JP6666162B2 - Pressure adjustment damper - Google Patents

Description

  The present invention relates to a pressure adjusting damper.

In various buildings, an auxiliary room is provided between a special evacuation stair or an emergency elevator and an adjacent room such as a corridor in order to secure an evacuation route in the event of a fire. Here, when an emergency elevator is provided, the attached room also serves as a lobby for getting on and off the emergency elevator. Pressurized smoke prevention equipment is installed in these additional rooms and the emergency elevator entry / exit lobby, and by sending air from the outside air to the additional room with a fan or the like and applying pressure, the pressure in the additional room is reduced from the pressure in the corridor. Raised to prevent smoke escaping from the firebox into the corridor from entering the room.
In addition, a fire door is provided between the annex room and the corridor, and when a fire occurs, the occupants open this fire door and evacuate from the corridor through the annex room using a special evacuation staircase.

  The fire doors are designed to open from the corridor to the attendant room according to the evacuation direction of evacuees. At the time of evacuation, as described above, since the pressure in the attached room is higher than the pressure in the corridor, the pressure that presses the fire door against the corridor acts due to the pressure difference. As a result, if the differential pressure between the attached room and the corridor is excessive, a large force is required to open the fire door, making it difficult to open the fire door.

  Therefore, in order to prevent the differential pressure between the additional room and the corridor from becoming excessive, the amount of air supplied to the additional room was controlled by controlling the amount of air supplied to the fan, and a pressure adjustment damper was installed on the wall facing the corridor in the additional room to supply the air Part of the air is released to the corridor.

For example, Non-Patent Literature 1 discloses a pressure adjustment damper including a rotary blade rotatably provided on a support shaft and a weight provided at a position offset from the support shaft. In this configuration, the moment acting on the support shaft from the weight acts in a direction to close the rotary blade. When a predetermined pressure or more acts on the rotating blade due to a differential pressure acting between the attached chamber and the adjacent chamber, the rotating blade is opened against the moment acting on the spindle from the weight. In this pressure adjusting damper, two weights are provided for each rotating blade. One of the weights is provided so as to offset the force due to the own weight of the rotating blade, and thus, when the rotating blade is opened to some extent, a moment acts so that the rotating blade is easily opened to the fully opened state. Let it.
In the pressure adjusting damper disclosed in Non-Patent Document 1, in addition to the moment acting on the support shaft from the weight, the moment due to the weight of the rotating blade also acts on the support shaft. Therefore, in the region where the rotating blade starts to open from the closed state, and further, in the region where the opening degree increases and reaches the fully opened state, the resistance when the rotating blade rotates is increased.
Further, in the pressure adjustment damper disclosed in Non-Patent Document 1, it is necessary to prevent the two weights from interfering with each other when the rotating blade rotates, and the installation space increases.

"Pressure adjustment damper", Damper general catalog, Nikkei Co., Ltd. March, 2015 second edition, page 25, [online], [searched on January 21, 2016], Internet <URL: http: // www. nikkey.co.jp/pdf/DAMPER_Web_2.pdf>

  SUMMARY OF THE INVENTION An object of the present invention is to provide a pressure adjustment damper capable of smoothly operating a rotating blade and reducing an installation space when a predetermined or more differential pressure is generated.

The present invention employs the following means in order to solve the above problems.
That is, the pressure adjustment damper of the present invention is a pressure adjustment damper provided between the first space and the second space adjacent to the first space, and has a first rotation shaft extending horizontally in the upward direction. A first rotating blade provided rotatably about the first rotation axis, a second rotation shaft extending downward in the horizontal direction, and provided rotatably about the second rotation axis. A second rotating blade, a connecting member that connects the first rotating shaft and the second rotating shaft so that the first rotating blade and the second rotating blade rotate in directions opposite to each other, A weight portion that applies a moment in the direction in which the first rotary blade and the second rotary blade close to the first rotary shaft or the second rotary shaft, against a pressure due to a differential pressure between the space and the second space; , Is provided.

According to such a configuration, the first rotating shaft and the second rotating shaft are connected by the connecting member so as to rotate in opposite directions to each other. The moment acting on the shaft and the second rotating shaft is offset. Thus, only the moment by the weight portion acts on the first rotating blade and the second rotating blade. Therefore, when the moment due to the pressure difference between the first space and the second space exceeds the moment due to the weight portion, the first rotating blade and the second rotating blade rotate smoothly, and The opening formed by the rotation of the first rotating blade and the second rotating blade expands, and the pressure difference between the first space and the second space is reduced.
Further, since the moments acting on the first rotating shaft and the second rotating shaft by the weights of the first rotating blade and the second rotating blade are offset as described above, the weight for offsetting the force due to the own weight of the rotating blades. Need not be installed. This makes it possible to reduce the number of weights to be installed, so that when the first rotating blades and the second rotating blades rotate, the weights do not interfere with the surroundings. Even if space is secured, the size of the pressure adjustment damper can be reduced.

  In one aspect of the present invention, in the pressure adjusting damper of the present invention, the weight portion may include a weight that applies the moment to the first rotation shaft or the second rotation shaft; As the rotating blades rotate in the opening direction from the closed state, the moment applied to the first rotating shaft or the second rotating shaft is reduced, so that the weight is moved from the first rotating shaft or the second rotating shaft. A variable offset size mechanism for changing the offset size.

  According to this configuration, the weight of the weight from the first rotation shaft or the second rotation shaft is reduced so that the moment due to the weight decreases as the first rotation blade and the second rotation blade rotate from the closed state to the opening direction. The offset dimension changes. Thereby, as the first rotating blade and the second rotating blade approach the fully opened state, they rotate in the opening direction with less resistance. Therefore, the first rotating blade and the second rotating blade rotate smoothly.

  In one aspect of the present invention, in the pressure adjustment damper of the present invention, the offset dimension variable mechanism rotates integrally with the first rotation shaft or the second rotation shaft, and the first rotation shaft or the second rotation shaft. The apparatus further includes an arm extending in a radial direction of the shaft, and a support member slidably provided along the arm and supporting the weight.

  According to such a configuration, when the first rotating blade and the second rotating blade rotate in the opening direction, the arm rotates integrally with the first rotating shaft or the second rotating shaft. As a result, the tilt state of the arm changes, and the support member supporting the weight slides along the arm. In this way, the offset dimension of the weight from the first rotary shaft or the second rotary shaft is reduced so that the moment due to the weight decreases as the first rotary blade and the second rotary blade rotate from the closed state to the open direction. Can be changed.

  In one aspect of the present invention, the pressure adjusting damper of the present invention is configured such that, when the arm is in the closed state of the first rotary blade and the second rotary blade, the first rotary shaft or the second rotary shaft. It is provided so as to be inclined obliquely downward as the distance from the side increases.

  According to such a configuration, when the first rotary blade and the second rotary blade are in the closed state, the arm is inclined obliquely downward as the arm is separated from the first rotary shaft or the second rotary shaft. The support member slides along the arm in a direction away from the first rotation shaft or the second rotation shaft. Thereby, the moment by the weight increases, and when the first rotary blade and the second rotary blade are in the closed state, the closed state can be reliably maintained.

  In one aspect of the present invention, in the pressure adjustment damper of the present invention, the offset dimension variable mechanism includes a stopper member that regulates an amount of sliding of the support member along the arm, and the stopper member is provided on the arm. The mounting position can be changed in a direction along the arm.

  According to such a configuration, by changing the mounting position of the stopper member along the arm, the magnitude of the moment applied to the first rotary blade and the second rotary blade by the weight can be easily adjusted.

  ADVANTAGE OF THE INVENTION According to this invention, when a pressure difference more than predetermined arises, while a rotating blade operates smoothly, it becomes possible to reduce installation space.

It is a top view of the building provided with the pressure adjustment damper concerning this embodiment. It is a front view which shows the pressure adjustment damper of FIG. FIG. 3 is a side view showing a damper unit constituting the pressure adjustment damper of FIG. 2. FIG. 4 is a front view showing a rotating shaft, a connecting member, and a weight mechanism that constitute the damper unit of FIG. 3. It is a side view which shows a weight mechanism. It is a side view which shows the weight mechanism when an upper blade and a lower blade are in a fully open state.

  An embodiment for implementing a pressure adjusting damper according to the present invention will be described below with reference to the accompanying drawings.

FIG. 1 shows a plan view of a building provided with a pressure adjusting damper according to the present embodiment.
As shown in FIG. 1, a building 1 is provided between an adjacent room (second space) 3 such as a corridor facing one or more rooms 2 and an adjoining room (first space) 4. A partition wall 9 for partitioning the storage room 4 from the storage room 4 is provided. Here, a special evacuation stair 5 is provided in the auxiliary room 4 so as to be adjacent via the partition wall 4a, and an emergency elevator 6 is provided so as to be adjacent through the partition wall 4b. A door 7 is provided between the attached room 4 and the special evacuation stairs 5.

The partition wall 9 is provided with a fire door 8 and a pressure adjusting damper 10.
The fire door 8 has one side end 8a rotatably supported about a vertical axis via a hinge (not shown). The fire door 8 is provided so as to be pushed open from the adjacent room 3 side to the attached room 4 side.

FIG. 2 is a front view showing the pressure adjustment damper of FIG. FIG. 3 is a side view showing a damper unit constituting the pressure adjusting damper of FIG. FIG. 4 is a front view showing a rotating shaft, a connecting member, and a weight mechanism constituting the damper unit of FIG.
As shown in FIG. 2, the pressure adjusting damper 10 includes a rectangular frame 11 fitted into an opening 9 a formed in the partition wall 9, and a plurality of pressure adjusting dampers 10 arranged in the frame 11, for example, in a vertical direction. And a damper unit 20 that is provided.

  As shown in FIGS. 3 and 4, each damper unit 20 includes a frame 20f, an upper blade (first rotating blade) 22A and a lower blade (second rotating blade) 22B, and a rotating shaft (first rotating shaft). 23A, a rotating shaft (second rotating shaft) 23B, a connecting member 24, and a weight mechanism (weight portion, offset dimension variable mechanism) 30.

  The frame 20f has a horizontally long rectangular cylindrical shape that is continuous in a direction in which the adjacent room 3 and the attached room 4 communicate with each other. The frame 20f is fixed to the frame 11 (see FIG. 2) by a fixing bracket or the like (not shown).

  The upper blade 22A and the lower blade 22B are provided as a pair up and down inside the frame 20f. The upper blade 22A and the lower blade 22B each have a strip shape extending in the width direction connecting the side walls 21a and 21b (see FIG. 4) on both sides of the frame 20f.

  As shown in FIG. 3, a groove 22m continuous in the width direction is formed in the upper blade 22A at a position offset above a middle position in the vertical direction. In the lower blade 22B, a groove 22n that is continuous in the width direction is formed at a position offset below a middle position in the vertical direction.

As shown in FIG. 4, the rotating shafts 23A and 23B extend in the width direction, respectively, and both ends of the rotating shafts 23A and 23B are formed in holes (not shown) formed in the side walls 21a and 21b of the frame 20f. It is rotatably supported around.
As shown in FIG. 3, the rotation shaft 23A is arranged above the frame 20f. The rotating shaft 23A is fitted into the groove 22m of the upper blade 22A, and is joined to the upper blade 22A via welding, a fixing bracket or the like.
The rotation shaft 23B is arranged below the frame 20f. The rotating shaft 23B is fitted into the groove 22n of the lower blade 22B, and is joined to the lower blade 22B via welding, a fixture, or the like.
In this manner, the upper blade 22A and the lower blade 22B held by the rotating shafts 23A and 23B are provided vertically symmetrically, and the tip 22s of the upper blade 22A and the tip 22t of the lower blade 22B move up and down with respect to each other. And is close to and facing. The upper blade 22A and the lower blade 22B rotate around the rotation shafts 23A and 23B as the rotation shafts 23A and 23B rotate.

  In the frame 20f, a stopper member 21S is provided on the attachment chamber 4 side of the tip portions 22s and 22t in a state where the upper blade 22A and the lower blade 22B are positioned in a vertical plane and are closed. The stopper member 21S restricts the rotation of the upper blade 22A and the lower blade 22B toward the attached chamber 4 from the state where they are located in the vertical plane. The stopper member 21S is formed in a V-shaped cross section in which the height in the vertical direction gradually increases from the side of the additional chamber 4 toward the side of the adjacent chamber 3.

  When the upper blade 22A and the lower blade 22B rotate together with the rotation shafts 23A and 23B to be fully opened, the frame 20f abuts on the tips 22s and 22t to open the upper blade 22A and the lower blade 22B. A stopper member 21T for regulating the degree is provided.

As shown in FIG. 4, one ends 23e and 23f of the rotating shafts 23A and 23B protrude outward in the width direction from the side wall 21a of the frame 20f.
As shown in FIG. 3, ends 23e and 23f of the rotating shafts 23A and 23B protruding outward in the width direction of the frame 20f are provided with rotating plates located in a plane orthogonal to the central axes of the rotating shafts 23A and 23B. 25A and 25B are provided. The rotating plates 25A and 25B are formed with through holes 25h through which the rotating shafts 23A and 23B pass, respectively. The rotating plates 25A and 25B are joined to the rotating shafts 23A and 23B by appropriate joining means such as welding. Thereby, the rotating plates 25A and 25B rotate integrally with the rotating shafts 23A and 23B.

  Pin insertion holes 26A and 26B are formed in the outer peripheral portions of the rotating plates 25A and 25B. Here, the pin insertion hole 26A formed in the upper rotary plate 25A is formed so as to be located below the rotary shaft 23A and, for example, on the side of the adjacent chamber 3 with respect to the rotary shaft 23A with the upper blade 22A closed. Have been. The pin insertion hole 26B formed in the lower rotary plate 25B is provided below the rotary shaft 23B and on the opposite side of the rotary shaft 23B from the pin insertion hole 26A with the lower blade 22B closed. It is formed to be located on the chamber 4 side.

The connecting member 24 has a rod shape, and pin insertion holes 28A and 28B are formed at upper and lower ends thereof. The connecting pins 27A, 27B are rotatably inserted into the pin inserting holes 28A, 28B of the connecting member 24 and the pin inserting holes 26A, 26B of the rotating plates 25A, 25B. Thus, the rotating plate 25A provided on the upper rotating shaft 23A and the rotating plate 25B provided on the lower rotating shaft 23B are connected via the connecting member 24 which extends obliquely in a cross-like manner.
Thereby, the upper blade 22A supported by the rotating shaft 23A and the lower blade 22B supported by the rotating shaft 23B are in a closed state and an open state in which the tip portions 22s and 22t swing toward the adjacent chamber 3 side. The opening 21K (see FIG. 4) on the inner side of the frame 20f opens and closes synchronously. That is, the upper blade 22A and the lower blade 22B constitute opposed wings that open and close in a so-called manner.

FIG. 5 is a side view showing the weight mechanism.
As shown in FIG. 5, the weight mechanism 30 is provided, for example, at the end 23e of the upper rotating shaft 23A. The weight mechanism 30 includes an arm 31, stopper members 32A and 32B, a slide member 33, and a weight.

  The arm 31 has a round bar shape, is inserted into a through hole 23h formed in the distal end 23e of the rotating shaft 23A, and is fixed to the rotating shaft 23A by, for example, welding. One end 31a of the arm 31 is fixed to the rotating shaft 23A, and the other end 31b extends radially outward from the rotating shaft 23A. Thereby, the arm 31 rotates integrally with the rotation shaft 23A.

  The stopper members 32A and 32B are provided on the other end 31b side of the arm 31 at intervals along the length direction of the arm 31. The stopper members 32A and 32B are formed in an annular shape made of, for example, a nut or the like, and the arm 31 is inserted through the inside thereof. Each of the stopper members 32A and 32B is provided with a retaining screw 35 that can advance and retreat in the radial direction of the arm 31. The position of the stopper members 32 </ b> A and 32 </ b> B in the length direction of the arm 31 can be fixed by screwing the retaining screw 35 and abutting its tip (not shown) against the outer peripheral surface of the arm 31.

  The slide member 33 has, for example, an annular shape, and the arm 31 is inserted inside the slide member 33. The slide member 33 is disposed between the pair of stopper members 32A and 32B, and is slidable along the length of the arm 31 between the stopper members 32A and 32B.

  The weight 34 is suspended from the slide member 33 via a support rod (support member) 36. The upper end 36 a of the support rod 36 is rotatably connected to the slide member 33.

  As shown in FIGS. 3 and 5, when the upper blade 22A is positioned in the vertical plane and is in the closed state, the arm 31 moves the other end 31b side downward below the horizontal state. It is provided so as to be inclined obliquely downward toward the other end 31b so as to be located. Thus, the slide member 33 is offset radially outward from the rotation shaft 23A in a state where the slide member 33 abuts against the stopper member 32A on the side closer to the other end 31b of the arm 31. The weight 34 suspended from the slide member 33 via the support rod 36 is located vertically below the slide member 33. In this state, the weight 34 causes the moment M1 in the direction in which the upper blade 22A closes to act on the rotation shaft 23A via the arm 31. This moment M1 is also transmitted to the lower rotating shaft 23B via the connecting member 24, and a force by the moment M1 acts in a direction in which the lower blade 22B closes.

FIG. 6 is a side view showing the weight mechanism when the upper blade and the lower blade are fully opened.
As shown in FIGS. 5 and 6, when the upper blade 22A shifts from the closed state to the open state, the arm 31 rotates together with the rotation shaft 23A, and the other end 31b is higher than the one end 31a. , And is inclined obliquely upward toward the other end 31b (shown by a two-dot chain line in FIG. 5). Then, the slide member 33 slides from the stopper member 32A side toward the stopper member 32B closer to the rotation shaft 23A. The weight 34 suspended from the slide member 33 via the support rod 36 moves toward the stopper member 32B while being positioned vertically below the slide member 33. In this state, the weight 34 applies a moment M2 in the direction in which the upper blade 22A closes to the rotating shaft 23A via the arm 31. In this state, as compared with the closed state (see FIG. 3), since the slide member 33 approaches the rotation shaft 23A and the offset dimension is small, the moment M2 is small as compared with the moment M1 in the closed state. Has become. This moment M2 is also transmitted to the lower rotating shaft 23B via the connecting member 24, and a force by the moment M2 acts in a direction in which the lower blade 22B closes.

Next, the operation of the above-described pressure adjusting damper 10 will be described.
As shown in FIG. 3, the pressure adjustment damper 10 is normally closed with the upper blade 22A and the lower blade 22B positioned in a vertical plane.

When the fire detection system detects that a fire has occurred due to the operation of the smoke sensor or the heat sensor, outside air is sent from the air supply port (not shown) to the attached room 4 through a duct connected to the air supply fan. Then, the inside of the additional chamber 4 is pressurized, and a pressure difference is generated between the adjacent chamber 3 side and the additional chamber 4 side.
Due to this differential pressure, in each damper unit 20 of the pressure adjusting damper 10, a pressure P from the additional chamber 4 side to the adjacent chamber 3 side acts on the upper blade 22A and the lower blade 22B. Due to the pressure P, a moment Me acts on the upper blade 22A and the lower blade 22B so as to open the upper blade 22A and the lower blade 22B toward the adjacent chamber 3 side. The weight M of the weight mechanism 30 acts on the upper blade 22A and the lower blade 22B in the direction of closing the upper blade 22A and the lower blade 22B. As long as the moment Me due to the pressure P from the additional chamber 4 side does not exceed the moment M1 in the direction of closing the upper blade 22A and the lower blade 22B, the upper blade 22A and the lower blade 22B maintain the closed state. .
In this way, it is possible to maintain the fully closed state when the pressure adjusting damper 10 is below a certain set differential pressure, the differential pressure between the adjacent chamber 3 side and the auxiliary chamber 4 side is maintained, and the pressure applied to the auxiliary chamber 4 is maintained. Intrusion of smoke through the room door 8 is prevented.

The pressure difference between the adjacent chamber 3 side and the auxiliary chamber 4 side increases, and the pressure P acting on the upper blade 22A and the lower blade 22B from the auxiliary chamber 4 side to the adjacent chamber 3 side is set to a first preset value. When the pressure (for example, 30 Pa) is reached, the moment Me becomes larger than the moment M1 by the weight 34, and the upper blade 22A and the lower blade 22B rotate in the opening direction.
Here, the upper blade 22A and the lower blade 22B are two-sided opposing wings provided vertically symmetrically, and the rotating shafts 23A and 23B extending in the width direction (horizontal direction) are connected by the connecting member 24. Moments acting on the rotating shafts 23A and 23B due to the loads of the blades 22A and the lower blades 22B are offset. Accordingly, only the moment M1 by the weight 34 acts on the rotating shafts 23A and 23B, and when the upper blade 22A and the lower blade 22B start opening due to the pressure P from the additional chamber 4, the opening operation is performed smoothly.

  Thereafter, as shown in FIG. 6, the upper blade 22A and the lower blade 22B are opened to a predetermined angle to be in a fully opened state. In this manner, when the upper blade 22A and the lower blade 22B shift from the slightly opened state at the beginning of opening to the fully opened state, the arm 31 of the weight mechanism 30 rotates with the rotation of the rotating shafts 23A and 23B. When the arm 31 is tilted so that the other end 31b is positioned higher than the one end 31a, the slide member 33 slides toward the rotation shaft 23A, and the moment in the direction in which the upper blade 22A is closed by the weight 34 is generated. It becomes smaller gradually. Therefore, as the upper blade 22A and the lower blade 22B approach the fully opened state, they rotate more easily in the opening direction, and reliably shift to the fully opened state.

  In this way, the pressure adjusting damper 10 is opened, and the air flows from the auxiliary chamber 4 side to the adjacent chamber 3 side, so that the differential pressure between the auxiliary chamber 4 and the adjacent chamber 3 side decreases. Thereby, the door 8 can be easily pushed and opened to the attached room 4 side.

According to the pressure adjustment damper 10 described above, the rotating shaft 23A extending upward in the horizontal direction is provided, the upper blade 22A rotatably provided around the rotating shaft 23A, and the rotating shaft extending downward in the horizontal direction. 23B is provided, and the lower blade 22B rotatably provided around the rotary shaft 23B is connected to the rotary shaft 23A and the rotary shaft 23B such that the upper blade 22A and the lower blade 22B rotate in opposite directions. And a weight mechanism 30 that applies a moment M1 in the direction in which the upper blade 22A and the lower blade 22B close to the rotating shaft 23A against the pressure P caused by the pressure difference between the additional chamber 4 and the adjacent chamber 3. Prepare.
According to such a configuration, the rotating shaft 23A and the rotating shaft 23B are connected by the connecting member 24 so as to rotate in the opposite directions to each other, so that the rotating shaft 23A and the rotating shaft 23A are rotated by their own weights of the upper blade 22A and the lower blade 22B. The moment acting on the shaft 23B is canceled. Thus, only the moment M1 by the weight mechanism 30 acts on the upper blade 22A and the lower blade 22B. Therefore, when the moment Me due to the pressure difference between the additional chamber 4 and the adjacent chamber 3 exceeds the moment M1 by the weight mechanism 30, the upper blade 22A and the lower blade 22B rotate smoothly. As a result, the additional room 4 side and the adjacent room 3 side communicate with each other, and the differential pressure between the additional room 4 and the adjacent room 3 decreases.
In this way, when a pressure difference equal to or more than a predetermined value is generated, the upper blade 22A and the lower blade 22B can operate smoothly.
Further, the moment acting on the rotating shaft 23A and the rotating shaft 23B due to the weight of the upper blade 22A and the lower blade 22B is offset as described above, and therefore, the force due to the weight of the upper blade 22A and the lower blade 22B is offset. There is no need to install weights. Accordingly, when the weight mechanism 30 rotates together with the upper blade 22A and the lower blade 22B, even if a space is secured so that the weight mechanism 30 does not interfere with the surroundings, the pressure adjustment damper 10 can be made smaller (thinner). Can be planned. Thereby, the installation space for the pressure adjustment damper can be reduced.

In addition, the weight mechanism 30 has a weight 34 that applies the moments M1 and M2 to the rotation shaft 23A, and a small moment that is applied to the rotation shaft 23A as the upper blade 22A and the lower blade 22B rotate from the closed state to the open direction. Thus, the offset dimension of the weight 34 from the rotation shaft 23A changes.
According to such a configuration, as the upper blade 22A and the lower blade 22B approach the fully opened state, they rotate in the opening direction with less resistance. Therefore, the upper blade 22A and the lower blade 22B rotate smoothly.

More specifically, the weight mechanism 30 further includes an arm 31 that rotates integrally with the rotation shaft 23A, and a support rod 36 that is slidably provided along the arm 31 and supports the weight 34.
According to such a configuration, when the upper blade 22A and the lower blade 22B rotate in the opening direction, the arm 31 rotates integrally with the rotation shaft 23A. Accordingly, the inclined state of the arm 31 changes, and the support rod 36 that supports the weight 34 slides along the arm 31. In this manner, the offset dimension of the weight 34 from the rotating shaft 23A can be changed so that the moment by the weight 34 decreases as the upper blade 22A and the lower blade 22B rotate from the closed state to the open direction.

Further, when the upper blade 22A and the lower blade 22B are in the closed state, the arm 31 is provided to be inclined obliquely downward as the arm 31 is separated from the rotation shaft 23A.
According to such a configuration, when the upper blade 22A and the lower blade 22B are in the closed state, the support rod 36 is inclined obliquely downward as the arm 31 moves away from the rotation shaft 23A side. It slides along the direction 31 away from the rotation shaft 23A side. Thereby, the moment M1 by the weight 34 increases, and when the upper blade 22A and the lower blade 22B are in the closed state, the closed state can be reliably maintained.

Further, the weight mechanism 30 includes stopper members 32A and 32B for restricting a sliding amount of the support rod 36 along the arm 31. The stopper members 32A and 32B are attached to the arm 31 in a direction along the arm 31. It can be changed.
According to such a configuration, the magnitudes of the moments M1 and M2 applied to the upper blade 22A and the lower blade 22B by the weight 34 can be easily changed by changing the mounting position of the stopper members 32A and 32B along the arm 31. Can be adjusted. For example, when the position of the stopper member 32A is adjusted so as to change the moment M1, the operating pressure at which the upper blade 22A and the lower blade 22B start to open can be adjusted. Further, when the position of the stopper member 32B is adjusted so as to change the moment M2, the opening degree and the rotation speed of the upper blade 22A and the lower blade 22B can be adjusted.

(Other modifications)
In the above-described embodiment, the weight mechanism 30 has a configuration in which the slide member 33 and the support rod 36 that support the weight 34 slide in the direction approaching the rotation shaft 23A along the arm 31. However, the present invention is not limited thereto. If the moment by the weight 34 changes gradually with the rotation of the arm 31, another structure may be adopted.
Further, the weight mechanism 30 may be configured so that the connection position of the support rod 36 supporting the weight 34 with respect to the arm 31 does not change.
Further, the upper blade (first rotary blade) 22A and the lower blade (second rotary blade) 22B may be slightly bent, instead of straight, to increase the lift.
Further, the additional room 4 taken up as a place where the pressure adjusting damper 10 is installed is not limited to the additional room defined by the Building Standards Law, but may be a pressurized room.
In addition, the configuration described in the above embodiment can be selected or changed to another configuration as appropriate without departing from the gist of the present invention.

1 building 3 adjoining room (second space)
4 attached room (first space)
10 Pressure adjusting damper 22A Upper blade (first rotating blade)
22B Lower blade (second rotating blade)
23A rotation axis (first rotation axis)
23B Rotary axis (second rotary axis)
24 Connecting member 30 Weight mechanism (weight part, offset dimension variable mechanism)
31 Arm 32A, 32B Stopper member 33 Slide member 34 Weight 36 Support rod (support member)
M1 Moment M2 Moment Me Moment P Pressure

Claims (3)

A pressure adjustment damper provided between a first space and a second space adjacent to the first space,
A first rotary shaft extending upward in the horizontal direction is provided, and a first rotary blade rotatably provided around the first rotary shaft,
A second rotary shaft extending downward in the horizontal direction is provided, and a second rotary blade rotatably provided around the second rotary shaft,
As the first rotating blade and the second rotating blade rotate in opposite directions, a connecting member that connects the first rotating shaft and the second rotating shaft,
Resisting the pressure due to the pressure difference between the first space and the second space, imparting a moment in the direction in which the first rotary blade and the second rotary blade close to the first rotary shaft or the second rotary shaft. Weight part,
Equipped with a,
The weight portion is
Weight to give the moment to the first rotation axis or the second rotation axis,
As the first rotary blade and the second rotary blade rotate in the opening direction from the closed state, the first weight of the weight is reduced so that the moment applied to the first rotary shaft or the second rotary shaft decreases. Offset dimension variable mechanism for changing the offset dimension from the rotation axis or the second rotation axis,
With
The offset dimension variable mechanism,
An arm that rotates integrally with the first rotation shaft or the second rotation shaft and extends in a radial direction of the first rotation shaft or the second rotation shaft,
Slidably provided along the arm, the pressure adjustment damper, wherein Rukoto and a support member for supporting the weight. The arm is provided such that when the first rotary blade and the second rotary blade are in the closed state, the arm is inclined obliquely downward as the distance from the first rotary shaft or the second rotary shaft side increases. The pressure adjustment damper according to claim 1 , wherein: The offset dimension variable mechanism includes a stopper member that regulates a sliding amount of the support member along the arm,
The stopper member, the pressure adjustment damper according to claim 1 or 2, characterized in that the mounting position relative to the arm is changeable in a direction along the arm.

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