JP2004244963A - Sliding door device having electromagnetic shielding function - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sliding door device which is simple in structure and positively shields from electromagnetic waves. <P>SOLUTION: The sliding door device has a door frame 500 mounted in an opening of an electromagnetic shielding room, a door main body 600 openably mounted in the door frame 500, a movement support mechanism 700 for supporting the door main body 600 and moving the same for opening/closing operation, and a shielding mechanism 800 for shielding from electromagnetic waves between the door main body 600 and the door frame 500. The movement support mechanism 700 has a mechanism which is deformed downward when the door main body 600 is in a door closed position. According to the shielding mechanism 800, an electromagnetic shielding gasket is arranged in a manner facing a member pressing the same, and at locations above and below the door, the electromagnetic shielding gasket is pressed by the pressing member facing the gasket, according to downward movement of the door main body for shielding from the electromagnetic waves. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a sliding door device having an electromagnetic wave shielding function provided in an opening such as an electromagnetic wave shielding room, and particularly to a sliding door device having an electromagnetic wave shielding function that opens and closes by sliding in an opening.
[0002]
[Prior art]
In recent years, when using equipment that needs to eliminate the influence of external electromagnetic waves such as MRI, or when using equipment that needs to be used while preventing external electromagnetic waves from being emitted, etc. Is used. In this type of electromagnetic wave shield room, there are places where electromagnetic waves are likely to leak. It is a part that requires opening and closing of doorways, windows, and the like. For this reason, conventionally, the window has a door-to-door structure while the window has a fitting-kill structure.
[0003]
However, there are cases where it is desired that the windows can be opened and closed. Also, regarding the doorway, there is a problem that the space within the opening / closing radius of the door becomes a dead space in both cases where the hinged door is opened inside and outside. Therefore, a door having a sliding door structure is desired.
[0004]
However, sliding doors are common as fittings. However, in terms of electromagnetic wave shielding, it is not possible to adopt a structure in which the entire periphery of the door is pressed against the door frame like a hinged door, so that the shielding performance is inferior. Therefore, it is not used as a door of an electromagnetic wave shield room.
[0005]
On the other hand, a door for an electromagnetic wave shield room having a sliding door structure has been proposed (Japanese Patent Application Laid-Open No. 2001-82049: Patent Document 1). This door has a double structure with a first member and a second member connected by a movable mechanism. The door is slidably opened and closed, and when the door is closed, the second member is closed by pressing the second member against the contact edge of the peripheral edge of the doorway. In this technology, the opening and closing part functions as a sliding door, and the sealing part functions as a hinged door, thereby improving the electromagnetic wave shielding function while being a sliding door as a whole.
[0006]
Further, a shielding gasket for preventing leakage of electromagnetic waves at the periphery of the opening has been proposed (US Pat. No. 5,294,270: Patent Document 2). The proposed gasket has a structure in which an outer periphery of a core tube made of an elastic body is covered with a braided heat-treated beryllium copper alloy wire. Since the core of the gasket (wire-mesh gasket) is an elastic body, the gasket can be in close contact with a metal member that comes into contact with the gasket. Therefore, it is suitable to prevent the leakage of the electromagnetic wave at the contact portion of the member.
[0007]
[Patent Document 1]
JP 2001-82049 A
[Patent Document 2]
USP. 5,294,270
[0008]
[Problems to be solved by the invention]
However, such a conventional electromagnetic wave sliding door device has a double structure including a first member and a second member, and a large driving device for increasing the side pressure of the door and a sturdy door frame. Is required, and there is a problem that the structure is complicated and heavy. In addition, the strength of the electromagnetic wave shield room on which such heavy sliding doors are to be mounted must be correspondingly increased. As a result, due to the effective use of space, it is not suitable for small electromagnetic wave shielded rooms where the need for sliding doors is higher.
[0009]
Conventionally, a member called a shield finger has been known as a shield material for a sliding door. This material is thin and easy to break, so it is easy to break during assembly work.It often breaks when opening and closing the door and its service life is relatively short. Problems. Further, since the shielded portion is in sliding contact, there is a problem that a gap is apt to be generated, and electromagnetic waves are likely to leak from the portion.
[0010]
On the other hand, as described above, the wire-mesh gasket proposed by Patent Literature 2 is suitable for a hinged door, but a sliding contact portion such as a sliding door is similar to the shield finger described above. There is a problem that the shielding performance is reduced.
[0011]
SUMMARY OF THE INVENTION An object of the present invention is to provide a sliding door device capable of reliably shielding electromagnetic waves with a simple structure.
[0012]
[Means for Solving the Problems]
According to a first aspect of the present invention,
In a sliding door device having an electromagnetic wave shielding function,
A door frame attached to the opening of the electromagnetic shield room;
A door body that can be freely opened and closed on this door frame,
A movement support mechanism that supports the door body and moves for opening and closing,
A shielding mechanism that performs electromagnetic wave shielding between the door body and the door frame,
The movement support mechanism has a mechanism for displacing downward when the door body is at the door closing position,
The shield mechanism, the electromagnetic wave shielding gasket, disposed to face the member that presses it, and, above the door and below the door, the electromagnetic wave shielding gasket, with the downward displacement of the door body, A sliding door device having an electromagnetic wave shielding function, characterized in that electromagnetic wave shielding is performed by being pressed by the pressing member.
[0013]
Here, the movement support mechanism movably supports the door body by a rail provided on the door frame and an upper hanging vehicle running on the rail,
The mechanism for displacing the door body downward is a notch provided in the rail, and the door body supported by the upper hanging car is displaced downward when the upper hanging car is located in the notch. be able to.
[0014]
Further, the movement support mechanism movably supports the door body by a groove provided in the door frame and a door mechanism having a door wheel that can move along the groove.
The mechanism for displacing the door body downward is digging provided in the groove, and when the door wheel is located in the digging, the door body supported by the door wheel mechanism is displaced downward. Can be.
[0015]
Further, the shield mechanism is arranged such that an electromagnetic wave shielding gasket is disposed at a door tip and a door end of the door body so as to face a member pressing the door, and when the door body is at the door closing position, The electromagnetic wave shield can be configured to be pressed by a pressing member to be pressed.
[0016]
Further, two door bodies can be provided. In that case, the shield mechanism arranges the electromagnetic wave shielding gasket at the door of one of the two door bodies, and arranges a member that presses the gasket at the door of the other door body. It can be configured.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, a sliding door device applied to an entrance, which is a type of opening in an electromagnetic wave shield room, will be described as an example.
[0018]
In the following embodiment, an electromagnetic wave shield room for preventing electromagnetic waves emitted from medical equipment such as a magnetic resonance diagnostic apparatus (MRI), electronic equipment, or the like from leaking out or preventing electromagnetic waves from entering from the outside will be described. It is assumed that. Of course, it is not limited to this.
[0019]
In the following embodiments, an electromagnetic wave shield room that is assembled by a panel or the like is illustrated, but is not limited thereto. Further, the present invention can be applied to a sliding door device installed in an opening when a building itself has a shield structure, an opening in a shield space formed by a tent formed of shielded cloth, and the like. Further, the present invention can be applied not only to the entrance and exit but also to a place where the sliding door device can be adopted in a portion such as a window which needs to be opened and closed.
[0020]
FIG. 1 shows an outline of a sliding door device according to a first embodiment applied to an enclosed electromagnetic wave shield room using a shield panel. The electromagnetic wave shield room shown in FIG. 1 has a shield wall plate 10, a shield ceiling plate 20, and a shield floor member (not shown) assembled to a beam 1 and a frame constituted by a frame structure not shown in the drawing. It is composed. In addition, an entrance 50, a window 40, an air conditioning port 30, and an inspection port 35 are prepared as openings. Here, the doorway 50 is provided with a sliding door device having an electromagnetic wave shielding function, as described later. Other openings are also shielded from electromagnetic waves. The shield wall plate 10 and the shield ceiling plate 20 are entirely or entirely formed of a conductive metal material.
[0021]
2 and 3 show the entire structure of the electromagnetic shielding sliding door device according to the first embodiment of the present invention. FIG. 2 shows a state in which the door is closed, and FIG. 3 shows a state in which the door is opened. In FIGS. 2 and 3, some of the members that should be on the inner peripheral side of the door frame 500 and the outer peripheral side of the door body 600 are shown in a state where some of the members should be removed so that the existence of the shield mechanism can be understood.
[0022]
The sliding door device of the present embodiment includes a door frame 500, a door body 600 attached thereto, a hanging movement support mechanism 700 that movably suspends the door body 600 in the door frame 500, a door body 600, and a door. And a shield mechanism 800 that shields electromagnetic waves from the frame 500. The sliding door device of the present embodiment is an example of a single door in which a door body 600 is disposed outside a shielded electromagnetic wave room in a door frame 500. That is, a half portion (the left half shown in FIG. 2) of the door frame 500 in the horizontal direction is the opening 51, and the other half (the right half shown in FIG. 2) is formed by the shield wall panel 10. It is closed.
[0023]
The door frame 500 includes a doorside frame member 510, an intermediate frame member 520, an upper frame member 530, a lower frame member (shoot rail) 540, and a door end side frame member 550. As described above, the shield wall plate 10 is attached to a region sandwiched between the intermediate frame member 520 and the door bottom frame member 550. Each of the frame members 510 to 550 and the shield wall plate are formed of a conductive material, for example, a metal such as iron or an iron alloy. The material may be any material as long as it can block electromagnetic waves in the frequency range for the purpose of blocking, and can make electrical contact with other members without gaps. Therefore, even if the surface of the metal has an insulating oxide film, for example, aluminum, an aluminum alloy, etc., it is important to note that the oxide film on the surface is insulative, and that the electromagnetic waves are cut off when the members are connected. Can be used where possible.
[0024]
As shown in FIGS. 4 and 5, the door-side member 510 is provided with a step portion 511 for accommodating the door-side shield mechanism 810. Also, as shown in FIGS. 12 and 13, the upper frame member 530 is similarly provided with a step portion 531 for accommodating the upper shield mechanism 830. The intermediate frame member 520 is connected to the upper frame member 530 and the lower frame member 540 by a fixing tool. FIGS. 14 and 15 show a state in which the bottom surface of the intermediate frame member 520 is connected and fixed to the lower frame member 540 by the fixtures 522 (bolts 522a and nuts 522b). The lower frame member 540 forms a shoe rub. In the present embodiment, rails and guides are not provided to make the entrance 51 barrier-free.
[0025]
As shown in FIGS. 2 and 3, the door body 600 attached to the door frame 500 faces the door tip 610 facing the door tip member 510 of the door frame 500 and the door end member 550, and at the time of closing the door. It has a door end 620 adjacent to the intermediate frame member 520, an upper end 630 facing the upper frame member 530 and suspended by the suspension movement support mechanism 700, and a lower end 640 facing the lower frame member 540. A region surrounded by the door tip 610, the door bottom 620, the upper end 630, and the lower end 640 is covered with the conductor plate 660. A pull 650 is attached to a part of the conductor plate 660. The pulls 650 are provided on both sides of the door body 600. The door body 600 is made of a conductive material, specifically, a metal, similarly to the door frame 500 described above.
[0026]
A rubber projection 615 for personal protection is attached to an end face of the door tip 610 by an attachment portion 614. In addition, a rubber sound insulation plate 647 is attached to the lower end 640, for example.
[0027]
Next, the hanging movement support mechanism 700 for hanging the door body 600 will be described with reference to FIGS. 2, 3, 12, and 13. FIG. The suspension movement support mechanism 700 includes a rail 710 attached to the upper frame member 530 of the door frame 500 and an upper suspension wheel 750 attached to the upper end 630 of the door body 600. The hanging movement support mechanism 700 functions as a means for movably supporting the door body 600 and a means for displacing the door body 600 downward when the door body is closed. Due to such a downward displacement, in the upper shield mechanism 830 and the lower shield mechanism 840 that extend in a direction parallel to the moving direction of the door body 600, it is possible to realize pressure contact by pressing instead of sliding contact with the shield gasket. . As a result, it is possible to further reduce the leakage of the electromagnetic wave at that portion.
[0028]
The rail 710 is attached to a surface 532 above the step portion 531 of the upper frame member 530 and outside the electromagnetic wave shield room. The rail 710 has a flat portion 711 for smoothly moving the door body 600 from the door to the door ass, a notch 712 provided near the door, and a portion near the intermediate frame member 520. The provided notch portion 713 is provided. The notch 712 on the door tip side is provided with an inclined portion 714 that is inclined toward the door tip. Thereby, the suspension pulley 751 of the upper suspension wheel 750 can move to the notch 712 smoothly. Note that the notch 713 is provided in a concave shape on a curve.
[0029]
A mounting plate 717 is provided on the rail 710 in parallel and integrally. The mounting plate 717 is fixed to the upper frame member 530 using a fixing tool 720 such as a bolt.
[0030]
The upper suspension wheel 750 includes a suspension pulley 751 for traveling on the rail 710, a shaft 752 for rotatably supporting the suspension pulley 751, a support plate 753 for fixing the shaft 752, and a support plate 753. A fixing device 755 (bolt 755a, nut 755b) for fixing the fixing portion 754 to the upper end 630 of the door body 600 is provided. The support plate 753 is fixed to the door main body 630 by a fixing tool 755 at the fixing portion 754. Accordingly, the door main body 600 is supported by the support plate 753, the shaft 752, and the suspension pulley 751 in a form suspended from the rail 710.
[0031]
The depth of the notches 712 and 713 is determined to be a length that can secure a pressing stroke for reliably performing shielding by pressing in an upper end shield mechanism 830 and a lower end shield mechanism 840 described later when the door is closed. . Further, when the suspension pulley 751 is on the flat portion 711 of the rail 710, the height of the flat portion 711 in the upper end shield mechanism 830 and the lower end shield mechanism 840 is set so that the shield is released by pressing. Is set.
[0032]
The structure described above is a basic structure of a sliding door. In the present embodiment, the sliding mechanism is provided with a shield mechanism 800. In the case of the present embodiment, the shield mechanism 800 is arranged on the outer periphery of the door body 600 and the inner side of the door frame 500 surrounding it. Specifically, a door end shield mechanism 810 disposed on the door end side, a door end shield mechanism 820 disposed on the door end side, an upper end shield mechanism 830 disposed on the upper end side of the door, and a lower end side of the door And a lower end shield mechanism 840 to be arranged. Each of these shield mechanisms 810, 820, 830, and 840 is composed of a member attached to the door frame side and a member attached to the door body side. Each of these members has a structure that prevents electromagnetic wave leakage at the contact portion by being pressed.
[0033]
As shown in FIGS. 4 and 5, the door shield mechanism 810 includes a member provided on the door frame 510 and a member provided on the door 610 of the door body 600.
[0034]
On the side of the door-side frame member 510, a gasket accommodating member 815 is fixed to a step portion 511 provided on the door-end frame member 510 by a fixture 817 together with a mounting reinforcing plate 816. The gasket accommodating member 815 is made of a channel material. The gasket accommodating member 815 is mounted on the step portion 511 such that the channel opening accommodates the door 610. Electromagnetic wave shielding gaskets 811a and 811b are arranged to face each of the inner walls of the gasket housing member 815 facing each other. A band-shaped electromagnetic wave shielding gasket 814 is arranged at the bottom of the gasket accommodating member 815. The electromagnetic wave shielding gasket 814 has a thickness that can be pressed against the gaskets 811a and 811b when the door body 600 is closed and the electromagnetic wave shielding gaskets 811a and 811b are deformed. Is arranged. The electromagnetic wave shielding gaskets 811a and 811b and the electromagnetic wave shielding gasket 814 are, of course, made of a material capable of blocking electromagnetic waves. Further, they have elasticity and easily elastically deform when pressed. Of course, when the pressure is released, it returns to its original shape.
[0035]
The gaskets 811a and 811b are provided with attachment portions 812a and 812b, respectively. These mounting portions 812a and 812b are mounted on the wall surface of the gasket housing member 815 by clamp members 813a and 813b, respectively. The distance between the opposing electromagnetic shielding gaskets 811a and 811b is determined so that the contact plates 861a and 861b, which are members of the door side 610 described later, can press-contact the corresponding gaskets 811a and 811b, respectively. Specifically, for example, the interval is determined to be shorter than the thickness of the door body 600 at the door tip 610.
[0036]
The gaskets 811a and 811b for electromagnetic wave shielding specifically have a structure as shown in FIG. That is, itself is formed in a cylindrical shape, and a mounting portion 812 is provided in a part thereof. The mounting portion 812 is mounted with an upper body extending along the axial direction of the gasket 811 and tangentially. To illustrate a typical size of the gasket, the height, that is, the diameter H of the gasket is 12.70 mm, and the maximum width W including the diameter of the mounting portion 812 and the gasket is 25.40 mm. The length is a length determined at the time of manufacturing, and is used after being cut to a required length.
[0037]
The electromagnetic shielding gaskets 811a and 811b are formed by covering an elastic elastomer core with a wire shielding made of a beryllium copper alloy wire. In the present embodiment, a shielding product manufactured by Instrument Specialties is used. The technology related to this product is disclosed in Patent Document 2 mentioned above.
[0038]
The electromagnetic wave shielding gasket 814 is formed, for example, by covering a band-shaped elastomer having elasticity with a wire shielding knitted with a beryllium copper alloy wire. In the present embodiment, it is not hollow, but may have a hollow structure. Further, the elastomer itself may have conductivity.
[0039]
On the other hand, on the door tip 610 side, contact plates 861a and 861b for contacting the electromagnetic shielding gaskets 811a and 811b, an attachment reinforcing plate 864 for reinforcing the contact plate when attached to the door tip, and a contact plate 861a , 861b to the door top 610. The contact plates 861a and 861b are
It has contact portions 863a and 863b formed by bending the distal end side, and contact portions 862a and 862b that are inclined inward so as to narrow the gap toward the distal end side. The contact portions 863a and 863b first contact the electromagnetic shielding gaskets 811a and 811b when the door is closed, and act to expand the gap. The contact portions 862a and 862b are in pressure contact with the electromagnetic wave shielding gaskets 811a and 811b when the door is closed and thereafter, and apply the force acting on the door closing direction received from the door body 600 in the door closing direction and the direction orthogonal to the door closing direction. And the pressing force in each direction is generated. Thereby, it is possible to make pressure contact with the electromagnetic wave shielding gaskets 811a and 811b even at a portion which is originally in sliding contact. Therefore, the electromagnetic wave shield can be reliably performed.
[0040]
As shown in FIG. 5, the electromagnetic shielding gaskets 811a and 811b and the contact plates 861a and 861b are in a non-contact state after the door is opened or before the door is completely closed. At this time, the electromagnetic wave shielding gaskets 811a and 811b have a cylindrical shape and are arranged to face each other. At this time, the shortest distance between the electromagnetic wave shielding gaskets 811a and 811b is shorter than the width of the door tip 610.
[0041]
Next, immediately before the door closing is completed, the door tip enters the opening of the gasket housing member 815. As a result, the contact portions 863a and 863b of the contact plates 861a and 861b press while contacting the electromagnetic wave shielding gaskets 811a and 811b, and act to expand the gap therebetween. Then, the contact portions 862a and 862b come into contact with the electromagnetic wave shielding gaskets 811a and 811b, and the component force of the force received from the door main body 600 in the traveling direction X of the door main body 600 and the Y direction orthogonal thereto. The generated gaskets 811a and 811b are pressed in both the X direction and the Y direction. Therefore, the contact portions 862a and 862b corresponding to the electromagnetic wave shielding gaskets 811a and 811b respectively press in both the X direction and the Y direction. Therefore, reliable contact can be realized in this portion. When the door is opened, the electromagnetic shielding gaskets 811a and 811b return to their original shapes due to elasticity, as shown in FIG.
[0042]
In addition, the electromagnetic shielding gaskets 811a and 811b are deformed due to the pressing by the contact plates 861a and 861b, and a part thereof comes into contact with the electromagnetic shielding gasket 814, and this part also blocks the leakage of the electromagnetic waves.
[0043]
The electromagnetic shielding gaskets 811a and 811b have a property that the electromagnetic shielding performance increases as the pressure (compression) increases. Therefore, the contact surfaces with the contact portions 862a and 862b are formed so as to be crimped in conformity with the operation requirements. The same applies to the gasket for shielding electromagnetic waves in other parts described later.
[0044]
Next, another example in which the door end shield mechanism 810 is realized with a simpler structure will be described. As shown in FIGS. 6 and 7, in the door shield mechanism 810, most of the main members are arranged on the door frame 510 side. In the case of this example, attachment of the rubber projection 615 for personal protection to the door tip 610 is omitted.
[0045]
On the side of the door-side frame member 510, a gasket housing member 819 is fixed to a step portion 511 provided on the door-end frame member 510 by a fixture 817. The gasket accommodating member 819 is made of a channel material. The gasket accommodating member 819 is mounted on the step portion 511 such that the channel opening accommodates the door 610. Electromagnetic wave shielding gaskets 811 a and 811 b are arranged on the inner walls of the gasket housing member 819 facing each other, facing the end surface 611 of the doortip 610. The same gaskets 811a and 811b for electromagnetic wave shielding as those shown in FIGS. 4 and 5 described above can be used. These electromagnetic wave shielding gaskets 811a and 811b are attached to support plates 818 attached to inner wall surfaces of the gasket accommodating member 819, with attachment portions 812a and 812b fixed by clamps 813a and 813b, respectively. Each of the support plates 818 is an angle member, and is fixed to the gasket accommodating member 819 by a fixture 817.
[0046]
According to the door shield mechanism 810, the electromagnetic wave shielding gaskets 811a and 811b and the door tip surface 611 are in a non-contact state after the door is opened or before the door is completely closed as shown in FIG. Therefore, the electromagnetic shielding gaskets 811a and 811b have a cylindrical shape and are in a state of facing the door tip surface 611.
[0047]
Next, just before the door is closed, the door 610 approaches the opening of the gasket accommodating member 815. As a result, as shown in FIG. 6, the door tip surface 611 presses the electromagnetic wave shielding gaskets 811a and 811b while being in contact therewith. Thereby, reliable contact can be realized in this portion. When the door is opened, as shown in FIG. 7, the electromagnetic shielding gaskets 811a and 811b return to their original shapes due to elasticity.
[0048]
Although this structure is very simple, the electromagnetic wave shielding gaskets 811a and 811b are pressed by the pressing by the door front end surface 611, so that the leakage of the electromagnetic wave can be surely suppressed.
[0049]
In this shield structure, an electromagnetic wave shield is formed between the door tip 610 and the door frame member 510 by compressing the electromagnetic wave shielding gaskets 811a and 811b by the door tip surface 611. This can be adopted when the repulsive force of the cylindrical electromagnetic wave shielding gasket used is low, or when the mass of the door body is large. Therefore, there is no need to attach a tapered plate or a rubber projection for protecting persons against the door 610.
[0050]
However, if the door is automatically opened and closed, a door switch will be installed. Further, since the front surface of the door tip directly compresses the electromagnetic wave shielding gasket, the load applied to the gasket is small, so there is little damage, and there are many advantages such as little replacement.
[0051]
Next, a shield structure of the door end portion of the electromagnetic wave shielding mechanism 800 will be described with reference to FIGS. FIG. 9 shows a state in which the door is closed, and FIG. 9 shows a state in which the door is opened (or a state before the door is completely closed).
[0052]
As shown in FIGS. 8 and 9, the door bottom shield mechanism 820 includes a member provided on the intermediate frame member 520 side and a member provided on the door bottom 620 side of the door body 600.
[0053]
On the intermediate frame member 520 side, gasket support plates 825a and 825b are attached to a surface facing the door frame member 510 by a fixture 826. Each of the gasket support plates 825a and 825b is formed of an angle member. Then, they open in the direction of the door end and constitute a channel functioning as a gasket accommodating portion. In this channel, electromagnetic wave shielding gaskets 821a and 821b are attached to gasket support plates 825a and 825b, respectively. Each of the gaskets 821a and 821b has the above-described structure shown in FIG. Therefore, duplicate description will be omitted. That is, the mounting portions 822a and 822b are fixed to the gasket support plates 825a and 825b by the clamp members 823a and 823b, respectively. The space between the opposing electromagnetic shielding gaskets 821a and 821b is determined to be a length that allows a contact plate 871, which is a member on the side of the door butt 620 described later, to be in pressure contact with the corresponding gaskets 821a and 821b. Specifically, for example, the interval is determined to be shorter than the thickness of the door body 600 at the door end 620.
[0054]
On the other hand, a contact plate 871 for contacting the electromagnetic wave shielding gaskets 811a and 811b, a support plate 872 for supporting the contact plate 871, and reinforcement for attaching the support plate 872 to the door butt 620 are provided on the door bottom 620 side. An electromagnetic wave shielding gasket 875 is disposed in a space between the contact reinforcing plate 873 and the fixing plate 874 for attaching the support plate 872 to the door end 620 and the contact plate 871 and the door end 620. This electromagnetic wave shielding gasket 875 has the same configuration as the electromagnetic wave shielding gasket 814 described above. The gasket 875 comes into contact with the tip 825c of the gasket support plate 825b when the door is closed. Each of these members is formed of a conductive material, for example, a metal.
[0055]
The contact plate 871 has a groove structure with a V-shaped tip. The outer surface presses the electromagnetic wave shielding gaskets 821a and 821b to block electromagnetic wave leakage.
[0056]
As shown in FIG. 9, the electromagnetic wave shielding gaskets 821a and 821b and the contact plate 871 are in a non-contact state after the door is opened or before the door is completely closed. At this time, the electromagnetic wave shielding gaskets 821a and 821b have a cylindrical shape and are arranged to face each other. At this time, the shortest distance between the electromagnetic shielding gaskets 821a and 821b is shorter than the width of the contact plate 871.
[0057]
Next, immediately before door closing is completed, the contact plate 871 enters the space between the gasket support plates 825a and 825b. As a result, the tip of the contact plate 871 is pressed while being in contact with the electromagnetic shielding gaskets 821a and 821b, and acts to widen the gap therebetween. Then, the contact portion 871 comes into contact with the electromagnetic wave shielding gaskets 821a and 821b and presses them until they are elastically deformed. Therefore, reliable contact can be realized in this portion. When the door is opened, as shown in FIG. 9, the electromagnetic shielding gaskets 821a and 821b return to their original shapes due to elasticity.
[0058]
Also, the electromagnetic wave shielding gasket 875 is deformed due to the pressing by the distal end 825c of the gasket support plate 825b, and a part of the gasket 875 comes into contact with the electromagnetic wave shielding gasket 875 to cut off the electromagnetic wave leakage at this part. .
[0059]
As described above, the door bottom shield mechanism 820 of the present embodiment uses the displacement in the same direction as the moving direction of the door body when the door is closed, and presses the electromagnetic wave shielding gaskets 821a and 821b in a manner of expanding the gap. To ensure the contact pressure. Similarly, the electromagnetic wave shielding gasket 875 also contacts the electromagnetic wave shielding gasket 875 and makes use of the displacement in the same direction as the moving direction of the door body when the door is closed, so that a large contact pressure is secured. ing. Therefore, as well as the door to be pressed, a reliable electromagnetic wave shield is realized also at the door bottom. When the door is opened, as shown in FIG. 9, the electromagnetic shielding gasket 875 returns to its original shape due to elasticity.
[0060]
Next, another example in which the door bottom shield mechanism 820 is realized with a simpler structure will be described. As shown in FIGS. 10 and 11, in the door end shield mechanism 820, members for shielding are arranged on the intermediate frame member 520 side and the door end 620 side.
[0061]
A gasket support plate 825b is fixed to the intermediate frame member 520 by a fixture 826. Electromagnetic wave shielding gaskets 821c and 821d are attached to the gasket support plate 825b on the side facing the door end frame member 530 by a clamp member 823 at an attachment portion 822c.
[0062]
A pressing plate 876 supported by a fixing member 878 on the support plate 872 is attached to the door bottom 620 side. Further, the same electromagnetic wave shielding gasket 875 as described above is arranged on the support plate 872.
[0063]
As shown in FIGS. 11 and 27, the electromagnetic wave shielding gaskets 821c and 821d are arranged in parallel in a double state, and are integrally connected via a mounting portion 822c. That is, similarly to the above-described electromagnetic wave shielding gaskets 811a and 811b, these are formed by integrating an elastomer core with a mounting portion 822c as a connecting portion, and covering a wire shielding made of a beryllium copper alloy wire. You.
[0064]
According to the door bottom shield mechanism 820, the electromagnetic wave shielding gaskets 821c and 821d and the pressing plate 876 are in a non-contact state after the door is opened or before the door is completely closed as shown in FIG. Therefore, the electromagnetic shielding gaskets 821c and 821d have a cylindrical shape, and are in a state of facing the pressing plate 876. Next, immediately before door closing is completed, the pressing plate 876 approaches the electromagnetic wave shielding gaskets 821c and 821d. Thereafter, as shown in FIG. 10, the pressing plate 876 presses the electromagnetic wave shielding gaskets 821c and 821d while being in contact therewith. Thereby, reliable contact can be realized in this portion. When the door is opened, as shown in FIG. 11, the electromagnetic shielding gaskets 821c and 821d return to their original shapes due to elasticity.
[0065]
According to this shield mechanism, since the structure is simple and sufficient contact can be performed by the pressing force, the electromagnetic wave shielding effect is also high.
[0066]
Next, the shield structure at the upper part of the door of the electromagnetic wave shield mechanism will be described with reference to FIGS. FIG. 12 shows a state in which the door is closed, and FIG. 13 shows a state in which the door is opened (or a state before the door is completely closed).
[0067]
As shown in FIGS. 12 and 13, in this state shield mechanism 830, members for shielding are arranged on the upper frame member 530 side and the door butt 620 side.
[0068]
A gasket support plate 835 is fixed to the upper frame member 530 by a fixture 836. On the side of the gasket support plate 835 facing the lower frame member 540, electromagnetic wave shielding gaskets 831a and 831b are attached by clamp members 833 at attachment portions 832.
[0069]
On the upper end 630 side, together with the mounting reinforcing plate 632, a pressing plate 881 is attached to the door body 600 near the upper end by a fixture 882.
[0070]
The electromagnetic wave shielding gaskets 831a and 831b have the same structure as the electromagnetic wave shielding gaskets 821c and 821d, as shown in FIGS. Since this has already been described, the description is omitted here.
[0071]
According to the upper end shield mechanism 830, the electromagnetic wave shielding gaskets 831a and 831b and the pressing plate 881 are in a non-contact state after the door is opened or before the door is completely closed as shown in FIG. Therefore, the electromagnetic shielding gaskets 831a and 831b have a cylindrical shape and are in a state of facing the pressing plate 881. Next, immediately before the door is closed, the pressing plate 881 approaches the electromagnetic shielding gaskets 831a and 831b. Thereafter, as shown in FIG. 12, the pressing plate 881 presses the electromagnetic wave shielding gaskets 831a and 831b while being in contact therewith. Thereby, reliable contact can be realized in this portion. When the door is opened, as shown in FIG. 13, the electromagnetic shielding gaskets 831a and 831b return to their original shape due to elasticity.
[0072]
In the shield mechanism 830, when the door body 600 reaches the door closing position, the suspension pulley 751 falls into the notches 712 and 713 provided on the rail 710. Thereby, the door main body 600 is displaced downward. With the downward displacement, the pressing plate 881 is displaced downward. As a result, the pressing plate 881 presses the electromagnetic shielding gaskets 831a and 831b supported by the support plate 835. Moreover, as long as the door-closed state continues, the pressing of the pressing plate 881 continues, so that a stable close contact state can be ensured. Therefore, since the structure is simple and sufficient contact can be performed by pressing force, a high electromagnetic wave shielding effect can be obtained.
[0073]
Next, the shield structure at the lower part of the door of the electromagnetic wave shield mechanism will be described with reference to FIGS. FIG. 14 shows a state in which the door is closed, and FIG. 15 shows a state in which the door is opened (or a state before the door is completely closed). As shown in FIGS. 14 and 15, the lower end shield mechanism 840 is disposed at the lower end 640 of the door main body 600.
[0074]
At the lower end 640, support plates 845a and 845b are fixed together with a mounting reinforcing member 844 by a fixture 846. In addition, a sound insulating plate 647 is attached.
[0075]
Electromagnetic wave shielding gaskets 841a and 841b are attached to support plates 845a and 845b by clamp members 843a and 843b at attachment portions 842a and 842b. Electromagnetic wave shielding gaskets 841a and 841b are arranged to face the upper surface of lower frame member 540. The same electromagnetic wave shielding gaskets 841a and 841b as those shown in FIGS. 4 and 5 can be used.
[0076]
According to this lower end shield mechanism 840, the electromagnetic wave shielding gaskets 841a and 841b and the lower frame member 540 upper surface 541 are in a non-contact state after the door is opened or before the door is completely closed as shown in FIG. . Therefore, the electromagnetic wave shielding gaskets 841 a and 841 b have a cylindrical shape and are in a state of facing the lower frame member 540 ridge surface 541.
[0077]
Next, immediately before the door is closed, the lower end 640 of the door body 600 approaches the upper surface 541 of the lower frame member 540. As a result, as shown in FIG. 14, the electromagnetic shielding gaskets 841a and 841b supported by the support plates 845a and 845b contact and press the upper surface 541 of the lower frame member 540. Thereby, reliable contact can be realized in this portion. When the door is opened, as shown in FIG. 15, the electromagnetic shielding gaskets 841a and 841b return to their original shapes due to elasticity.
[0078]
In this shield mechanism 840, when the door body 600 reaches the door closing position, the suspension pulley 751 falls into the notches 712 and 713 provided on the rail 710. Thereby, the door main body 600 is displaced downward. At this time, the downward displacement causes the electromagnetic wave shielding gaskets 841a and 841b supported by the support plates 845a and 845b to be pressed against the upper surface 541 of the lower frame member 540. In addition, as long as the door-closing state continues, this pressure contact continues, so that a stable close contact state can be ensured. Therefore, since the structure is simple and sufficient contact can be performed by pressing force, a high electromagnetic wave shielding effect can be obtained.
[0079]
The electromagnetic shielding function of the sliding door device according to the present embodiment having the above-described structure will be described together with its operation.
[0080]
First, as shown in FIG. 1, the sliding door device of the present embodiment includes a door frame 500 and a door body 600, and the door frame 500 is connected to an electromagnetic wave shielding room so as to obtain an electromagnetic wave shield, and It is used when carrying in and out and carrying equipment. During use of the electromagnetic wave shielding room, the door body 600 is closed, and the contact portion between the door frame 500 and the door body 600 is shielded by the electromagnetic wave shielding mechanism 800 (see FIG. 2) that exhibits electromagnetic wave shielding performance suitable for operation requirements. ing. For this reason, the electromagnetic shielding performance is enhanced by using a cylindrical soft and elastic electromagnetic shielding gasket 811 or the like at the contact portion. Since this electromagnetic wave shielding gasket has a property that the electromagnetic wave shielding performance increases as the pressure (compression) is increased, each contact surface of the door is formed so as to be crimped in conformity with operation requirements. The contact surfaces are the door tip, the door bottom, the upper door, and the lower door.
[0081]
By the way, since the initial operation of the operation of opening the sliding door is an operation of lifting the hanging pulley 751 from the notches 712 and 713, the weight is manually reduced using a kicker or the like. With this operation, the electromagnetic wave shields related to the door are simultaneously opened. On the other hand, when the door is dropped into the groove, a braking device such as an air cushion or a rubber stopper is required to close the sliding door because the door is light and slippery due to the action of the suspension pulley 751. However, in the case of automatic opening / closing by evangelism, braking by forced rotation of the motor is applied, so that it is unnecessary. Also, the slanting drop of the door becomes a force for inserting the slant, and after dropping, the hanging pulley 751 falls to the notches 712 and 713. The insertion pressure and the compression pressure are maintained.
[0082]
In the above-described embodiment, the reason why the cylindrical shield gasket is used as the shield member is as follows. That is, as this kind of shield gasket, as a shield material for the gap between the doors, it is easy to mount and fit into the door frame, and many have a desired shielding performance. However, when the door is closed, the repulsive force due to its compression is strong, and in the case of a sliding door, there are problems that a large force is required for closing and that many doors cannot be employed because the closing cannot be maintained. In this regard, in the above-described embodiment, since the door body 600 is displaced downward by using the notch of the rail, it is easy to maintain the door closed state against the repulsive force.
[0083]
As described above, according to the present embodiment, the following effects can be obtained.
(1) The electromagnetic wave shielding sliding door device of the present embodiment does not require a large driving device for electromagnetic wave shielding, and can be adopted in a small electromagnetic wave shielding room such as a hospital or a research laboratory. Moreover, since the door is a sliding door, a space for opening and closing the door is unnecessary, so that the room can be used widely.
(2) Doors used for human entry and exit have many opportunities to come into contact with people, including their surroundings, and the use of exposed sharp members is inappropriate, but the cylindrical electromagnetic shielding gasket itself has roundness and elasticity. There is a higher safety. In addition, the contact plate used in the door-end shield mechanism has a flat bent tip and a tapered portion, which enhances safety for humans and smooth insertion between gaskets, Scratching is also eliminated, so that the service life of the gasket is not shortened.
[0084]
On the other hand, if an electromagnetic wave shielding gasket that can be compressed without applying a large force is used, the compression plate at the door tip and the door end can be made flat, further enhancing safety for people and extending the service life of the gasket. Can be done.
(3) By adopting the cylindrical electromagnetic wave shielding gasket, installation at the time of assembling the door or exchanging members is easy. In addition, the transportation and storage of the maintenance member are also facilitated. For this reason, maintenance is excellent. In the door shield, the contact plate has a taper. For this reason, when the gasket is inserted between the electromagnetic wave shielding gaskets, the gasket is deformed and compressed in a direction away from the taper, so that the sliding frictional force is reduced and the service life is extended.
(4) Since the lower frame member (shoot rail) can be flattened, it is free from the inconvenience of entering and leaving due to steps and slopes, and the dirt of the shoe rail from grooves.
(5) Since the door is a sliding door, an automatic door can be obtained by attaching a relatively small electric drive device to the upper part of the door frame while utilizing the characteristics of the electromagnetic wave shield.
[0085]
In the above-described embodiment, the example in which the door main body 600 is provided outside the electromagnetic wave shield room shown in FIG. 2 has been described. The present invention is not limited to this. The door frame 500, the door body 600, and the suspension movement support mechanism 700 can be configured to be attached from the inside of the electromagnetic wave shield room. That is, for example, it can be configured such that FIGS. 1 and 2 are viewed from the inside of the electromagnetic wave shield room.
[0086]
Further, the hanging movement support mechanism 700 is arranged inside and outside the electromagnetic wave shielding room of the door frame 500, and the door body 600 is attached symmetrically to each other, whereby a two-door structure can be obtained. Furthermore, a two-door sliding door device that opens left and right can also be used.
[0087]
16 to 25 show an example thereof. Hereinafter, a second embodiment of the present invention applied to a double door will be described. In the present embodiment, the same components as those in the above-described embodiment are denoted by the same reference numerals, and redundant description will be omitted. Therefore, the following description focuses on differences from the first embodiment described above.
[0088]
16 and 17 show the overall structure of a two-door electromagnetic shield sliding door device according to a second embodiment of the present invention. FIG. 16 shows a state in which the door is closed, and FIG. 17 shows a state in which the door is opened (or a state before the door is completely closed). In FIGS. 16 and 17, parts that should be on the inner peripheral side of the door frame 500 and the outer peripheral side of the door main body 600 are partially deleted so that the existence of the shield mechanism can be seen. In addition, in the present embodiment, since the left and right door main bodies 600L and 600R are provided, if it is necessary to distinguish between the left and right doors, the symbols of L and R will be assigned.
[0089]
The sliding door device according to the present embodiment includes a door frame 500, left and right door bodies 600L and 600R attached thereto, a movement support mechanism 900 that movably supports the door bodies 600L and 600R within the door frame 500, and a door. It has a shield mechanism 800 that shields electromagnetic waves between the main bodies 600L and 600R and the door frame 500. The sliding door device of the present embodiment is an example of a two-door system in which door bodies 600L and 600R are arranged outside a shielded electromagnetic wave room in a door frame 500. That is, a half of the center in the horizontal direction of the door frame 500 is the opening 51, and the other quarters are closed by the shield wall panel 10.
[0090]
The door frame 500 has intermediate frame materials 520L and 520R, an upper frame material 530, a lower frame material (shootsuri) 540, and a door end side frame material 550L and 500R. As described above, the shield wall plate 10 is attached to a region sandwiched between the intermediate frame member 520L and the door butt frame member 550L and a region sandwiched between the intermediate frame member 520R and the door butt frame member 550R. . The intermediate frame members 520L, 520R, the upper frame member 530, the lower frame member (shootsuri) 540, and the door end side frame members 550L, 500R, and the shield wall plate 10 are each made of a conductive material, for example, iron. , And a metal such as an iron alloy. The materials are the same as in the first embodiment.
[0091]
As shown in FIGS. 16 and 17, the door body 600L (600R) faces the door tip 610R (610L) of the other door body 600R (600L), and contacts the door tip 610L (610R) when the door is closed. The door butt member 550L (550R) is opposed to the door butt 620L (620R) adjacent to the intermediate frame member 520L (520R) and the upper frame member 530 when the door is closed. It has an upper end 630L (630R) and a lower end 640L (640R) that is opposed to the lower frame member 540 and is movably supported. A region surrounded by the door tip 610L, the door bottom 620L, the upper end 630L, and the lower end 640L is covered with the conductor plate 660. Similarly, a region surrounded by the door tip 610R, the door bottom 620R, the upper end 630R, and the lower end 640R is covered with the conductor plate 660. Further, a pull 650 is attached to a part of the conductor plate 660. The pulls 650 are provided on both sides of the door body 600. The door body 600 is made of a conductive material, specifically, a metal, like the door body 600 described above.
[0092]
The movement support mechanism 900 in the present embodiment is divided into a lower frame member 540 side and an upper frame member 530 side. On the lower frame member 540 side, as shown in FIGS. 24 and 25, a groove 911 provided in the lower frame member 540 and a door wheel mechanism 920 that moves along the groove 911 are provided. On the other hand, the upper frame member 930 is provided with an opening / closing mechanism 930 as shown in FIGS.
[0093]
The groove 911 is provided on the surface of the lower frame member along the opening and closing directions of the door bodies 600L and 600R, as shown in FIGS. In this groove 911, the door bodies 600L and 600R abut the respective door tips 610L and 610R doors, and when the doors are closed, house the door wheel 921 and displace the door bodies 600L and 600R downward. Digging 912 is provided. The digging 912 has an inclination because the door wheel 921 is smoothly displaced.
[0094]
As shown in FIGS. 24 and 25, the door mechanism 920 includes a mounting frame member 924 fixed to the lower end of the door body 600, a door 921, a shaft 922 for supporting the door rolling freely, and a shaft And a fixture 923 for fixing to the member 924. The door wheel 921 runs in the groove 911.
[0095]
The opening / closing mechanism 930 includes a toothed belt 934, toothed pulleys 931 </ b> L and 931 </ b> R that mesh with the toothed belt 934 to rotate the belt, and torque transmission plates 941 and 946 fixed to the toothed belt 934.
[0096]
The toothed pulleys 931L and 931R are attached to the upper frame member 530. FIGS. 20 and 21 show 931R, but the same applies to 931L. Now, the toothed pulley 931R is fixed and supported on the shaft 932R. The shaft 932R is rotatably attached to the upper frame member 530 via a bearing 933R. It should be noted that a power source can be connected to one of the toothed pulleys 931L and 931R, a motor can be connected, and the pulley can be automatically opened and closed.
[0097]
The torque transmission plate 941 is fixed on the upper side of the parallel part of the toothed belt 934. On the other hand, the torque transmission plate 946 is fixed on the lower side of the parallel portion of the toothed bell. By fixing in this manner, when one of the left and right door bodies 600L and 600R is pulled, the belt 934 is displaced so as to rotate around the belt 934 via the torque conducting plate 941. As a result, the belt is displaced around. Along with that,
The other torque conducting plate 946 will be pulled in the opposite direction.
[0098]
The toothed belt 934 is integrally provided with a base portion 934a that is closed in an annular shape and teeth 934b attached to the base portion.
[0099]
By fixing the transmission plate 941 at the upper part and the transmission plate 946 at the lower part of the torque transmission plates 941 and 946, the torque transmission plates 941 and 946 can be configured to move in opposite directions. The torque transmission plate 941 and the toothed belt 934 are fixed by fixing a part of the toothed belt 934 to a fixing portion 942 provided on the torque transmission plate 941. Further, the torque transmission plate 946 and the toothed belt 934 are fixed by fixing another part of the toothed belt 934 to a fixing portion 947 provided on the torque transmission plate 946.
[0100]
In the example shown in FIGS. 20 and 21, a guide groove 951 is attached to the upper end of the door main body 600, and is disposed in the guide groove 951 so as to rotate with the movement of the door main body 600. A guide roller 953 that regulates the inclination of the door against swinging of the door, and an arm 952 that supports the guide roller and whose base end is fixed to the upper frame member by a fixing tool 965. With this structure, it is possible to suppress the swing of the door body when moving.
[0101]
Note that the above-described guide roller 953 can be omitted. In the examples shown in FIGS. 22 and 23, the width of the torque transmission plate 946 is reduced by omitting the guide rollers, the guide arms, and the guide grooves.
[0102]
In the sliding door device configured as described above, the opening and closing of the door bodies 600L and 600R are performed by moving the door body using the pull handle 650. Since the door bodies 600L and 600R are supported by the door roller 921, they can be easily opened and closed. In this sliding door device, a groove 911 is provided in the lower frame member 540, but there is no protrusion. Therefore, it has a so-called barrier-free structure.
[0103]
Also, one of the toothed pulleys 931L and 931R, or another toothed pulley may be provided, and connected to a motor or the like to be electrically driven. In this case, for example, a touch switch or the like may be arranged on the pull handle 650 so that the door bodies 600L and 600R automatically open and close when touched.
[0104]
The structure described above is a basic structure of a sliding door. In the present embodiment, the sliding mechanism is provided with a shield mechanism 800. In the case of the present embodiment, the shield mechanism 800 is disposed at the contact portions between the door main bodies 600L and 600R, at the door butt, the upper end, and the lower end thereof. Specifically, a door end shield mechanism 810 provided between the doors, a door end shield mechanism 820 provided at the door end of each door, an upper end shield mechanism 830 disposed at the upper end side of the door, and a lower end side of the door And a lower end shield mechanism 840 arranged at the bottom.
[0105]
In the case of the present embodiment, the door shield mechanism 810 is provided with an electromagnetic shielding gasket accommodating member on one door main body, for example, as shown in FIG. Has the same structure as in FIGS. 4 and 5 described above. In this manner, when the door is occupied, when the door is closed so that the door main body 600L and the door main body 600R are brought into contact with each other at the door tip, the electromagnetic action and the shield are performed by the same operation as that shown in FIG. Can be realized. This portion may have the structure shown in FIGS.
[0106]
Next, the door bottom shield mechanism 820 can have the structure shown in FIGS. 8 to 11 described above. Therefore, the description is omitted in this embodiment.
[0107]
As shown in FIGS. 20 to 23, the upper shield mechanism 830 can be realized by the pressing plate 881, the electromagnetic shielding gaskets 831a and 831b, and the support plate 835. This structure is the same as that shown in FIGS. Therefore, the description is omitted here.
[0108]
24 to 25, the lower shield mechanism 840 can be realized by electromagnetic wave shielding gaskets 841a and 841b and support plates 845a and 845b. This structure is the same as that shown in FIGS. Therefore, the description is omitted here.
[0109]
Also in the case of the present embodiment, when the door is closed, the door wheel 921 is dropped into the groove 911, so that the door bodies 600L and 600R are displaced downward. By utilizing this displacement, the above-described upper shield mechanism 830 and lower shield mechanism 840 can press the electromagnetic wave shielding gasket. Thereby, leakage of electromagnetic waves can be reliably blocked.
[0110]
In the above-described second embodiment, a groove is provided in the lower frame member, and the door body is moved and supported using a door mechanism. This structure can be applied to the first embodiment. In such a case as well, by providing a recess in the groove and displacing the door body downward, it is possible to reliably perform the electromagnetic wave shielding in the vertical direction.
[0111]
On the other hand, the movement support mechanism using the rails and the overhead hoist used in the first embodiment can be applied to the second embodiment.
[0112]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to this invention, the sliding door apparatus which can perform a reliable electromagnetic wave shield with a simple structure can be implement | achieved.
[Brief description of the drawings]
FIG. 1 is an overall perspective view showing the appearance of an electromagnetic shield room using an electromagnetic shield sliding door device according to a first embodiment of the present invention.
FIG. 2 is a front view of the electromagnetic shield sliding door device according to the first embodiment of the present invention with the door closed.
FIG. 3 is a front view showing the entire electromagnetic shielding door apparatus according to the first embodiment of the present invention with the door opened.
FIG. 4 is a sectional view showing a structure of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is closed.
FIG. 5 is a diagram showing a state of a door end portion of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention, in a state where the door is opened (or a state before the door is completely closed). FIG.
FIG. 6 is a cross-sectional view showing another structure of a door tip portion of the electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is closed. .
FIG. 7 is a diagram illustrating another structure of the door end portion of the electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention, in a state where the door is opened (or before the door is completely closed). (State).
FIG. 8 is a cross-sectional view showing a structure of a door end portion of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention with the door closed.
FIG. 9 is a diagram showing a state of a door end portion of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention, in a state where a door is opened (or a state before door closing is completed). FIG.
FIG. 10 is a cross-sectional view showing another structure of a door end portion of the electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is closed. .
FIG. 11 is a diagram illustrating another structure of the door end portion of the electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention, in a state where the door is opened (or before the door is completely closed). (State).
FIG. 12 is a sectional view showing a structure of an upper portion of a door of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is closed.
FIG. 13 is a diagram showing a structure of an upper portion of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is opened (or in a state before the door is completely closed). FIG.
FIG. 14 is a sectional view showing a structure of a lower part of a door of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is closed.
FIG. 15 is a diagram showing a structure of a lower portion of an electromagnetic wave shielding mechanism used in the electromagnetic wave shielding sliding door device according to the first embodiment of the present invention in a state where the door is opened (or in a state before the door is completely closed). FIG.
FIG. 16 is a front view of a two-door electromagnetic shield sliding door device according to a second embodiment of the present invention, with the door closed.
FIG. 17 is a front view showing the entirety of the two-door electromagnetic shield sliding door device according to the second embodiment of the present invention with the door opened.
FIG. 18 is a sectional view showing a structure of an electromagnetic wave shielding mechanism used in a two-door electromagnetic shielding sliding door device according to a second embodiment of the present invention in a state where the door is closed. is there.
FIG. 19 is a diagram showing the structure of a door tip portion of an electromagnetic wave shielding mechanism used in a two-door electromagnetic wave sliding door apparatus according to a second embodiment of the present invention, in a state where the door is opened (or closed). (State before completion).
FIG. 20 is a cross-sectional view showing a structure of an upper part of a door of an electromagnetic wave shielding mechanism used in a two-door electromagnetic wave shielding sliding door device according to a second embodiment of the present invention in a state where the door is closed. .
FIG. 21 is a diagram showing a structure of an upper portion of an electromagnetic wave shielding mechanism used in a two-door electromagnetic wave sliding sliding door device according to a second embodiment of the present invention, in a state where the door is opened (or before the door is completely closed). (State).
FIG. 22 is a cross-sectional view illustrating a structure of a two-door electromagnetic shield sliding door apparatus according to a second embodiment of the present invention shown in FIG. 20, except for a guide roller.
FIG. 23 is a cross-sectional view showing a structure of a two-door electromagnetic shield sliding door device according to the second embodiment of the present invention shown in FIG. 21 except for a guide roller.
FIG. 24 is a cross-sectional view showing a structure of a lower part of an electromagnetic wave shielding mechanism used in a two-door electromagnetic wave shielding sliding door device according to a second embodiment of the present invention in a state where the door is closed. .
FIG. 25 is a diagram showing the structure of the lower part of the electromagnetic wave shielding mechanism used in the two-door electromagnetic wave shielding sliding door device according to the second embodiment of the present invention, with the door opened (or before the door is completely closed). (State).
FIG. 26 is a perspective view showing an example of an electromagnetic wave shielding gasket that can be used in the present invention.
FIG. 27 is a perspective view showing another example of an electromagnetic wave shielding gasket that can be used in the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Shield wall board, 20 ... Shield ceiling board, 30 ... Air-conditioning port, 35 ... Inspection port, 40 ... Window, 50 ... Doorway, 51 ... Opening, 60 ... Door,
500: Door frame, 510: Door side frame material, 520: Intermediate frame material, 530: Upper frame material, 540: Lower frame material (shoot sliding), 550: Door butt side frame material, 560: Fixture,
600 ... door, 610 ... door, 620 ... door butt, 630 ... top, 640 ... bottom, 647 ... sound insulation board, 650 ... puller,
700: hanging and moving support mechanism, 710: rail, 711: flat portion, 712: notched portion, 713: notched portion, 714: inclined portion, 717: mounting portion, 720: fixing member, 750: upper hanging wheel, 751 ... hanging pulleys, 752 ... shafts, 753 ... support plates, 754 ... fixing parts, 755 ... fixing tools, 755a ... bolts, 755b ... washers,
800: shield mechanism,
810: door end shield mechanism, 811a, 811b: gasket for electromagnetic wave shielding, 812: mounting part, 813: clamp member, 814: gasket for electromagnetic wave shielding, 815: gasket housing member, 816: mounting reinforcing plate, 817: fixing tool, 861a, 861b: contact plate; 862a, 862b: contact portion; 863a, 863b: push-open portion; 864: mounting reinforcing plate; 867: fixing device;
820: door bottom shield mechanism, 821a, 821b, 821c, 821d: gasket for electromagnetic wave shielding, 822a, 822b, 822c: mounting portion, 823, 823a, 823b: clamp member, 825a, 825b: gasket support plate, 825c: contact Reference numeral 826: Fixing device, 871: Contact plate, 872: Support plate, 872: Support plate, 873: Mounting reinforcing plate, 874: Fixing device, 875: Gasket for electromagnetic wave shielding, 878: Fixing device,
830: Upper end shield mechanism, 831a, 831b: Electromagnetic wave shielding gasket, 832: Mounting part, 833: Clamp member, 835: Gasket support plate, 836: Fixing tool, 881: Gasket compression plate, 882: Fixing tool,
840: Lower end shield mechanism, 841a, 841b: Gasket for electromagnetic wave shielding, 842a, 842b: Mounting portion, 843a, 843b: Clamping member, 845a, 845b: Gasket support plate, 844: Mounting reinforcing plate, 846: Fixing device,
900: moving support mechanism, 911: groove, 912: digging,
920: Door car mechanism. 921… door car,
930: open / close mechanism, 931L, 931R: toothed pulley, 934: toothed belt.

Claims (5)

In a sliding door device having an electromagnetic wave shielding function,
A door frame attached to the opening of the electromagnetic shield room;
A door body that can be freely opened and closed on this door frame,
A movement support mechanism that supports the door body and moves for opening and closing,
A shielding mechanism that performs electromagnetic wave shielding between the door body and the door frame,
The movement support mechanism has a mechanism for displacing downward when the door body is at the door closing position,
The shield mechanism, the electromagnetic wave shielding gasket, disposed to face a member that presses it, and, above the door and below the door, the electromagnetic wave shielding gasket, with the downward displacement of the door body, A sliding door device having an electromagnetic wave shielding function, wherein electromagnetic wave shielding is performed by being pressed by the pressing member. The sliding door device according to claim 1,
The movement support mechanism is a rail provided on the door frame, and movably supports the door body by an upper hanging vehicle traveling on the rail,
The mechanism for displacing the door body downward is a notch provided in the rail, and when the overhanging vehicle is located in the notch, the door body supported by the overhanging vehicle is displaced downward. A sliding door device having a characteristic electromagnetic wave shielding function. The sliding door device according to claim 1,
The movement support mechanism is configured to movably support the door body by a groove provided in the door frame and a door mechanism having a door wheel that can move along the groove.
The mechanism for displacing the door body downward is digging provided in the groove, and when the door wheel is positioned in the digging, the door body supported by the door wheel mechanism is displaced downward. Sliding door device having an electromagnetic wave shielding function. The sliding door device according to any one of claims 1, 2 and 3,
The shield mechanism is arranged such that the electromagnetic wave shielding gasket is disposed at the door tip and the door end of the door body so as to face a member that presses the gasket, and when the door body is at the door closing position, the opposing pressing is performed. A sliding door device having an electromagnetic wave shielding function, characterized in that electromagnetic wave shielding is performed by being pressed by a member to be made. The sliding door device according to any one of claims 1, 2, 3, and 4,
The door body is provided in two pieces,
The shield mechanism, of the two door bodies, disposing the electromagnetic wave shielding gasket on the door of one door body, and disposing a member for pressing the gasket on the door tip of the other door body. A sliding door device having an electromagnetic wave shielding function.

Images