JP6815595B2 - Pressure adjustment room - Google Patents

Description

The present invention relates to a pressure regulating chamber in which the interior of the chamber is transformed.

In the pressure adjustment room as described above, the sealing of the room is an indispensable requirement. Many of the doors used in the pressure adjustment room are hinged, and the closing door presses the seal member provided around the opening to seal the room. However, hinged doors require space in the direction in which the door opens, so space cannot be used effectively. On the other hand, for example, as disclosed in Patent Document 1, a pressure adjusting room using a sliding door is already known.

Patent Document 1 describes a sealing body embedded around the entrance and exit of a chamber, a pressing base that pushes the sealing body from the inside to the outside of the chamber, and a plurality of eccentrics that move the pressing base from the inside to the outside of the chamber by rotational motion. It has a cam and an operation lever for operating the plurality of eccentric cams, and is configured so that the seal body can be extended to the outside of the chamber by operating the operation lever. In Patent Document 1, when the door slides and is located at the front position of the doorway frame body, the door and the seal body are pressed against each other by operating the operation lever to extend the seal body toward the door to seal the room. Is playing.

Jikken Sho 63-000262

According to Patent Document 1, since a sliding door is used, a space is not required in the opening direction unlike a hinged door, and the space can be effectively used. However, according to Patent Document 1, in order to achieve the sealing of the room, it takes time and effort to operate the operating lever, and the structure is also complicated.

Therefore, an object of the present invention is to provide a pressure adjusting room having a simple structure and easily sealing the room.

The characteristic configuration of the pressure adjustment room according to the present disclosure is a pressure adjustment room in which the inside of the room is transformed, and a seal portion arranged around the opening of the room and an open state in which the opening is opened. A door that can be moved between a position, a closed position that closes the opening, and a closed position that is in close contact with the seal portion and seals the chamber, and an open position and a closed position. The first slide mechanism that moves the door in the first direction along the path connecting the doors, and the second that moves the door in the second direction along the path connecting the closed position and the closed position. A slide mechanism and a guide mechanism for guiding the movement of the door are provided, and the guide mechanism is formed along the first direction and has a first guide portion for guiding the door in the first direction. The door having a second guide portion that is formed so as to project in the second direction and guides the door in the second direction to be brought into close contact with the seal portion, and the door that is in close contact with the seal portion is at the time of transformation. The point is that the seal portion is compressed by the pressure change of the door.

According to this configuration, the door opens the opening of the chamber in the open position, closes the opening of the chamber in the closed position, and adheres to the seal portion in the sealed position to seal the chamber. Then, the door is guided in the first direction by the first guide portion of the guide mechanism and moves between the open position and the closed position by the first slide mechanism. Further, the door is guided in the second direction by the second guide portion of the guide mechanism and moves by the second slide mechanism to be in close contact with the seal portion, and the door presses the seal portion by the pressure change during transformation. And seal the room. That is, by the guide mechanism that guides the door in the first direction and the second direction, the door is brought into close contact with the seal portion by a series of flows of sliding the door, and the inside of the room is transformed to press the door against the seal portion. Therefore, the room can be easily sealed. Therefore, the pressure adjustment room according to this configuration has a simple structure and can be easily sealed.

Further, the door has a guide roller that is suspended and supported and can come into contact with the first guide portion and the second guide portion, and the guide mechanism is opposite to the seal portion with the guide roller interposed therebetween. It is preferable that the guide roller has a guide wall at a position on the side, and the guide roller is configured to roll along the guide wall while being in contact with the guide wall.

According to this configuration, the guide roller can roll while being in contact with the guide wall located on the opposite side of the seal portion with the guide roller in between. That is, the guide roller can be rolled while the seal portion and the door are separated from each other. Further, the door having the guide roller is suspended and supported. Therefore, the weight of the door does not prevent the guide roller from rolling. In this way, the pressure adjustment room according to this configuration smoothly moves the door in the first and second directions without receiving the frictional force between the seal portion and the door due to the rolling of the guide roller. Can be done.

Further, the first guide portion has a first guide wall formed along the first direction, and the second guide portion has a second guide wall formed so as to be inclined in the second direction. It is preferable to have it.

According to this configuration, the guide roller rolls along the first guide wall to ensure that the door is guided in the first direction. Further, the guide roller rolls along the second guide wall so that the door is surely guided in the second direction. That is, the pressure adjusting room according to this configuration can reliably guide the door in the first direction and the second direction, and as a result, the accurate operation of the door can be realized.

Further, the door has an inner door arranged inside the room and an outer door arranged outside the room, and the inner door and the outer door are the second door at the time of transformation. It is preferable that they are configured to move to the same side when moving in a direction.

According to this configuration, when pressure is applied from the inside to the outside of the chamber when the chamber is pressurized, both the inner door and the outer door move outward in the second direction, and only the inner door is sealed. The part is pressed to seal the room. On the other hand, when pressure is applied from the outside to the inside of the chamber when the chamber is depressurized, both the inner door and the outer door move inward in the second direction, and only the outer door presses the seal portion. The room is sealed. That is, the pressure adjustment room according to this configuration can reliably seal the room even when the room is pressurized and depressurized.

Further, it is preferable that the pressure adjusting room according to the present disclosure further includes a restraining member that covers the outer periphery of the opening.

When the chamber is transformed, pressure is applied to the entire chamber, but in particular, stress is concentrated on the opening, so that the chamber is easily deformed. According to this configuration, since the outer circumference of the opening is restrained by the restraining member, the deformation of the chamber opening is restricted. Therefore, the pressure adjustment room according to this configuration can prevent deformation of the opening due to stress concentration, and thus prevent damage to the pressure adjustment room due to the deformation.

It is preferable that the pressure adjustment room according to the present disclosure is configured to pressurize the room by filling the room with oxygen and nitrogen using cylinders provided separately.

According to this configuration, it is possible to pressurize the room and appropriately adjust the amount of oxygen and nitrogen in the room. That is, when the pressure adjustment room is used for medical treatment such as rapid recovery of the body, it is possible to increase the oxygen concentration in the room. As a result, the oxygen concentration in the user's body can be increased to promote metabolism, and effects such as recovery from fatigue can be obtained. In addition, it is possible to pressurize the room with the same concentration as the oxygen concentration and nitrogen concentration contained in the atmosphere. As a result, it is possible to perform muscle strength training with a low load under pressure, and it is possible to efficiently perform physical training. That is, the pressure adjustment room according to this configuration can be suitably used for medical treatment or physical training.

Further features and advantages of the techniques according to the present disclosure will be further clarified by the following illustration of exemplary and non-limiting embodiments described with reference to the drawings.

It is a perspective view of the pressure adjustment room which concerns on this embodiment. It is the figure which looked at the pressure adjustment room from the indoor side. FIG. 2 is a sectional view taken along line III-III in FIG. It is explanatory drawing of the guide mechanism which concerns on this embodiment. It is sectional drawing of the main part of the pressure adjustment room which concerns on 2nd Embodiment. It is sectional drawing of the door which concerns on 2nd Embodiment.

Hereinafter, the pressure adjusting room 1 according to the present embodiment will be described with reference to the drawings.

[Structure of pressure adjustment room according to the first embodiment]
As shown in FIGS. 1 and 2, the pressure adjusting room 1 opens a room 2 capable of accommodating a user, a seal portion 3 arranged around an opening 22 of the room 2, and an opening 22. It is possible to move between the open position OP, the closed position CP that closes the opening 22, and the closed position SP that is in close contact with the seal portion 3 and seals the chamber 2 (see also FIGS. 3 and 4). It is equipped with a door 4. The pressure adjusting room 1 is configured so that the inside of the room 2 can be transformed.

The chamber 2 has a main body portion 21 and an opening 22 formed in the main body portion 21. The main body 21 is formed in a cylindrical box shape in order to evenly disperse the pressure inside the chamber 2 during transformation over the entire chamber 2. Further, the pressure adjusting room 1 further includes a restraining member 8 that covers the outer periphery of the opening 22. The restraint member 8 is formed in a band shape. In the present embodiment, a pair of such restraint members 8 are provided. Each of the pair of restraint members 8 is provided along both edges of the opening 22 over the entire outer circumference of the chamber 2. Further, an auxiliary member is provided which is arranged along both upper and lower edges of the opening 22 and which stretches a pair of restraint members 8. With these restraint members 8 and restraint members, it is possible to regulate the deformation of the opening 22 which is easily deformed as a result of receiving stress concentration during transformation of the chamber 2. Therefore, it is possible to prevent damage to the pressure adjusting room 1 due to deformation of the opening 22 during transformation. As the restraining member 8, an annular member such as a sword can be used. The restraint member 8 is preferably made of metal. As a result, the durability of the pressure adjusting room 1 at the time of transformation is improved.

The opening 22 is formed in such a size that the user of the pressure adjusting room 1 can enter and exit the inside of the room 2. Further, the opening 22 is formed in a rectangular shape including upper and lower sides and both side surfaces. Specifically, since the opening 22 is formed in the cylindrical box-shaped main body portion 21, both sides are formed in a rectangular shape curved to the outside of the chamber 2. The pressure adjusting room 1 is closed because the opening 22 is closed by the door 4. When the opening 22 is not closed by the door 4 and is open, the pressure adjusting room 1 is in the open state. In FIG. 2, the opening 22 does not show a curved shape for the convenience of visual recognition, but shows the vicinity of the upper portion and the vicinity of the lower portion of the opening 22 in a vertical state.

As shown in FIG. 2, a seal portion 3 is arranged around the opening 22. In the present embodiment, the seal portion 3 is formed inside the chamber 2 over the entire circumference of the opening 22. An elastic member that expands and contracts with a predetermined shrinkage allowance by pressing is used for the seal portion 3. As the seal portion 3, for example, natural rubber, synthetic rubber, or the like can be preferably used.

The door 4 is attached to the inside of the chamber 2 and is configured to be movable between an open position OP that opens the opening 22 and a closed position CP that closes the opening 22. In the present embodiment, the door 4 is a sliding type, and has an outer handle 42O on the outside and an inner handle 42I on the inside (see FIGS. 1 and 2). Since the door 4 closes the opening 22, the door 4 is formed in a rectangular shape whose central portion is curved outward, corresponding to the shape of the opening 22. The door 4 is formed sufficiently larger than the opening 22. Here, the "closed state" means a state in which the door 4 overlaps the entire opening 22. Therefore, since the door 4 is formed sufficiently larger than the opening 22, the door 4 can move to some extent while maintaining the closed state.

As shown in FIG. 2, the pressure adjusting chamber 1 includes a first slide mechanism 5 that moves the door 4 in the first direction A along a path connecting the open position OP and the closed position CP. .. Here, the first direction A is the direction indicated by A in FIG. Hereinafter, the side in which the door 4 is closed in the first direction A will be referred to as the “first direction closing side A1”, and the side in which the door 4 is opened will be referred to as the “first direction opening side A2”. The first slide mechanism 5 supports the door 4 inside the chamber 2, and the door 4 can be moved along the first direction A. The first slide mechanism 5 is configured to include a slide rail 51 extending along the first direction A, and a slide body 52 that fits outside the slide rail 51 and moves along the slide rail 51. .. The slide rail 51 is attached to the main body 21 via the attachment bracket 56 (see FIG. 3). Although not shown, a plurality of rollable balls are interposed between the slide rail 51 and the slide body 52. The ball is configured to circulate inside the slide body 52 while rolling along the slide rail 51 inside the slide body 52. Therefore, the first slide mechanism 5 is configured so that the slide body 52 can smoothly move along the slide rail 51 by rolling the balls inside the slide body 52. In the present embodiment, a pair of slide bodies 52 are provided, and these slide bodies 52 support the upper portion of the door 4 and both ends in the first direction A. That is, in the present embodiment, since the pair of slide bodies 52 support the door 4 at both ends, the posture of the door 4 can be maintained parallel to the slide rail 51. Therefore, the door 4 does not tilt with respect to the first direction A, and the first slide mechanism 5 can smoothly move the door 4 along the first direction A.

As shown in FIG. 3, the pressure adjusting room 1 includes a second slide mechanism 6 that moves the door 4 in the second direction B along the path connecting the closed position CP and the closed position SP. .. Here, the second direction B is the direction indicated by B in FIG. The second direction B means a direction extending in the radial direction from the center of the internal space of the chamber 2. Hereinafter, the central side of the internal space of the chamber 2 in the second direction B will be referred to as the “second direction inner B2”, and the side facing outward from the center of the internal space of the chamber 2 will be referred to as the “second direction outer B1”. In the present embodiment, the second slide mechanism 6 is provided integrally with the first slide mechanism 5. The second slide mechanism 6 directly suspends and supports the door 4. The first slide mechanism 5 described above has a connecting shaft 53, and is connected to the second slide mechanism 6 by the connecting shaft 53. The connecting shaft 53 is formed so as to project from the surface of the inner side B2 in the second direction of the slide body 52 toward the inner side B2 in the second direction. The second slide mechanism 6 has a slide cylinder portion 61 that is extrapolated to the connecting shaft 53 and can slide along the connecting shaft 53. A washer 54 is provided at the tip of the connecting shaft 53 so that the slide cylinder portion 61 slides along the connecting shaft 53 and does not come off to the inner side B2 in the second direction. The slide cylinder portion 61 is connected to the middle plate 62 at the end portion of the outer side B1 in the second direction. As shown in FIG. 2, the middle plate 62 is provided so as to project downward with respect to the slide cylinder portion 61. A door connecting portion 63 is provided at the lower part of the middle plate 62. In the present embodiment, as the door connecting portion 63, three bolts penetrating the middle plate 62 are shown as an example. As shown in FIG. 3, the door connecting portion 63 is connected to the door 4 at the end of the outer side B1 in the second direction. In the second slide mechanism 6, when the slide cylinder portion 61 slides in the second direction B along the connecting shaft 53 of the first slide mechanism 5, the middle plate 62 integrated with the slide cylinder portion 61 and the door are connected. The portion 63 and the door 4 are also configured to slide in the second direction B. When the second slide mechanism 6 slides to the outer side B1 in the second direction, the first slide mechanism 5 is between the middle plate 62 and the middle plate 62 so that the middle plate 62 does not strongly contact the slide body 52 of the first slide mechanism 5. Moreover, a cushioning plate 55 is provided at the base end of the connecting shaft 53. Note that FIG. 3 shows the case where the door 4 is in the closed position SP, which will be described later. At this time, the door 4 and the seal portion 3 are in contact with each other, but the door 4 is not in the closed position SP. Occasionally, the weight of the door 4 causes the second slide mechanism 6 to slide inward B2 in the second direction. This is because the door 4 is formed in a curved shape that is convex toward the outer side B1 in the second direction, so that the weight of the door 4 is applied to the inner side B2 in the second direction. That is, in that case, the door 4 is moved to the inner side B2 in the second direction by the second slide mechanism 6, and the door 4 and the seal portion 3 are in a non-contact state.

The door 4 described above is suspended and supported by the first slide mechanism 5 and the second slide mechanism 6, and has a guide roller 41 in the lower part inside the chamber 2. In the present embodiment, the pressure adjusting room 1 further includes a guide rail 7 as a guide mechanism for guiding the door 4. As shown in FIG. 2, the guide rail 7 is provided below the opening 22 inside the chamber 2. The guide rail 7 is provided along the first direction A, and as shown in FIGS. 3 and 4, only the upper portion is open. Further, as shown in FIG. 4, the guide rail 7 is formed along the first direction A and is formed so as to protrude in the second direction B with the first guide portion 71 that guides the door 4 in the first direction A. It also has a second guide portion 72 that guides the door 4 in the second direction B and brings it into close contact with the seal portion 3. Further, in the present embodiment, as shown in FIG. 3, the guide rail 7 has a guide wall 73 at a position opposite to the seal portion 3 with the guide roller 41 interposed therebetween. In the present embodiment, as shown in FIG. 3, the guide wall 73 is formed on the inner side B2 in the second direction of the guide rail 7. Further, the guide wall 73 is formed perpendicular to the bottom surface of the guide rail 7. Further, the guide roller 41 has a rotation axis perpendicular to the bottom surface of the guide rail 7. Therefore, the guide roller 41 is configured to roll along the guide wall 73 while being in contact with the guide wall 73. As described above, the door 4 is urged to the inner side B2 in the second direction by its own weight. Therefore, the guide roller 41 provided at the lower part of the door 4 is also always urged to the inner side B2 in the second direction. Since the guide roller 41 is always in contact with the guide wall 73 formed on the inner B2 in the second direction of the guide rail 7 by being urged by the inner B2 in the second direction, the guide roller 41 rolls along the guide wall 73. It is movable. Further, as a result, when the door 4 is located at the open position OP, the door 4 and the seal portion 3 are in a non-contact state, and the door 4 moves smoothly without frictional resistance due to contact with the seal portion 3. can do. As described above, the door 4 having the guide roller 41 has a configuration that can be guided by the guide rail 7.

As shown in FIG. 4, the first guide portion 71 has a first guide wall 73A formed along the first direction A, and the second guide portion 72 is formed so as to be inclined in the second direction B. It has a second guide wall 73B. As shown in FIGS. 4 (b) and 4 (b'), the first guide wall 73A is formed on the inner side B2 in the second direction of the first guide portion 71. The second guide wall 73B is formed on the inner side B2 in the second direction of the second guide portion 72. In the present embodiment, the second guide wall 73B is formed so as to be inclined toward the outer side B1 in the second direction. As described above, since the guide roller 41 is urged to the inner side B2 in the second direction by the weight of the door 4, the first guide roller 41 is first along the first guide wall 73A when passing through the first guide portion 71. Roll in direction A. Further, the guide roller 41 rolls along the second guide wall 73B in a state of being pushed toward the outer side B1 in the second direction by the second guide wall 73B when passing through the second guide portion 72. In the present embodiment, the guide rail 7 has an outer wall 74 formed perpendicular to the bottom surface of the guide rail 7 on the outer side B1 in the second direction and an end portion on the closed side A1 in the first direction with respect to the bottom surface of the guide rail 7. It has a stopper wall 75 formed vertically. The stopper wall 75 regulates the guide roller 41 from moving beyond the stopper wall 75 to the closed side A1 in the first direction.

Here, FIG. 4 is a diagram showing the relationship between the movement of the guide roller 41 and the movement of the second slide mechanism 6 and the door 4. The figures shown in FIGS. 4A and 4A are cross-sectional views of the upper part of the door 4. The views shown in FIGS. 4 (b) and 4 (b') are views of the lower portion of the door 4 as viewed from the direction of the rotation axis of the guide roller 41. 4 (a) and 4 (b) are diagrams corresponding to each other. Further, FIGS. 4 (a') and 4 (b') are diagrams corresponding to each other. When the guide roller 41 is in the position of the first guide portion 71 as shown in FIG. 4 (b), the door 4 is located in the closed position CP that closes the opening 22 as shown in FIG. 4 (a). At this time, the door 4 and the seal portion 3 are in a non-contact state. When the guide roller 41 is in the position of the second guide portion 72 as shown in FIG. 4 (b'), the door 4 is in a sealed position SP in contact with the seal portion 3 as shown in FIG. 4 (a'). Is located in.

The door 4 in close contact with the seal portion 3 is configured to press the seal portion 3 due to a pressure change during transformation. In the present embodiment, the door 4 is configured to press the seal portion 3 toward the outer side B1 in the second direction when the inside of the chamber 2 is pressurized. As shown in FIG. 4 (b'), when the guide roller 41 is at the position of the second guide portion 72, that is, at the position corresponding to the closed position SP of the door 4 (see FIG. 4 (a')). When the guide roller 41 is located, a constant gap G is formed between the outer wall 74 and the guide roller 41. The size of the guide roller 41 with respect to the guide rail 7 is adjusted so that the gap G becomes larger than the shrinkage allowance of the seal portion 3 when the door 4 presses the seal portion 3 when the inside of the chamber 2 is pressurized. There is.

[Operation of pressure adjustment room]
Next, the operation of the pressure adjustment room 1 will be described. The user of the pressure adjusting room 1 enters the inside of the room 2 through the opening 22, and slides the door 4 at the open position OP to the first-direction closed side A1. Since the door 4 is in a state of being urged to the inner side B2 in the second direction by its own weight, the guide roller 41 rolls while contacting the first guide wall 73A as shown in FIG. 4B. As a result, the door 4 moves to the closed side A1 in the first direction along the first direction A while being guided by the first guide portion 71.

When the door 4 is located at the closed position CP while moving along the first direction A, the door 4 and the opening 22 are completely overlapped with each other. Since the door 4 is formed sufficiently larger than the opening 22, the door 4 can move a predetermined distance while maintaining a position completely overlapping the opening 22, that is, a closed position CP. At this time, the door 4 and the seal portion 3 are still in a non-contact state.

As shown in FIG. 4 (b'), when the guide roller 41 reaches the second guide portion 72, the guide roller 41 rolls along the second guide wall 73B. Since the second guide wall 73B is formed so as to be inclined toward the outer side B1 in the second direction, the guide roller 41 is pushed into the outer side B1 in the second direction by the second guide wall 73B. When the guide roller 41 is pushed into the outer side B1 in the second direction, the second slide mechanism 6 functions as shown in FIG. 4A, and the door 4 moves to the outer side B1 in the second direction against its own weight. Moving. As a result, the door 4 is located at the closed position SP, and the door 4 and the seal portion 3 are in contact with each other. At this time, the door 4 and the seal portion 3 are only in contact with each other, and the seal portion 3 is not pressed by the door 4. Further, there is a gap G between the guide roller 41 and the outer wall 74 of the guide rail 7 that is larger than the shrinkage allowance of the seal portion 3.

Next, the inside of the chamber 2 is pressurized from the state where the door 4 is located at the closed position SP in contact with the seal portion 3. As shown in FIG. 3, when the inside of the chamber 2 is pressurized, the pressing force Pi acts on the entire chamber 2. The pressing force Pi acts toward the outer side B1 in the second direction and pushes the door 4 into the outer side B1 in the second direction. Then, the door 4 urged to the inner side B2 in the second direction by its own weight receives the pressing force Pi and slides to the outer side B1 in the second direction by the amount of the shrinkage allowance of the seal portion 3. Then, the door 4 presses the seal portion 3 in contact with the outside B1 in the second direction. As a result, the seal portion 3 is pressed by the door 4 and crushed. At this time, the door 4 slides to the outer side B1 in the second direction in order to press the seal portion 3, but before the pressurization of the chamber 2, the guide roller 41 and the guide rail 7 are placed in the lower part of the door 4. Since a gap G larger than the shrinkage allowance of the seal portion 3 is formed between the outer wall 74 and the door 4 (see FIG. 4 (b')), the sliding of the door 4 during pressurization is not hindered. .. When the seal portion 3 is pressed against the door 4 and crushed, the door 4 and the main body portion 21 of the chamber 2 are firmly sealed, and the air inside the chamber 2 does not leak to the outside. Under this pressure, the user of the pressure adjusting room 1 can utilize the pressure adjusting room 1 according to the purpose of use such as treatment and physical training.

[Pressure in the room]
In the above, the pressure adjusting room 1 in which the inside of the room 2 is pressurized has been described. In the present embodiment, the pressure adjusting room 1 is configured to pressurize the room by filling the room with oxygen and nitrogen using cylinders provided separately. Although not shown, an oxygen cylinder and a nitrogen cylinder are installed outside the room 2 of the pressure adjustment room 1. The pressure adjustment chamber 1 is configured to be provided with a pipe or the like that communicates an oxygen cylinder and a nitrogen cylinder with the inside of the chamber 2. Then, the amount of oxygen and the amount of nitrogen inside the chamber 2 are adjusted by manually opening and closing the valves of the oxygen cylinder and the nitrogen cylinder. Therefore, oxygen and nitrogen can be supplied from the oxygen cylinder and the nitrogen cylinder installed outside the chamber 2 to the inside of the chamber 2. Further, both an oxygen concentration meter or a nitrogen concentration meter or both an oxygen concentration meter and a nitrogen concentration meter are installed inside the chamber 2. As a result, the pressure adjusting room 1 can pressurize the inside of the room 2 while adjusting the oxygen concentration and the nitrogen concentration inside the room 2. This adjustment may be performed mechanically by automatic control. Further, the oxygen cylinder and the nitrogen cylinder may be installed inside the chamber 2.

In general, it is already known that a high concentration of oxygen is taken into the body for the purpose of recovery of the body. It is also already known that a more recovery effect can be obtained by ingesting oxygen and pressurizing the room. However, excessive intake of oxygen may cause oxygen toxicity and have an adverse effect on the human body. Therefore, if the oxygen concentration in the room becomes too high, the air in the room may be discharged to the outside. In this case, the pressurized state in the room cannot be maintained due to the discharge of air. However, in the present embodiment, the pressure adjusting room 1 is configured to pressurize the inside of the room 2 by filling the room 2 with nitrogen as well as oxygen. Therefore, when the oxygen concentration in the chamber 2 becomes too high, nitrogen can be supplied into the chamber 2 at the same time to maintain the pressurized state in the chamber 2 even when the air in the chamber 2 is discharged. ..

[Structure of pressure adjustment room according to the second embodiment]
Hereinafter, the pressure adjustment room according to the second embodiment will be described. It should be noted that the points not particularly described with respect to the second embodiment are the same as those of the first embodiment.

As shown in FIG. 5A, in the second embodiment, the door 4 has an inner door 42 arranged inside the room 2 and an outer door 43 arranged outside the room 2. There is. That is, the door 4 has a double structure. Each of the inner door 42 and the outer door 43 has the same structure as the door 4 according to the first embodiment. That is, in the second embodiment, the first slide mechanism 5, the second slide mechanism 6, and the guide rail 7 (not shown) as the guide mechanism are provided both inside and outside the chamber 2. Further, as shown in FIG. 5A, the seal portions 3 are also provided on both the inside and the outside of the chamber 2. That is, the inner seal portion 3I is arranged around the opening 22 inside the chamber 2. An outer seal portion 3O is arranged around the opening 22 on the outside of the chamber 2. At normal pressure, the inner door 42 is configured to be urged to the inner side B2 in the second direction by its own weight so as not to press the inner seal portion 3I. Similarly, with respect to the outer door 43, its own weight acts on the inner B2 in the second direction. Therefore, the outer door 43 is provided with a coil spring 57 that urges the outer door 43 to the outer B1 in the second direction so that the outer door 43 does not press the outer seal portion 3O at normal pressure. The coil spring 57 urges the outer door 43 against the outer B1 in the second direction against the weight of the outer door 43 so that the outer door 43 does not press the outer seal portion 3O under normal pressure. There is. In the present embodiment, the coil spring 57 is provided between the middle plate 62 and the cushioning plate 55 while being fitted on the connecting shaft 53. Further, a compression coil spring is used as such a coil spring 57. The coil spring 57 may be omitted, and the second slide mechanism 6 that suspends and supports the outer door 43 may be tilted downward of the outer side B1 in the second direction. In that case, the outer door 43 is urged to the outer side B1 in the second direction by its own weight.

The inner door 42 and the outer door 43 are configured to move to the same side when moving in the second direction B during transformation. In the present embodiment, the inner door 42 and the outer door 43 are configured to move to the outer B1 in the second direction when the inside of the chamber 2 is pressurized. As shown in FIG. 5B, when the chamber 2 is pressurized, the pressing force Pi acts toward the outer side B1 in the second direction. The pressing force Pi acts to push the inner door 42 and the outer door 43 into the outer B1 in the second direction, and the inner door 42 and the outer door 43 slide in the outer B1 in the second direction. Therefore, the inner seal portion 3I is pressed against the outer B1 in the second direction by the inner door 42 and is crushed. As a result, the inner door 42 and the main body 21 of the chamber 2 are firmly sealed, and the air inside the chamber 2 does not leak to the outside.

In the present embodiment, the inner door 42 and the outer door 43 are configured to move to the inner side B2 in the second direction when the pressure in the chamber 2 is reduced. As shown in FIG. 5C, when the chamber 2 is depressurized, a decompression force Pd acts toward the inner side B2 in the second direction. The depressurizing force Pd acts to pull the inner door 42 and the outer door 43 toward the inner B2 in the second direction, and the inner door 42 and the outer door 43 slide toward the inner B2 in the second direction. Therefore, the outer seal portion 3O is pressed against the inner B2 in the second direction by the outer door 43 and is crushed. As a result, the outer door 43 and the main body 21 of the chamber 2 are firmly sealed, and the air outside the chamber 2 does not enter the inside.

As described above, the pressure adjusting room according to the second embodiment can surely seal the room 2 even when the inside of the room 2 is pressurized and depressurized. Here, since the second embodiment is configured as a double door, the inner door 42 and the outer door 43 are arranged so as to face each other with the seal portion 3 and the main body portion 21 interposed therebetween. Therefore, the protruding handles 23 cannot be provided on the facing surfaces of the inner door 42 and the outer door 43 as in the first embodiment. Therefore, as shown in FIG. 6, in the second embodiment, the inner door 42 and the outer door 43 are provided with recesses 44 that are curved to the opposite sides to the opposite surfaces. That is, the inner recess 44I is provided on the surface of the inner door 42 on the outer side B1 in the second direction. An outer recess 44O is provided on the surface of the outer door 43 on the inner side B2 in the second direction. An inner recess handle 45I for opening and closing the inner door 42 is attached to the inner recess 44I. Further, an outer recess handle 45O for opening and closing the outer door 43 is attached to the outer recess 44O. With this configuration, the inner door 42 and the outer door 43 can be slid without interfering with the handle and the door. As the inner concave handle 45I or the outer concave handle 45O, various types such as a lever type and a knob type can be used. Further, the shape of the recess 44 can be made so that the user can easily grasp it by hand. In this case, it is not necessary to provide a handle in the recess 44.

[Other Embodiments]
(1) In each of the above embodiments, the first slide mechanism 5 includes a slide rail 51 extending along the first direction A and a slide body 52 externally inserted into the slide rail 51 and moving along the slide rail 51. And, a plurality of rollable balls interposed between the slide rail 51 and the slide body 52 are rolling along the slide rail 51 inside the slide body 52. , An example of being configured to circulate inside the slide body has been described. However, the first slide mechanism 5 is not limited to such a configuration, and may be configured so that the door 4 can be moved in the first direction A. For example, the first slide mechanism 5 may include a rail and a roller that rolls on the rail.

(2) In the first embodiment described above, an example in which the door 4 is attached to the inside of the chamber 2 has been described. However, the door 4 may be attached to the outside of the chamber 2. In this case, the first slide mechanism 5, the second slide mechanism 6, the guide rail 7 as the guide mechanism, and the seal portion 3 are provided on the outside of the chamber 2. Then, the door 4 presses the seal portion 3 toward the inner side B2 in the second direction when the chamber 2 is depressurized. According to this configuration, the pressure adjusting room 1 can be suitably used for depressurization.

(3) In each of the above embodiments, an example in which the guide mechanism is configured as the guide rail 7 has been described. However, the guide mechanism is not limited to such a configuration, and the guide rail 7 may not be provided. In this case, a protrusion or the like that pushes the guide roller 41 moving along the first direction A in the second direction B can be provided as a guide mechanism. Specifically, the protrusion is arranged at a position slightly deviated from the track on which the guide roller 41 moves along the first direction A to the inner side B2 in the second direction. With such a configuration, the guide roller 41 moving in the first direction A comes into contact with the protrusion, and the guide roller 41 is pushed out to the outer side B1 in the second direction. Therefore, the door 4 can be guided in the second direction B by the protrusion.

(4) In each of the above embodiments, an example in which the door 4 is suspended and supported has been described. However, the present invention is not limited to such a configuration, and the door 4 may not be suspended and supported. In this case, a free bearing may be provided instead of the guide roller 41 having a rotating shaft, and the free bearing may be configured to roll on the bottom surface of the guide rail 7. According to this configuration, since the free bearing can roll on the guide rail 7 in the first direction A and the second direction B, the guide rail 7 guides the door 4 in the first direction A and the second direction B. be able to. Not only that, according to this configuration, since the door 4 is not suspended and supported, the burden on the first slide mechanism 5 and the second slide mechanism 6 that support the door 4 can be reduced.

(5) In each of the above embodiments, an example in which the door 4 is formed in a rectangular shape whose central portion is curved outward has been described. However, the present invention is not limited to such a configuration, and the door 4 may be formed in a flat plate shape when the wall in which the opening 22 is formed in the main body 21 of the chamber 2 is flat. In this case, the weight of the door 4 acts vertically downward, and at normal pressure, the door 4 does not slide inward B2 in the second direction due to the weight of the door 4. Therefore, in this configuration, a spring body that urges the door 4 to the inner side B2 in the second direction is provided in the first slide mechanism 5 or the second slide mechanism 6. When a compression coil spring is used as the spring body, for example, the compression coil spring is fitted onto the connecting shaft 53 of the first slide mechanism 5, and the cushion plate of the first slide mechanism 5 is attached to the end of the outer B1 in the second direction of the compression coil spring. The 55 is arranged so as to be in contact with the middle plate 62 of the second slide mechanism 6 so that the end portion of the inner B2 in the second direction of the compression coil spring is in contact with the spring. According to this configuration, at normal pressure, the door 4 can be urged to the inner side B2 in the second direction by the compression coil spring and slid to the inner side B2 in the second direction. In this case, when the pressing force Pi at the time of pressurization becomes larger than the pushing force of the compression coil spring, the door 4 slides to the outer side B1 in the second direction and presses the seal portion 3. As the spring body, various springs such as leaf springs, torsion coil springs, and tension coil springs can be used.

(6) In addition, when the door 4 is located at the closed position SP, the door 4 may be fastened with a fastener such as a clamp. According to this configuration, the movement of the door 4 in the first direction A can be regulated so that the door 4 does not move in the first direction A when the chamber 2 is transformed. Therefore, the room 2 can be safely transformed.

(7) In addition, a safety valve that opens in an emergency may be provided in the main body 21 of the room 2. According to this configuration, in an emergency such as when the user's condition deteriorates while using the pressure adjustment room 1, the safety valve is opened to communicate the inside and the outside of the room 2 so that the inside of the room 2 can be communicated with each other. Can be under normal pressure.

(8) Each of the above embodiments is merely an example, and the present invention is not limited to each of the above embodiments, and various modifications can be made without departing from the gist thereof. Each of the above embodiments can be combined as long as there is no contradiction.

1: Pressure adjustment room 2: Room 3: Seal part 3I: Inner seal part 3O: Outer seal part 4: Door 5: First slide mechanism 6: Second slide mechanism 7: Guide rail (guide mechanism)
8: Restraint member 14: Seal body 22: Opening 41: Guide roller 42: Inner door 43: Outer door 71: First guide part 72: Second guide part 73: Guide wall 73A: First guide wall 73B: Second Guide wall A: First direction A1: First direction closed side A2: First direction open side B: Second direction B1: Second direction outside B2: Second direction inside

Claims (5)

It is a pressure adjustment room where the inside of the room is transformed.
A seal portion arranged around the opening of the chamber, an open position for opening the opening, a closed position for closing the opening, and a sealed state for sealing the chamber in close contact with the seal portion. A door that can move between the positions of the door, a first slide mechanism that moves the door in the first direction along a path connecting the open position and the closed position, and the closed position. A second slide mechanism for moving the door in a second direction along a path connecting the door and the closed position, and a guide mechanism for guiding the movement of the door are provided.
The guide mechanism is formed with a first guide portion that is formed along the first direction and guides the door in the first direction, and is formed so as to project in the second direction and guides the door in the second direction. It has a second guide portion that guides the door to the seal portion and brings it into close contact with the seal portion.
The door in close contact with the seal portion is configured to press the seal portion due to a pressure change during transformation .
The door has an inner door arranged inside the room and an outer door arranged outside the room.
The inner door and the outer door are pressure adjusting chambers configured to move to the same side when moving in the second direction during transformation . The door has a guide roller that is suspended and supported and can come into contact with the first guide portion and the second guide portion.
The guide mechanism has a guide wall at a position opposite to the seal portion across the guide roller.
The pressure adjustment chamber according to claim 1, wherein the guide roller is configured to roll along the guide wall while being in contact with the guide wall. The first guide portion has a first guide wall formed along the first direction.
The pressure adjustment room according to claim 2, wherein the second guide portion has a second guide wall formed so as to be inclined in the second direction. The pressure adjusting room according to any one of claims 1 to 3 , further comprising a restraining member that covers the outer periphery of the opening. The pressure adjustment room according to any one of claims 1 to 4 , which is configured to pressurize the room by filling the room with oxygen and nitrogen using cylinders provided separately.

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