JP5393512B2 - Fire door - Google Patents

Description

  The present invention relates to a fire door that can be easily unlocked even when the room is at a high pressure by supplying gas into the room.

  2. Description of the Related Art Conventionally, in a facility equipped with precision equipment such as a large computer and a server, a fire extinguishing system is known that quickly extinguishes fire in order to protect precision equipment when a fire or the like occurs in a room.

  In this fire extinguishing system, fire extinguishing gas is generally used as a fire extinguishing agent because, when extinguishing with water or a chemical fire extinguishing agent, the device may be damaged or malfunction or malfunction may occur. As an example of this fire extinguishing system, for example, Patent Document 1 discloses a gas fire extinguishing facility that injects and fills a room with a fire extinguishing gas composed of an inert gas such as nitrogen gas, carbon dioxide gas, and halogen gas or a nonflammable gas. ing.

  In such a gas fire extinguishing system, a large amount of fire extinguishing gas is filled in a room in a short time to quickly extinguish the fire. Therefore, since the room becomes a high pressure in a short time, a high pressure by the high-pressure gas is applied to the door for entering and exiting the room.

  Here, for example, a latch mechanism is provided in the fire door provided in the room in which the precision instrument is installed. The latch mechanism is configured such that a strike provided on one door engages a latch bolt provided on the other door. For example, in the door lock device described in Patent Document 2, a spring member is provided at the base of the latch bolt, and the spring member is operated by pressing the door by operating a knob or lever handle or pushing the door. The latch bolt is retracted and removed from the strike so that the door can be opened.

JP 2000-60984 A JP 2000-240341 A

  However, when a high-pressure fire extinguishing gas is injected (spouted) into the room at the time of a fire as described above, high-pressure is instantaneously applied to the fire door that divides the room where the equipment is installed and the external space such as a corridor. Is done. For this reason, there was a possibility that the fire door could not be opened due to deformation. That is, for example, as shown in FIG. 13 and FIG. 14, when the high pressure P is applied to the fire door 1, the doors 2 and 3 are bent and deformed, and an excessive force is applied to the latch mechanism 4 to cause the latch and strike. The hinge 5 is deformed, the rank 5 is deformed, the order adjuster 6 is broken or caught, the door check 7 is broken, or the joinery frame (door frame) 8 is deformed. Even if the lever handle (handle 9) is operated, the fire door 1 (doors 2 and 3) may not be opened.

  If the fire door 1 is not opened in this way, an evacuation route cannot be secured or the secondary fire extinguishing activity will be hindered, so fire extinguishing gas is injected into the room R1 and high pressure P is loaded. Even in such cases, there was a strong demand to be able to go in and out of the room.

  In view of the above circumstances, an object of the present invention is to provide a door unlocking device capable of reliably opening and closing a fire door even when a fire extinguishing gas is injected into the room and a high pressure is applied. And

  This invention is made in view of such a situation, Comprising: It aims at providing the fire door which can go in and out of a room | chamber interior even if it is a case where a room | chamber interior becomes high voltage | pressure by ejection of fire extinguishing gas, etc. To do.

In order to solve the above problems, the present invention proposes the following means.
That is, the fire door according to the present invention is a fire door provided with a door that can be freely opened and closed in a passage communicating with the interior and exterior of a fire extinguishing gas, wherein the door includes a first door member and the first door. A single door comprising a second door member rotatably connected to the member, wherein the second door member is one piece with the first door member against the rotation of the second door member. An urging member for urging the door is provided, and the urging force of the urging member is configured to be offset by the pressure in the room when the fire extinguishing gas is completely supplied into the room. It is characterized by that.

  According to the fire door having such characteristics, when pressure is applied to the door by supply of the fire extinguishing gas, the pressure counteracts the urging force of the urging member to cancel the urging force. Thereby, the 2nd door member in a door can turn with respect to the 1st door member for the first time, when the room becomes high pressure.

  Moreover, in the fire door which concerns on this invention, the said 1st door member is attached to the wall surface of the said passage so that rotation is possible, and the said 2nd door member is the said room | chamber interior with respect to the said 1st door member. It is connected so that it can rotate toward the top, and it is preferred that the door which consists of these 1st door members and 2nd door members has made the shape of a folding door.

  By making the door into a folded door shape composed of the first door member and the second door member, the door can be used as a single door by the urging force of the urging member in a normal time, and the room has a high pressure. In this case, the urging force of the urging member is canceled by the indoor pressure, and the second door member can be opened as a folding door by rotating toward the indoor side.

  Furthermore, in the fire door according to the present invention, the first door member is rotatably attached at one end thereof to the wall surface of the passage, and further includes a communication portion for communicating the interior and the exterior. May be arranged as a hollow door that closes the communication portion, and connected to the first door member so as to be rotatable toward the outside of the room.

  By making the second door member a hollow door disposed in the communication portion of the first door member, the door can be used as a single door by the urging force of the urging member in a normal state, and the room has a high pressure. In this case, the urging force of the urging member is offset by the indoor pressure, and the second door member rotates toward the outside of the room, so that an evacuation path can be secured.

  According to the fire door of the present invention, the door is constituted by the first door member and the second door member that function as a single door by the urging force of the urging member, and the urging force of the urging member is supplied when the fire extinguishing gas is supplied. By competing with the pressure in the room, the second door member and the first door member can be rotated only when the pressure in the room becomes high. Thereby, even when a fire extinguishing gas is injected into the room and a high pressure is applied, it is possible to go in and out of the room.

It is a front view of the fire door of 1st Embodiment. It is a perspective view of the fire door of 1st Embodiment. It is a top view of the fire door of 1st Embodiment. It is a top view explaining the function of the fire door of 1st Embodiment. It is a front view of the fire door of 2nd Embodiment. It is a perspective view of the fire door of 2nd Embodiment. It is a top view of the fire door of 2nd Embodiment. It is a top view explaining the function of the fire door of 2nd Embodiment. It is the (a) side view and (b) front view of the fire door of the 1st modification. It is the (a) side view and (b) front view of the fire door of the 2nd modification. It is the (a) side view and (b) front view of the fire door of the 3rd modification. It is the (a) side view and (b) front view of the fire door of the 4th modification. It is a front view which shows the conventional fire door. It is a top view which shows the conventional fire door.

  First, the fire door 20 of the present embodiment includes a room R1 such as a room in which precision equipment such as a large computer and a server is installed, a clean room in which a semiconductor manufacturing apparatus is installed, and a door opening formed in the wall of the room R1. It is installed so as to be openable and closable so as to communicate / partition with an external space R2 such as a corridor that is connected through the space. Further, the chamber R1 is provided with a gas fire extinguishing system that injects an inert gas such as nitrogen gas, carbon dioxide gas, and halogen gas or a nonflammable gas (fire extinguishing gas) at a high pressure when a fire occurs.

  Hereinafter, the fire door 20 of the first embodiment will be described. As shown in FIGS. 1 to 4, the fire door 20 is provided in a passage (joint frame) 11 that communicates the inside and outside of the room R <b> 1 and the external space R <b> 2, and has a double door with a pair of doors 21 and 22. Has been. The doors 21 and 22 are pivotally connected to the side walls of the passage 11 by a plurality of first hinges (hinges) 23 so that the passage 11 can be opened and closed. The opening direction F of the fire door 20 is a direction from the chamber R1 toward the external space R2.

  Each of the doors 21 and 22 is a single door composed of a first door member 51 and a second door member 52. The first door member 51 constitutes the outer half of the passage 11 in the doors 21 and 22, has a substantially rectangular shape extending over the upper and lower sides of the passage 11, and one end side thereof with respect to the passage 11 by the first hinge 23. And are pivotally connected.

The second door member 52 forms a central half of the doors 21 and 22 that are joined to each other. The ends are connected via a plurality of second hinges 54. The second hinge 54 connects the first door member 51 and the second door member 52 so as to be rotatable about the vertical axis on the chamber R1 side, whereby one end of the second door member 52 is the first door. The other end of the door member 51 is rotatable toward the inside of the chamber R1.
As described above, the doors 21 and 22 of the present embodiment have a so-called folding door shape because the first door member 51 and the second door member 52 are rotatably connected.

  Moreover, as shown in FIG. 1, the cylinder lock 26 and the latch lock 27 are provided in the opposing surfaces 21a and 22a of the center side in the doors 21 and 22 mutually joined. In addition, it replaces with the cylinder lock 26 or it replaces with the cylinder lock 26, and other locking devices, such as an electric lock, may be provided.

  The latch lock 27 is provided in the latch strike 40 provided on the right door 21 in FIG. 1 and the left door 22 in FIG. And a latch 35. The latch lock 27 is provided with a lever handle 30 for removing the latch 35 from the strike 40, but a door knob may be provided instead of the lever handle 30.

  Further, a dead bolt strike 29 is provided on the left door 21 in FIG. 1, and a cylinder lock 26 on the right door 22 is received in the dead bolt strike 29 to lock the opening and closing of the fire door 20. A dead bolt 28 is provided. Furthermore, the door closer (door check) 31 for adjusting the closing speed of the doors 21 and 22 is provided in the upper part by the side of the 1st hinge 23 of each door 21 and 22. FIG.

  As shown in FIG. 3, the fire door 20 of the present embodiment is provided with a compression spring 53 that connects the first door member 51 and the second door member 52 of each door 21 and 22 outside the chamber R1. It has been. The compression spring 53 has a coil shape in which a metal is formed in a spiral shape. One end of the compression spring 53 is fixed to the first door member 51 and the other end is fixed to the second door member 52. And the compression spring 53 resists the rotation with respect to the 1st door member 51 of the 2nd door member 52 so that these 1st door members 51 and the 2nd door member 52 may be in the state of one door. That is, the first door member 51 and the second door member 52 are biased so as to be positioned in the same vertical plane.

  Accordingly, in a normal state, the relative positions of the first door member 51 and the second door member 52 are maintained by the biasing force of the compression spring 53, so that the doors 21 and 22 can each be used as a single door. it can.

  It should be noted that only one compression spring 53 may be provided on each of the doors 21, 22 or a plurality of compression springs 53 may be provided on each of the doors 21, 22, but the total urging force of the compression spring 53 may be provided. Is set to a value equivalent to the room pressure when the fire extinguishing gas is completely supplied into the room R1,

  Next, the operation of the fire door 20 will be described. 1 to 3, it is assumed that an electric lock and a cylinder lock 26 (not shown) are unlocked and the latch locks 27 of the doors 21 and 22 of the fire door 20 are closed.

  When an operator enters or exits the chamber R1, for example, the lever 35 is rotated downward, so that the latch 35 is retracted via a coupling mechanism (not shown). Accordingly, when the latch bolt 36 is retracted from the strike 40, the door is opened, and the operator enters and exits by opening the other door 22 that functions as a single door to the outside of the chamber R1 by the urging force of the compression spring 53. Will be able to.

  For example, when a fire occurs in the chamber R1 and a high-pressure fire extinguishing gas is injected at a high speed from the gas injection port provided in the chamber R1, the fire extinguishing gas fills the chamber R1 in a short time, and the fire extinguishing is performed. It is. At this time, high pressure is instantaneously applied to the fire door 20 that partitions the chamber R1 and the external space R2 toward the door opening direction F.

  By being pushed by such a pressure, the doors 21 and 22 start to deform around the central portion. In this state, when the operator rotates the lever handle 30 or the knob in order to get out of the chamber R1 in the high-pressure gas state, the latch 35 advances into the strike 40 and is engaged, so that the lever handle is caused by the rotational resistance. 30 or the knob is difficult to rotate.

  On the other hand, when pressure is applied to the doors 21 and 22 due to the high pressure in the chamber R1, the pressure tends to rotate the second door member 52 relative to the first door member 51. The pressure antagonizes the urging force of the compression spring 53. At this time, since the urging force of the compression spring 53 is set to a value equivalent to the pressure in the chamber R1 to which the extinguishing gas is completely supplied, the urging force is offset by the pressure in the chamber R1, and the second The door member 52 can be rotated with respect to the first door member 51.

  At this time, when a worker applies human power to the doors 21 and 22 by pressing the connecting portion between the first door member 51 and the second door member 52, that is, the vicinity of the second hinge 54, from inside the chamber R1, As shown in FIG. 4, the first door member 51 rotates toward the outside of the chamber R <b> 1 relative to the side wall of the passage 11, and the second door member 52 moves toward the inside of the chamber R <b> 1 with respect to the first door member 51. And the doors 21 and 22 are deformed into folding doors.

  Accordingly, in the present embodiment, the doors 21 and 22 that are normally used as a single door are deformed into a folding door only when the inside of the chamber R1 becomes high pressure. It can be opened and the inside and outside of the room R1 can be communicated. Thereby, it becomes possible to ensure the safety by securing an evacuation route for the creator.

Next, although the fire door 20 of 2nd Embodiment is demonstrated with reference to FIGS. 5-8, the description is abbreviate | omitted using the same code | symbol for the part which is the same as that of 1st Embodiment mentioned above, or the same, and a member. To do.
In 2nd Embodiment, only the door 21 was comprised from the 1st door member 61 provided with the communication part 61a, and the 2nd door member 62 which obstruct | occludes the communication part 61a among a pair of doors 21 and 22. It is a single door.

  The first door member 61 has a frame plate shape that forms a substantially rectangular outer shape of the door 21, and a communication portion 61 a that communicates the inside and outside of the chamber R <b> 1 is formed inside the first door member 61. The communication portion 61a has a substantially rectangular shape in which the outer shape of the first door member 61, that is, the outer shape of the door 21, is made slightly smaller, and is large enough for an operator to pass through. One end of the first door member 61 is connected to the passage 11 by the first hinge 23 so as to be rotatable.

  The second door member 62 has a substantially rectangular plate shape having the same outer shape as the communication portion 61a so as to close the communication portion 61a of the first door member 61, and the end portion on the side wall side of the passage 11 is The first door member 61 is connected via a plurality of (four in this embodiment) pretension hinges 63. The pretensioning hinge 63 connects the first door member 61 and the second door member 62 so as to be rotatable about the vertical axis inside the chamber R1, so that one end of the second door member 62 is connected to the first door member 62. The other end of the one-house member 61 is rotatable toward the outside of the chamber R1.

  Here, the pretension hinge 63 is provided with an elastic body such as a spring as an urging member, and the urging member resists the rotation of the second door member 62 relative to the first door member 61. The first door member 61 and the second door member 62 are energized so that they are in a single door state, that is, the first door member 61 and the second door member 62 are positioned in the same vertical plane. doing. As a result, the door 21 is normally held in a state where the communication portion 61a of the first door member 61 is closed by the second door member 62, and the door 21 can be used as a single door. Yes.

  The sum of the urging forces of the urging members in the pretension hinge 63 is set to a value equivalent to the indoor pressure when the fire extinguishing gas is completely supplied into the chamber R1.

  Since the fire door 20 of the present embodiment has the above-described configuration, when pressure is applied to the doors 21 and 22 due to the high pressure in the chamber R 1, the pressure is applied to the second door 21. The door member 62 tends to be rotated toward the outside of the chamber R1 with respect to the first door member 61. Then, this pressure antagonizes the urging force of the urging member of the pretension hinge 63. At this time, since the urging force of the urging member is set to a value equivalent to the pressure in the chamber R1 to which the extinguishing gas is completely supplied, the urging force is offset by the pressure in the chamber R1, and the second The door member 62 can be easily rotated with respect to the first door member 61.

  At this time, when the worker presses the second door member 62 from the inside of the chamber R1 from the inside of the chamber R1, the second door member 62 rotates toward the outside of the chamber R1 as shown in FIG. The worker can escape from the room R1 through the communication portion 61a using the second door member 62 as a hollow door.

  Therefore, in this embodiment, the door 21 that is normally used as a single door rotates the second door member 62 with respect to the first door member 61 only when the inside of the chamber R1 becomes high pressure. Therefore, since it can be used as a hollow door, it is possible to secure an evacuation route for the collector and ensure safety.

The embodiment of the present invention has been described above, but the present invention is not limited to this, and can be appropriately changed without departing from the technical idea of the present invention.
For example, in the embodiment, the description has been given of the case where the compression spring 53 or the pretension hinge 63 is used as the urging member. However, the present invention is not limited to this, and the first of the second door members 52 and 62 is normally used. Other spring members may be employed as the biasing member as long as they can be biased against the rotation of the door members 51 and 61. Even in this case, the urging force of the spring member is set to be equal to the pressure when the inside of the chamber R1 becomes high pressure due to the fire extinguishing gas, thereby realizing the fire door 20 having the same effect as the embodiment. be able to.

FIG. 9 shows a first modification of the present invention.
The fire door 20 shown in FIG. 9 is formed with a communication path 70 having a substantially rectangular shape at the center of the door 22 of the pair of doors 21 and 22, and a slide member 71 for closing the communication path 70 is provided. It has been. The slide member 71 is configured to be slidable downward along the guide 73 by a roller 72, and is normally locked at a position where the communication path 70 is closed. When the operator operates the unlock lever 74, the slide member 71 is configured to slide downward by its own weight.

  Thereby, even if it is a case where the inside of chamber R1 becomes a high voltage | pressure and the doors 21 and 22 become difficult to open, an operator can escape by passing the communicating path 70. FIG. Further, since the roller 72 is installed in a direction to receive pressure acting from the inside of the chamber R1, the slide member 71 can be reliably slid even under high pressure.

FIG. 10 shows a second modification of the present invention.
In the fire door 20 shown in FIG. 10, a communication path 80 having a substantially rectangular shape is formed in the lower part of the door 21 of the pair of doors 21 and 22, and a slide member 75 for closing the communication path 80 is provided. ing. The slide member 75 is configured to be slidable upward by a roller 81. Further, one end of a rope 77 that extends around a fixed pulley 76 provided on the upper portion of the door 21 and extends downward is fixed to the slide member 75, and a weight 78 is fixed to the other end of the rope 77. Is provided.

  As a result, when the operator holds the handle 79 of the slide member 75 and tries to push it upward, the slide member 75 can be easily slid upward with the assistance of the weight of the weight 78. Therefore, even when the inside of the chamber R1 becomes high pressure and the doors 21 and 22 are difficult to open, the operator slides the slide member 75 to open the communication path 80 and opens the communication path 80. By passing through, it is possible to easily escape from the room R1. Similarly to the first modification, the roller 81 is installed in a direction to receive pressure acting from the inside of the chamber R1, so that the slide member 75 can be reliably slid even under high pressure.

FIG. 11 shows a third modification of the present invention.
A pair of doors 21 and 22 in the fire door 20 shown in FIG. 11 is formed with a rectangular communication passage 82 extending in the vertical direction, and a shutter 83 is provided so as to close the communication passage 82. Yes. A shutter accommodating portion 84 is provided at the upper end portion of the shutter 83, and when the shutter 83 is pushed up, the shutter 83 is accommodated in the shutter accommodating portion 84.

  Thereby, even if the inside of the chamber R1 becomes high pressure and the doors 21 and 22 are difficult to open, the operator can easily escape from the chamber R1 by pushing up the shutter 83. Alternatively, the shutter 83 may be electrically operated, and the shutter 83 may be automatically pushed up when a fire signal and an operation signal are received.

FIG. 12 shows a fourth modification of the present invention.
A communication path 85 having a substantially rectangular shape is formed in the lower portion of the pair of doors 21 and 22 in the fire door 20 shown in FIG. 12, and the fire damper 86 is configured to close the communication path 85. Is provided. The fire damper 86 is normally closed, but by operating the operation lever 87, the damper can be opened to temporarily release the pressure in the chamber R1. The damper is urged in the closing direction in advance, and is configured to be self-closed when the pressure in the chamber R1 decreases.

  Thereby, when the inside of the chamber R1 becomes high pressure and the doors 21 and 22 are difficult to open, the pressure in the chamber R1 is temporarily released by operating the operation lever 87, and the doors 21 and 22 are easily opened. be able to.

20 Fire door 21 Door 22 Door 51 First door member 52 Second door member 53 Compression spring (biasing member)
54 Second hinge 61 First door member 62 Second door member 63 Pre-tension hinge (urging member)
R1 room

Claims (3)

In a fire door provided with a door that can be freely opened and closed in a passage that communicates with the interior and exterior of a room where fire extinguishing gas is supplied,
The door is a single door comprising a first door member and a second door member rotatably connected to the first door member,
A biasing member that biases the second door member to a state of a single door with the first door member against rotation of the second door member is provided,
A fire door characterized in that the urging force of the urging member is configured to be offset by the pressure in the room when the fire extinguishing gas is completely supplied into the room. One end of the first door member is rotatably attached to the wall surface of the passage,
The second door member is rotatably connected to the first door member toward the room,
The fire door according to claim 1, wherein the door formed of the first door member and the second door member has a folded door shape. The first door member includes a communicating portion that is rotatably attached to a wall surface of the passage and that communicates the interior and the exterior.
The said 2nd door member is arrange | positioned as a hollow door which obstruct | occludes the said communication part, and is connected with respect to the said 1st door member so that rotation toward the said outdoor is possible. Fire door.

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