking unit installed in the frame and the door.

Description

Explosion proof door

The present invention relates to an explosion-proof door, more specifically, is installed in the entrance of the shelter, such as a shelter or bunker, and is provided with functions such as external shock absorption, protection, explosion-proof, waterproof, airtight, bulletproof, such as a strong blow, explosion, etc. To an explosion proof door.

Generally, in military units, ammunition stores for storing explosives such as ammunition, shells, missiles, etc. and to protect lives and prevent the destruction of critical facilities from explosions caused by accidents and collapse of facilities in petrochemical plants or various industrial production facilities. In order to prevent explosions, explosion-proof doors are used.

This is because the heavy weight that the average person cannot easily open or close is made of a special design, it is usually open, and in case of emergency, it is controlled.

According to the special emergency situation, the opening and closing device applied to the explosion-proof door is locked for external control, and the opening of the explosion-proof door is located by rotating the door on the wall side to reduce the volume occupied by the door on the passage after opening. The door is positioned and fixed to the guide groove recessed from the construction.

Such explosion-proof doors are disclosed in the Korean Registered Utility Model No. 20-0415402, the above-mentioned design has the advantage of opening and closing the explosion-proof door by electric, but when installed in defense-related facilities are hit by direct hits such as shells, missiles, etc. When an emergency occurs, the door is not opened due to breakage or deformation of the explosion-proof door, which makes it difficult to use for a special purpose.

The present invention has been made in order to solve the above problems, to ensure the airtightness of the explosion-proof door to prevent exposure, harmful gas and radioactive leakage of the NBC, and the explosion-proof door by the external impact when a fire in the shelter or bunker occurs It is a main object to provide an explosion-proof door that can be opened quickly even if breakage or deformation occurs.

Explosion-proof door according to the invention is a frame configured to support the doorway formed in the wall of the structure, the door is installed to open and close on the inner surface of the frame, and the door is interposed between the frame and the door so that the door is rotated And a hinge part and a locking part installed on the frame and the door.

On the other hand, it is installed adjacent to the doorway formed in the wall of the structure, the inner surface of the frame is formed with a rail, the door is coupled to move to the rail and the locking portion is installed on the frame and door; do.

In addition, the door is made of a steel plate material and is located between the outer surface of the plate-like outer shell facing a predetermined interval, and the I-shaped reinforcement is installed between the outer shell material to reinforce the rigidity of the door It is done.

In addition, it is characterized in that it comprises an aluminum foam which is provided on the inner surface of the outer cover material to absorb the external impact, and an insulator provided between the aluminum foam and the I-type reinforcement.

The door may further include a honeycomb-shaped reinforcing member installed on an outer circumferential surface of the I-shaped reinforcement body.

In addition, it is formed on the outer peripheral surface of the door, it is made of a thermosetting resin, characterized in that it further comprises a sealing portion that is hardened by the heat caused by the fire to fill the gap between the frame and the door to seal.

In addition, the inner peripheral surface of the frame is characterized in that as the sealing portion is cured by heat, the receiving groove for receiving the cured sealing portion is formed.

In addition, the sensing unit is installed on the door to detect a fire or shock, the drive unit is installed on the frame to open and close the door, the direction in which the entrance is closed as the fire or shock is detected by receiving a detection signal of the detection unit And a control unit for controlling the driving unit to drive the door.

In addition, the frame is provided with an identification unit for determining the presence of a person in the doorway, the control unit receives the signal of the identification unit when the person is present in the doorway, characterized in that for controlling the drive unit to stop the door. do.

The lock part may include a metal block installed at one side of the door, an electromagnet block installed at a position corresponding to the metal block on one side of the frame and fastened by a magnetic block, and installed in the electromagnet block. It characterized in that it comprises a control module for operating the electromagnet block by detecting the proximity of the block.

In addition, the locking unit is installed adjacent to the electromagnet block, characterized in that it further comprises a magnetic force blocking member for releasing the fixed metal block and the electromagnet block by blocking the power applied to the electromagnet block.

In addition, the metal block is installed in the first insertion groove formed in the outer surface of the door, the same height as the height of the outer surface of the door, the electromagnet block is installed in the second insertion groove formed in the inner peripheral surface of the frame. The height is the same as the height of the inner peripheral surface of the frame.

The present invention comprises a frame for supporting the door of the wall, the door coupled to the frame through the hinge portion and the frame and the locking portion is installed on the door, respectively, can be opened and closed by pushing or pulling the door in and out through the hinge, the frame and the door Provides the effect of maintaining the fastened state without being opened by an explosion or external impact through a lock installed in.

The explosion-proof door according to the present invention is composed of an outer shell material, an aluminum foam, an insulator, and an I-type reinforcement structure of the door formed of the most fragile structure among safety facilities, the impact on the outer shell aluminum foam Absorption in the secondary foam, the I-type reinforcement installed inside the aluminum foam can be absorbed in the third and minimize the deformation of the entire door, and the insulation generated on both sides of the I-type reinforcement caused by the explosion or flame It provides the effect of double blocking heat.

In addition, a honeycomb-shaped reinforcing member is further included in a space formed inside the skeleton forming the skeleton of the I-shaped reinforcement to absorb the impact applied to the I-shaped reinforcement to maintain the shape of the I-shaped reinforcement, By filling sand inside the honeycomb space, it provides the effect of further improving shock absorption.

In addition, an electromagnetic block is installed on one side of the frame at a position where the door can seal the entrance and exit, a metal block fixed by the magnetic force of the electromagnetic block is installed on the door, and the metal block approaches the electromagnetic block by the movement of the door. Through a control module for detecting the door, the invention of claim 1 prevents the door from being rotated to the outside or inside of the structure when the door is closed, the invention of claim 2 stops the door on the rail in the position of the best sealing force It provides an effect that can close the doorway.

In addition, the door that is in close contact with the frame by the electromagnet block and the metal block can block the magnetic force applied from the electromagnet block in case of emergency through the magnetic force blocking member to release the fastening of the electromagnet block and the metal block so that the user can open the door arbitrarily. Provide the effect.

In addition, the electromagnet block is formed at the same height as the height of the inner peripheral surface of the frame, the metal block is formed at the same height as the height of the outer surface of the door, so that the movement of the door on the frame is not interfered, and there is a gap between the inner surface of the frame and the outer surface of the door It does not provide the effect to maintain the sealing force.

In addition, the sealing portion is formed on the outer circumferential surface of the door, the sealing portion is hardened by the heat generated from the explosion or fire to fill the gap between the inner circumferential surface of the frame and the outer circumferential surface of the door to provide the effect of preventing the ingress of outside smoke or contaminated air. do.

In addition, the accommodating groove is hardened to correspond to the shape of the accommodating groove when the sealing portion formed on the outer circumferential surface of the door is cured by heat generated by an explosion or fire, so that the opening and closing of the door can be facilitated even after the sealing portion is cured. Provide effect.

In addition, by detecting a shock applied to the door through the detection unit, and when the fire or shock is detected by driving the door to close the door, there is an effect that can automatically close the door in the event of a fire.

In addition, when a person is in a position adjacent to the doorway while automatically closing the doorway in the event of a fire, it provides an effect that can prevent the door and the person from impacting by limiting the movement of the door.

1 is a perspective view showing a state in which the explosion-proof door is installed in a shelter according to an embodiment of the present invention.
2 is a perspective view showing a frame and a door according to an embodiment of the present invention.
3 is a perspective view illustrating a state cut along the cross-section of X-X 'of FIG.
FIG. 4 is a right cross-sectional view illustrating a state cut along the cross-section of X-X 'of FIG. 2.
5 is a front view showing an explosion-proof door according to an embodiment of the present invention.
FIG. 6 is an enlarged cross-sectional view of part A of FIG. 5.
7 is a perspective view showing a sealing part according to an embodiment of the present invention.
8 is a flow chart showing the automatic opening and closing of the explosion-proof door according to an embodiment of the present invention.
9 is a front view showing the explosion-proof door according to another embodiment of the present invention.
10 is an enlarged cross-sectional view of B of FIG. 9.
11 is a cross-sectional view showing an explosion-proof door according to another embodiment of the present invention.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

The accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the forms of the accompanying drawings.

However, in the following description of the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

Explosion-proof door of the present invention is installed at the entrance of safety facilities (hereinafter, structures), such as evacuation bunkers or shelter, is designed to withstand the impact of bombing or explosion from the outside, heat or toxic gases generated from fire It relates to an explosion-proof door that can prevent the entry of the.

1 is a perspective view showing an explosion-proof door according to an embodiment of the present invention.

As shown in FIG. 1, the explosion-proof door according to the present invention includes a frame 100, a door 200, a hinge part 300, and a locking part 400.

First, the frame 100 is configured to support the doorway 11 formed in the wall 10 of the structure.

Typically, since the doorway 11 is formed in a rectangular shape, the frame 100 of the present invention is also preferably formed in a rectangular frame shape.

Next, the door 200 is installed to be opened and closed on the inner surface of the frame 100, it is formed of an iron plate of a high strength material.

At this time, Figure 3 is a perspective view showing a state cut in the cross-section of X-X 'of Figure 2, as shown in Figure 3, the door 200 is an outer shell material 210, aluminum foam 220, heat insulating material 230 and the I-shaped reinforcement 240.

First, the envelope 210 is located on the outermost side of the door 200, it is made of a steel plate material.

That is, the envelope 210 is formed to surround the upper surface, the lower surface, the left surface, the right surface, the front surface, and the rear surface of the door 200, and between the front and rear aluminum foam 220, the heat insulator 230 and The I type reinforcement 240 is interposed in turn.

The aluminum foams 220 are installed in pairs on the inner surfaces of the pair of outer shells 210, respectively, and are manufactured to be lightweight and are formed to absorb shocks applied to the outside or inside of the structure.

On the other hand, the heat insulator 230 is installed in pairs on the inner surface of the pair of the aluminum foam 220, respectively, to block the heat to prevent the heat generated from the flame from the outside of the structure to enter the inside.

In addition, a plurality of I-type reinforcement members 240 are installed along a length direction of the door 200 between a pair of the heat insulators 230 to reinforce the rigidity of the door 200. .

In addition, the outer shell material 210, the aluminum foam 220 and the heat insulator 230 are formed in pairs at both ends of the I-shaped reinforcement 240 to the impact or heat applied to the outside or inside of the structure. With the structure of double blocking, there is an effect to improve the shock absorption and heat insulation, and to maintain the skeleton of the door 200.

In addition, as illustrated in FIG. 4, a honeycomb reinforcement member 250 is installed on an outer circumferential surface of the I-shaped reinforcement 240.

The reinforcement member 250 reinforces the impact applied to both ends of the I-shaped reinforcement 240 to minimize the deformation of the I-shaped reinforcement 240, a plurality of I-shaped reinforcement 240 It is installed on the outer circumferential surface of the

Each honeycomb space of the reinforcing member 250 may be filled with sand to absorb noise as well as shock absorption.

Next, as shown in FIG. 5, the hinge part 300 is installed between the frame 100 and the door 200 such that the door 200 is rotated on one side of the frame 100.

That is, the hinge part 300 is installed to rotate the door 200 to the outside or the inside of the structure, whereby the door 200 is opened and closed in the form of a case.

In addition, as shown in Figures 2 and 6, the locking unit 400 is installed in the frame 100 and the door 200, respectively, so that the frame 100 and the door 200 is closed.

In this case, the locking part 400 includes a metal block 410, an electromagnet block 420, and a control module 430.

First, the metal block 410 is installed on one side of the door 200, preferably is formed on the top of the door 200.

In this case, the metal block 410 is installed in the first insertion groove 201 formed in the upper surface of the door 200, it is formed at the same height as the height of the upper surface of the door 200.

In addition, the electromagnet block 420 is installed at a position corresponding to the metal block 410 on the inner circumferential surface of the frame 100, and is fastened by the magnetic block with the metal block 410 to frame the door 200. Fix to (100).

The electromagnet block 420 is installed in the second insertion groove 101 formed in the inner circumferential surface of the frame 100, it is formed at the same height as the height of the inner circumferential surface of the frame 100.

That is, the metal block 410 and the electromagnet block 420 are formed at the same height on the upper surface of the door 200 and the inner circumferential surface of the frame 100, respectively, so that a gap occurs between the frame 100 and the door 200. In this case, interference with the frame 100 may not occur in the opening and closing process of the door 200.

The control module 430 is installed adjacent to the electromagnet block 420 to sense the approach of the metal block 410, and when the metal block 410 approaches the electromagnet block 420, an electromagnet block ( Power is applied to the 420 to control the metal block 410 and the electromagnet block 420 to be fixed.

In addition, the locking unit 400 is installed adjacent to the electromagnet block 420, the magnetic block blocking the power applied to the electromagnet block 420 to release the metal block 410 and the electromagnet block 420 It further comprises a member 440.

The magnetic force blocking member 440 is made of a nonmagnetic material, and temporarily cuts off the power applied to the electromagnet block 420, so that a person who is present in the structure when an emergency occurs inside the structure is the metal block 410. ) And the electromagnet block 420 is released to open the closed door 200 in the frame 100.

Next, as shown in Figure 7, formed on the outer circumferential surface of the door 200, made of a thermosetting resin and cured by heat caused by the fire to fill the gap between the frame 100 and the door 200 is sealed It includes a sealing unit 500 to.

The sealing part 500 is formed on the outer surface of the door 200 that is in close contact with the inner surface of the frame 100, usually do not interfere with the opening and closing of the door 200 on the frame 100, due to explosion or bombing It is hardened by the heat of the generated flame to increase the volume and to close the doorway while filling the gap between the frame 100 and the door 200.

In addition, as the sealing part 500 is cured by heat, an accommodation groove (not shown) in which the cured sealing part 500 is accommodated is formed in the inner circumferential surface of the frame 100.

The receiving groove is formed in a shape corresponding to the sealing part 500 formed in the door 200, the sealing part 500 is formed to be accommodated while being cured by the heat of the flame generated by the explosion or bombing.

In one embodiment of the present invention, the door of the explosion-proof door, the sealing portion 500 is formed on the longitudinal surface of the door 200 in close contact with the frame 100, the receiving groove is the sealing portion 500 It is formed in the vertical surface of the frame 100 so as to correspond to the () is not affected by opening and closing the door 200 because the sealing part 500 is accommodated in the receiving groove even if the sealing part 500 is cured by heat. .

Next, a detection unit installed in the door 200 to detect a fire or shock, a drive unit installed in the frame to open and close the door 200 and a detection signal of the detection unit to detect a fire or shock The control unit further controls the driving unit to drive the door 200 in the direction in which the doorway is closed.

Referring to FIG. 8, when detecting a fire or an impact applied to the door 200 through the sensing unit, the door 200 is driven to close the door 11 to automatically close the door 11 when a fire occurs. Can be closed.

In addition, the frame 100 is provided with an identification unit for determining the presence or absence of a person in the doorway 11, the control unit receives the signal of the identification unit when the person is present in the doorway 11, the door 200 ) To control the driving unit.

Here, when there is a person in a position adjacent to the doorway 11, the identification unit detects it and transmits a signal to the control unit, and the control unit stops the door so that the frame and the door are closed so that a person gets stuck or moves ( 200) can be prevented from hitting people.

Next, the explosion-proof door according to another embodiment of the present invention is opened and closed in the form of a case, as shown in Figure 9, includes a frame 100, the door 200 and the locking unit 400.

The frame 100 is installed adjacent to the doorway 110 formed on the wall of the structure, the rail 110 is formed on the inner surface.

In this case, the frame 110 may be installed outside or inside the structure, and may be installed at the top or the bottom, respectively, and may be formed to face each other in the upper and lower parts.

The door 200 is coupled to the rail 110 to be movable along the rail 110, and opens and closes the doorway 11.

The locking unit 400 is installed on the frame 100 and the door 200 and fastened by magnetic force to fix the frame 100 and the door 200.

Explosion-proof door according to another embodiment of the present invention, as shown in Figure 3, the door 200 is an outer shell material 210, aluminum foam 220, insulator 230 and type I reinforcement 240 ).

First, the envelope 210 is located on the outermost side of the door 200, it is made of a steel plate material.

That is, the envelope 210 is formed to surround the upper surface, the lower surface, the left surface, the right surface, the front surface, and the rear surface of the door 200, and between the front and rear aluminum foam 220, the heat insulator 230 and The I type reinforcement 240 is interposed in turn.

The aluminum foams 220 are installed in pairs on the inner surfaces of the pair of outer shells 210, respectively, and are manufactured to be lightweight and are formed to absorb shocks applied to the outside or inside of the structure.

On the other hand, the heat insulator 230 is installed in pairs on the inner surface of the pair of the aluminum foam 220, respectively, to block the heat to prevent the heat generated from the flame from the outside of the structure to enter the inside.

In addition, a plurality of I-type reinforcement members 240 are installed along a length direction of the door 200 between a pair of the heat insulators 230 to reinforce the rigidity of the door 200. .

In addition, the outer shell material 210, the aluminum foam 220 and the heat insulator 230 are formed in pairs at both ends of the I-shaped reinforcement 240 to the impact or heat applied to the outside or inside of the structure. With the structure of double blocking, there is an effect to improve the shock absorption and heat insulation, and to maintain the skeleton of the door 200.

In addition, as illustrated in FIG. 4, a honeycomb reinforcement member 250 is installed on an outer circumferential surface of the I-shaped reinforcement 240.

The reinforcement member 250 reinforces the impact applied to both ends of the I-shaped reinforcement 240 to minimize the deformation of the I-shaped reinforcement 240, a plurality of I-shaped reinforcement 240 It is installed on the outer circumferential surface of the

Each honeycomb space of the reinforcing member 250 may be filled with sand to absorb noise as well as shock absorption.

In this case, the locking unit 400 will be described in detail with reference to FIG. 10.

The lock part 400 includes a metal block 410, an electromagnet block 420, and a control module 430.

First, the metal block 410 is installed on one side of the door 200, preferably is formed on the top of the door 200.

Here, the metal block 410 is installed in the first insertion groove 201 formed in the upper surface of the door 200, it is formed at the same height as the height of the upper surface of the door 200.

In addition, the electromagnet block 420 is installed at a position corresponding to the metal block 410 on the inner circumferential surface of the frame 100, and is fastened by the magnetic block with the metal block 410 to frame the door 200. Fix to (100).

The electromagnet block 420 is installed in the second insertion groove 101 formed in the inner circumferential surface of the frame 100, it is formed at the same height as the height of the inner circumferential surface of the frame 100.

That is, the metal block 410 and the electromagnet block 420 are formed at the same height on the upper surface of the door 200 and the inner circumferential surface of the frame 100, respectively, so that a gap occurs between the frame 100 and the door 200. In this case, interference with the frame 100 may not occur in the opening and closing process of the door 200.

The control module 430 is installed adjacent to the electromagnet block 420 to sense the approach of the metal block 410, and when the metal block 410 approaches the electromagnet block 420, an electromagnet block ( Power is applied to the 420 to control the metal block 410 and the electromagnet block 420 to be fixed.

In addition, the locking unit 400 is installed adjacent to the electromagnet block 420, the magnetic block blocking the power applied to the electromagnet block 420 to release the metal block 410 and the electromagnet block 420 It further comprises a member 440.

The magnetic force blocking member 440 is made of a nonmagnetic material, and temporarily cuts off the power applied to the electromagnet block 420, so that a person who is present in the structure when an emergency occurs inside the structure is the metal block 410. ) And the electromagnet block 420 is released to open the closed door 200 in the frame 100.

Next, with reference to Figure 11 in detail with respect to the receiving groove 130 and the sealing portion 500,

It is formed on the outer circumferential surface of the door 200, it is made of a thermosetting resin is cured by the heat caused by the fire to fill the gap between the frame 100 and the door 200 to seal the entrance further 500 Include.

The sealing part 500 is formed on the outer surface of the door 200 that is in close contact with the inner surface of the frame 100, usually do not interfere with the opening and closing of the door 200 on the frame 100, due to explosion or bombing It is hardened by the heat of the generated flame to increase the volume and to close the doorway while filling the gap between the frame 100 and the door 200.

In addition, as the sealing part 500 is cured by heat, an accommodation groove (not shown) in which the cured sealing part 500 is accommodated is formed in the inner circumferential surface of the frame 100.

The receiving groove is formed in a shape corresponding to the sealing part 500 formed in the door 200, the sealing part 500 is formed to be accommodated while being cured by the heat of the flame generated by the explosion or bombing.

In another embodiment of the present invention as a sliding door explosion-proof door, the sealing part 500 may be formed on both the horizontal surface and the vertical surface of the door, the receiving groove 130 also the horizontal surface and vertical surface of the frame 100 It can be recessed in both.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

10: wall
11: doorway
100: frame
101: second insertion groove
110: rail
120: first insertion groove
130: accommodation home
200: door
201: second insertion groove
210: shell material
220: aluminum foam
230: insulation
240: I type reinforcement
250: reinforcement member
300: hinge part
400: locking part
410: metal block
420: electromagnet block
430 control module
440: magnetic block member
500: sealed

Claims (12)

A frame configured to support the doorway formed in the wall of the structure;
A door installed to be opened and closed on an inner surface of the frame;
A hinge part interposed between the frame and the door to rotate the door; And
Includes; the locking portion is installed on the frame and the door,
The door is
It is made of a steel plate material and includes a plate-like outer shell material facing each other with a predetermined interval on the outermost side, and I-shaped reinforcement is installed between the outer shell material to reinforce the rigidity of the door,
An explosion-proof door, comprising: an aluminum foam installed on the inner surface of the outer cover material to absorb external shocks, and an insulator installed between the aluminum foam and the I-shaped reinforcement body.
It is installed adjacent to the doorway formed in the wall of the structure, the inner surface of the frame frame is formed;
A door coupled to the rail to be movable; And
Includes; the locking portion is installed on the frame and the door,
The door is
It is made of a steel plate material and includes a plate-like outer shell material facing each other with a predetermined interval on the outermost side, and I-shaped reinforcement is installed between the outer shell material to reinforce the rigidity of the door,
An explosion-proof door, comprising: an aluminum foam installed on the inner surface of the outer cover material to absorb external shocks, and an insulator installed between the aluminum foam and the I-shaped reinforcement body.
delete delete The method according to claim 1 or 2,
The door is
Explosion-proof door further comprises a honeycomb-shaped reinforcing member provided on the outer circumferential surface of the I-shaped reinforcement.
The method of claim 5,
The explosion-proof door is formed on the outer circumferential surface of the door, and further comprises a sealing portion formed of a thermosetting resin and cured by heat due to a fire to fill and close the gap between the frame and the door.
The method of claim 6,
On the inner circumferential surface of the frame,
As the seal is cured by heat, explosion-proof door characterized in that the receiving groove is formed to accommodate the cured seal.
The method of claim 5,
A detection unit installed in the door to detect a fire or an impact, a drive unit installed in the frame to open and close the door, and a detection signal of the detection unit to receive a detection signal such that a fire or shock is detected so that the doorway is closed. Explosion-proof door further comprises a control unit for controlling the drive unit to drive the door.
The method of claim 8,
The frame is provided with an identification unit for determining the presence or absence of people in the doorway,
The control unit receives the signal of the identification unit explosion-proof door, characterized in that for controlling the drive unit to stop the door when a person is present in the entrance.
The method according to claim 1 or 2,
The locking portion,
A metal block installed at one side of the door, an electromagnet block installed at a position corresponding to the metal block on one side of the frame and fastened by a magnetic block, and installed in the electromagnet block to detect an access of the metal block; Explosion-proof door comprising a control module for operating the electromagnet block.
The method of claim 10,
The locking portion,
And a magnetic force blocking member installed adjacent to the electromagnet block and releasing electric power applied to the electromagnet block to release the fixed metal block and the electromagnet block.
The method of claim 11,
The metal block is,
Is installed in the first insertion groove formed in the outer surface of the door, the same height as the height of the outer surface of the door,
The electromagnet block,
Explosion-proof door is installed in the second insertion groove formed in the inner peripheral surface of the frame, characterized in that the same height as the height of the inner peripheral surface of the frame.

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