The present invention relates to a magnetic shield panel used for shielding an influence of magnetism emitted from facilities, in which magnetism is used, to the outside, and also used for shielding an influence of magnetism given to the facilities from the outside.
On the other hand, the official gazette of Japanese Unexamined Patent Publication No. 2002-164686 discloses an open type magnetic shield method. A magnetic shield room is defined by walls on which a plurality of magnetic shield members, each of which comprises a plurality of strips of magnetic shield material on each other, are arranged perpendicularly along the walls parallel to each other so that the magnetic flux density (the magnetic field intensity) can be attenuated between the opposed faces of the magnetic shield members adjacent to each other.
However, it takes much labor and time to arrange a large number of magnetic shield strip members along the walls in parallel to each other while leaving a gap between them. Further, when an external force is applied to the magnetic shield members, the magnetic shield members are deformed.
The present invention has been accomplished in view of the above points of the prior art. It is an object of the present invention to provide a magnetic shield panel, the magnetic shield members of which can be easily constructed and the shapes of which can be positively maintained. It is another object of the present invention to provide a magnetic shield panel, the visibility through which can be ensured so that a patient can feel easy about being in the magnetic shield room and further a doctor can easily observe a condition of the patient.
The present invention provides a magnetic shield panel characterized in that a magnetic shield member made of magnetic material is attached to a metallic plate.
According to another feature of the present invention, a magnetic shield panel is provided which is characterized in that a magnetic shield member made of magnetic material is attached to a translucent plate member.
Since the magnetic shield panel of the present invention includes a magnetic shield member, the magnetic flux, absorbed by the magnetic shield member, can be diffused through the magnetic shield member. Due to the foregoing, the magnetic shield property can be ensured.
According to the present invention, by forming a panel with a magnetic shield member integrated with a metallic plate or a translucent plate member, the magnetic shield member can be easily applied. Further, by the metallic plate or the translucent plate member, the magnetic shield member can be protected, and a deformation and damage, which are caused when an external force is carelessly given to the magnetic shield member, can be prevented, and the shape of the magnetic shield member can be properly maintained.
Especially when a translucent plate member is used as a face plate, the visibility in a room, in which a magnetic field forming apparatus such as MRI is arranged, can be ensured. Therefore, a patient can feel easy about being in the magnetic shield room and further a doctor can easily observe a condition of the patient.
In this specification, the term “translucent” includes “transparent”.
The most preferred embodiment of the present invention will be explained as follows.
In this magnetic shield room, two walls 12, which are adjacent to each other, among the ceiling 10, the floor 11 and the four walls, are formed of magnetic shield panels A of the present invention. The magnetic shield panel A is of a vertical type in which magnetic shield members 2 vertically and longitudinary extend. In the present invention, the longitudinal direction of the magnetic shield member 2 may be directed in any direction. However, for example, it is preferable that the longitudinal direction of the magnetic shield member 2 is arranged substantially in parallel to the direction of the magnetic field to be shielded. In the magnetic shield room shown in
As shown in
The pair of plate members 1 are arranged in parallel to each other with a gap between them. In one of the pair of plate members 1, on the inner face of the plate member opposing to the other, a plurality of substantially parallel groove portions 14 are formed as shown in
In this connection, in the present invention, it is not necessary that the plate member 1 is completely transparent, that is, the plate member 1 may be a semitransparent material such as figured glass, frosted glass or punching metal. The plate member 1 may have a permiable property. Further, the plate member 1 may be composed in such a manner that one portion is translucent and the other portion is not translucent. For example, the plate member 1 may be composed in such a manner that one of the upper and the lower portion of the plate member 1 is translucent and the other portion is not translucent. In this case, the translucent portion may be composed of a plate member made of transparent glass or synthetic resin such as acrylic resin, and not translucent portion may be composed of a plate member made of plywood or plaster board. According to the present embodiment, a plurality of the above types of plate members 1 can be appropriately combined with each other.
The magnetic shield member 2 used for the present embodiment may be made of magnetic material such as a magnetic steel sheet, Permalloy, amorphous metal or nano-crystal magnetic material (“Finemet (R)” manufactured by Hitachi Kinzoku Co.). As shown in
As shown in
Except for the above shape, the cross section of the magnetic shield member 2 may be formed into various shapes such as a cross-shaped section, a Y-shaped section, a circular section, a hollow circular section, a square (rectangular) section, a hollow square (rectangular) section, a star-shaped section, an H-shaped section, an I-shaped section, a T-shaped section, a semicircular section, a triangular section, a vortex-shaped section, a circular section having a multilayer space inside, and a square section having a multilayer space inside. The magnetic shield member 2 can be formed into various shapes such as a simple-rectangular shape, an intermediate portion expanding shape, a rectangular shape having a hole, a needle shape, a triangular shape, a curved rectangular shape, a bent rectangular shape, an angle member shape, a twisted rectangular shape, a spiral shape, a rotary stand shape and a deformed reinforcing bar shape. Corrosion-prevention treatment or coating may be conducted on the magnetic shield member 2. Coating may be carried out by a well known method such as a coating method of dacuronium, organic substance, powder or static electricity.
The radio wave shielding member 4 is made of a metallic mesh (a wire net). Concerning the radio wave shielding member 4, as long as it can shield the radio waves, the frequency of which is 10 kHz to 40 GHZ, any radio wave shielding member may be used, that is, the radio wave shielding member 4 is not particularly limited to the above specific embodiment. For example, it is possible to use a metallic material such as a stainless steel net in which the diameter of the wire is 0.02 to 1.9 mm and the size of the mesh is 1.5 to 635 mesh.
Concerning the elastic member 3, it is possible to use a spring such as a coil spring. However, the elastic member 3 is not limited to a spring, for example, other materials such as rubber may be used.
The magnetic shield panel A of the present embodiment can be composed when one or a plurality of magnetic shield members 2 are attached to the plate member 1. That is, as shown in
(Sm·μs)/Sa>1 (1)
where
Sm: area of lateral section of magnetic shield member 2
μs: relative magnetic permeability of magnetic material of magnetic shield member 2
Sa: area of lateral section of space between magnetic shield members 2 adjacent to each other
In the same manner as that of the case of the official gazette of Japanese Unexamined Patent Publication No. 2002-164686, the magnetic shield panel A satisfying the expression (1) is capable of attenuating the magnetic flux density at the interval between the opposing magnetic shield members 2 adjacent to each other, and the magnetic shielding effect can be provided.
On the magnetic shield panel A of the present embodiment, the radio wave shield member 4 can be stuck on one face or both faces of a pair of plate members 1. The transparent cover plate 70 can be provided on the surface of this radio wave shield member 4. The cover plate 70 can be formed in the same manner as that of the plate member 1.
The top plate 17 is provided in an upper portion of the magnetic shield panel A of the present embodiment. The top plate 17 is arranged between the upper end portions of the pair of plate members 1 and closes an upper face opening of the space formed between the pair of plate members 1. Except that the size of the top plate 17 is different from the size of the plate member 1, the top plate 17 can be formed in the same manner as that of the plate member 1, however, the top plate 17 is not necessarily transparent. A plurality of through-holes 18, which penetrate the top plate 17 in the thickness direction (the perpendicular direction), are formed on the top plate 17. An upper portion of the flat plate portion 15 of each magnetic shield member 2 is inserted into this through-hole 18. Accordingly, the engaging portion 16 of the upper end of the magnetic shield member 2 is located at a position higher than the top plate 17. As shown in
The bottom plate 19 is provided in a lower portion of the magnetic shield panel A of the present embodiment. The bottom plate 19 is arranged between the lower end portions of the pair of plate members 1 and closes a lower face opening of the space formed between the pair of plate members 1. Except that the size of the bottom plate 19 is different from the size of the plate member 1, the bottom plate 19 can be formed in the same manner as that of the plate member 1, however, the bottom plate 19 is not necessarily transparent. A plurality of through-holes 18, which penetrate the bottom plate 19 in the thickness direction (the perpendicular direction), are formed on the bottom plate 19. A lower portion of the flat plate portion 15 of each magnetic shield member 2 is inserted into this through-hole 18. Accordingly, the engaging portion 16 of the lower end of the magnetic shield member 2 is located at a position lower than the bottom plate 19. The spacer 23 may be provided being interposed between the lower face of the bottom plate 19 and the upper face of the engaging portion 16 on the lower side of the magnetic shield member 2.
In this embodiment, the magnetic shield member 2 is not fixed to the plate member 1. Therefore, the magnetic shield member 2 can be moved in the perpendicular direction. Accordingly, there is a possibility that an intermediate portion of the magnetic shield member 2 is bent and deformed. However, as described above, the magnetic shield member 2 can be held being stretched in such a manner that the magnetic shield member 2 is pushed being extended in the longitudinal direction by the elastic member 3. Therefore, deterioration of the magnetic shielding property of the magnetic shield panel A can be prevented.
Side plates 20 are provided in both side edge portions of the magnetic shield panel A of the present embodiment. The side plates 20 are arranged between the side edge portions of the pair of plate members 1 so that the side openings of the space formed between the pair of plate members 1 can be closed by the side plates 20. Except that the size and thickness of the side plates 20 are different from the size and thickness of the plate member 1, the side plates 20 can be formed in the same manner as that of the plate member 1, however, the side plates 20 are not necessarily transparent. The engaging protrusion 21 is formed on an outer face of one of the side plates 20, and the engaging recess 22 is formed on an outer face of the other side plate 20.
In this connection, in order to assemble the magnetic shield panel A of the present embodiment, each member can be fixed with the fixture such as screws or bonded with adhesive.
When construction is conducted by arranging a plurality of vertical type magnetic shield panels A in the substantially horizontal direction, the magnetic shield room shown in
As shown in
The magnetic shield panel A of the present embodiment is attached to the floor, ceiling and wall so that a gap formed between the magnetic shield member 2 and the under-floor magnetic shield plate 30 and a gap formed between the magnetic shield member 2 and the ceiling side magnetic shield plate 28 can be not more than 2 mm, preferably not more than 0.5 mm. In the present embodiment, the magnetic shield member 2 is formed into a substantial I-shape or Z-shape. Therefore, the upper end face and lower end face of the magnetic shield member 2 can be made to be planes which are substantially parallel to the surfaces of the ceiling side magnetic shield plate 28 and the under-floor magnetic shield plate 30. Therefore, the ceiling side magnetic shield plate 28 and the under-floor magnetic shield plate 30 can be excellently joined to the engaging portion 16. Therefore, the magnetically shielding performance can be positively ensured. In this connection, the top plate 33 is fixed to a lower face of the ceiling structural member 25 by the fixing fixture such as bolts, and the floor plate 35 is fixed to an upper face of the floor structural member 27 by the fixing fixture 36 such as bolts.
As shown in
As shown in
On the two magnetic shield panels A which are adjacent and connected to each other via the pillar member 37, it is preferable that the distance “b” between the magnetic shield members 2, which are located at the closest positions to the pillar member 37, is smaller than the interval “a” of the magnetic shield members 2 arranged between the plate members 1 of one magnetic shield panel A. Due to the foregoing, deterioration of the magnetic shielding property of the magnetic shield member can be prevented.
As shown in
The magnetic shield member 2 is accommodated in the accommodating space 51 all over the length of the accommodating space 51 in the perpendicular direction. In this case, as shown in
Concerning the magnetic shield room, a portion or all of at least one face of the ceiling face 10, the floor face 11 and the wall face 12 can be composed of the above magnetic shield panel A. In this case, the circumstances outside the room can be seen from the inside of the room through the magnetic shield panel A. Further, the circumstances inside the room can be seen from the outside of the room through the magnetic shield panel A. Therefore, the magnetic shield room can be preferably used for MRI apparatus room in a hospital.
The top plate 17 is composed of a plurality of top plate members 17a. When the top plate members 17a are arranged at predetermined intervals, the top plate members 17a are arranged between the upper end portions of a pair of plate members 1 so that an upper face opening of the space formed between the pair of plate members 1 can be closed. A gap formed between the top plate members 17a adjacent to each other is formed as a through-hole 18 provided on the top plate 17.
The floor plate 19 is composed of a plurality of floor plate members 19a. When the floor plate members 19a are arranged at predetermined intervals 19b, the floor plate members 19a are provided between the lower end portions of a pair of plate members 1 so that a lower face opening of the space formed between the pair of plate members 1 can be closed. An interval between the bottom plate members 19a, which are adjacent to each other, is formed as a through-hole 18 provided on the bottom plate 19. Further, on the side plate 20, the engaging protrusion 21 and the engaging recess portion 22 are not formed, that is, the side plate 20 is formed into a flat plate shape, and a plurality of gap members 63 are provided on an outer face of the side plate 20.
When the plate member 1, the cover plate 70, the ceiling member 17a, the bottom member 19a, the side plate 20, the magnetic shield member 2, the elastic member 3 and the radio wave shield member 4 are assembled in the same manner as described before, the magnetic shield panel A can be formed. As shown in
A method of connecting the above members of the plate member 1 and others by using the connecting fixture 64 will be explained as follows. First, the angle steel member 65 is arranged between the members to be connected by the connecting fixture 64. That is, as shown in
Next, the connecting screw 66 is inserted into the through-hole 68 from the outer face side of the cover plate 70, the top plate member 17a, the bottom plate member 19a and the side plate 20, and a forward end portion of the connection screw 66 is screwed into the screw hole 67 of the angle steel member 65. At this time, in the case where the cover member 70 is provided on an outer face of the plate member 1, the connection screw 66 is inserted from an outer face of the cover member 70 via the through-holes 68 of the cover member 70 and the plate member 1. In this way, the cover plate 70, the top plate member 17a, the bottom plate member 19a and the side plate 20 are connected to each other. In this connection, the pair of plate members 1 are not just rightly opposed to each other but they are opposed to each other being somewhat displaced from each other. Due to the above structure, the protruding piece 69 is formed out of the side edge portion protruding outside from the side plate 20 of the plate member 1.
The magnetic shield panel A illustrated in
In this magnetic shield room, two wall faces among the ceiling face 10, the floor face 11 and the four wall faces 12 are formed out of the magnetic shield panels A of the present embodiment. In the present embodiment, the magnetic shield panel A is a horizontal type magnetic shield panel A on which the magnetic shield member 2 is horizontally formed, that is, the magnetic shield member 2 is formed in the lateral direction. In the magnetic shield room shown in
The horizontal type magnetic shield panel A includes a pair of translucent plate member 1, a magnetic shield member 2 and a radio wave shield member 4. Longitudinal directions of the plate member 1 and the groove portion 14 are substantially horizontal. Except for that, the horizontal type magnetic shield panel is composed in the same manner as that of the vertical type magnetic shield panel described before. That is, the groove portion 14 is formed all over the length of the plate member 1 in the horizontal direction so that the groove portion 14 can be provided from one end of the plate member 1 to the other end. The magnetic shield member 2 used for the horizontal type magnetic shield panel A is formed into a rectangular plate shape which is long in the horizontal direction. Except for that, the magnetic shield member 2 used for the horizontal type magnetic shield panel A is formed in the same manner as that of the vertical type magnetic shield panel described before. That is, the magnetic shield member 2 includes: a rectangular-plate-shaped flat plate portion 15 which is long in the horizontal direction; and a forward end portion 40 adjoining both end portions of the flat plate portion 15 in the longitudinal direction. In the magnetic shield member 2, the engaging portion 16, which is provided in the embodiment described before, is not formed. The radio wave shield member 4 used for the horizontal type magnetic shield panel A is the same as that of the vertical type magnetic shield panel described before. In this connection, the horizontal type magnetic shield panel A is not provided with the elastic member 3 and the side plate 20.
On the horizontal type magnetic shield panel A, the magnetic shield member 2 is extended long in the horizontal direction. Except for that, the horizontal type magnetic shield panel A can be formed in the same manner as that of the vertical type magnetic shield panel A. That is, a plurality of magnetic shield members 2 are arranged between a pair of plate members 1 which are arranged being opposed to each other. The pair of plate members 1 are arranged in such a manner that one side of one plate member 1, on which the groove portion 14 is formed, is opposed to one side of the other plate member 1 on which the groove portion 14 is formed, and a side edge portion of the flat plate portion 15 of the magnetic shield member 2 is inserted into the groove portion 14. The magnetic shield members 2 are arranged, being separate from each other, at predetermined intervals between the pair of plate members 1 so that the plane portions (the faces of the largest area) of the flat plate portions 15 can be opposed to each other. Even in the case of the horizontal type magnetic shield panel A, it is preferable that the expression (1) is satisfied. When this condition is satisfied, the magnetic shield property can be provided.
The horizontal type magnetic shield panel A includes the same radio wave shield member 4 as that of the vertical type magnetic shield panel. On the surface, the transparent cover plate 70 is provided on its surface. On the horizontal type magnetic shield panel A, in the same manner as that of the embodiment described before, the top plate 17 and the bottom plate 19 are provided, however, the aforementioned through-hole 18 is not formed on the top plate 17 and the bottom plate 19.
Further, the horizontal type magnetic shield panel A does not include the side plate 20 which is provided in the vertical type magnetic shield panel. A space formed between the pair of plate members 1 is open to the side of the magnetic shield panel A. The forward end portion 40 of the magnetic shield member 2 arranged between the pair of plate members 1 is protruded from there. On the horizontal magnetic shield panel A, the magnetic shield member 2 is not fixed to the plate member 1 but can be moved in the horizontal direction. When the magnetic shield member 2 is inserted into the groove portion 14, the magnetic shield member 2 can be held between the pair of plate members 1 without being bent in the central portion. Therefore, deterioration of the magnetic shield property of the horizontal magnetic shield panel A can be prevented.
When a plurality of horizontal type magnetic shield panels A are arranged in the perpendicular and the horizontal direction, the magnetic shield room shown in
The forward end portion 40 of the magnetic shield member 2 protruding outside (on the side) of the side edge portion of a pair of plate members 1 is adjacent to the horizontal type magnetic shield panels A adjoining in the horizontal direction. As explained below, the forward end portions 40 are connected to each other. Referring to
It is preferable that a plurality of shield members 2a composing the magnetic shield member 2 has a predetermined length L3, preferably a predetermined length L3 which is not less than 10 mm, and the plurality of shield members 2a are arranged being offset in the longitudinal direction. Due to the foregoing, end portions of the sections 2a of the magnetic shield member 2 are not arranged on the perpendicular straight line but arranged on an oblique line. Further, side edge portions of the radio wave shield members 4 protruding from the side edge portions of the horizontal type magnetic shield panels A, which are adjacent to each other in the horizontal direction, are connected with each other by the connecting member 52. The side edge portions of the electric shield member 4 are connected to each other by the joint 45 on the reverse side of the accessory 46.
In this connection, it is possible to form a magnetic shield room when both the vertical and the horizontal type magnetic shield panel A are used. In this case, the vertical and the horizontal type magnetic shield panel A are arranged before and behind so that the plate member 1 of the vertical type magnetic shield panel A and the plate member 1 of the horizontal type magnetic shield panel A can be opposed to each other. Due to the foregoing, not only the magnetic fields in the perpendicular and the horizontal direction but also the magnetic fields in all directions can be shielded.
In the above embodiment, the magnetic shield room is composed in such a manner that two wall faces are respectively formed out of the magnetic shield panels A. However, all the six faces including the ceiling face 10, the floor face 11 and the four wall faces 12 may be composed of the magnetic shield panels A of the present invention. In this case, the magnetic shield unit 55 shown in
In the embodiment described before, it is explained that the magnetic shield panel A includes a pair of plate members 1. However, it should be noted that the present invention is not limited to the above specific embodiment. For example, the magnetic shield panel A may be composed when the magnetic shield member 2 is provided on one plate member 1. Further, on the magnetic shield panel A of the present embodiment, it is possible to use not less than three plate members 1. For example, as shown in
Next, referring to
In this embodiment, the translucent heat insulating member 71 is accommodated inside the magnetic shield panel A. For example, as shown in
The heat insulating member 71 is filled between the magnetic shield members 2 adjacent to each other and bonded onto the inner face (the opposing face) of the plate member 1 by adhesive. When the magnetic shield member 2 and the heat insulating member 71 are tightly contacted with each other, the magnetic shield member 2 can be interposed between the heat insulating members 71, which are adjacent to each other, and held at a predetermined position.
Still another embodiment of the present invention will be explained below.
Referring to
The heat insulating member 203 may be made of a conventionally used heat insulating material. Examples of the heat insulating material are: inorganic fiber such as rock fiber, glass fiber or ceramic fiber; and foamed resin such as urethane foam or phenol foam. It is preferable that rock fiber or glass fiber, the heat insulating performance and the fire resistance performance of which are high, is used for the heat insulating member 203. The heat insulating member 203 can be formed into a block shape like a square bar. The density of the heat insulating member 203 is usually 20 to 400 kg/m3. However, it is preferable that the density of the heat insulating member 203 is 120 to 200 kg/m3.
The magnetic shield panel B can be composed in such a manner that a plurality of magnetic shield members 202 and heat insulating members 203 are provided between a pair of metallic plates 201. That is, as shown in
In the present embodiment, the heat insulating member 203 is filled between the magnetic shield members 202 on the magnetic shield panel B and bonded on the inner faces (the faces opposed to each other) of the metallic plates 201. As shown in
In this embodiment, the magnetic shield member 202 is not fixed to the metallic plate 201 in the same manner as that of the magnetic shield member 2 of the embodiment described before. Therefore, the magnetic shield member 202 can be moved in the longitudinal direction (the perpendicular direction). The magnetic shield member 202 is pinched from both sides by the heat insulating members 203 substantially all over the length. Accordingly, there is no possibility that the magnetic shield member 202 is bent and deformed at the middle portion. Therefore, deterioration of the magnetic shielding property of the magnetic shield panel B can be prevented.
As shown in
In the case where the heat insulating member 203 is made of fiber such as rock fiber, it is preferable that the fiber is mainly directed in the thickness direction (the direction perpendicular to the surface of the metallic plate 201) of the magnetic shield panel B. Due to the foregoing, deterioration of the mechanical strength of the magnetic shield panel B can be prevented.
The magnetic shield panel B of the present embodiment includes: an engaging protruding portion 221 formed in one side edge portion; and an engaging recess portion 222 formed in the other side edge portion. As shown in
The magnetic shield member 202 is arranged between a pair of metallic plates 201 so that the engaging portion 216 of the magnetic shield member 202 can be protruded from an upper end and a lower end of the metallic plate 201. An upper face and a lower face of the heat insulating member 203 are exposed from between the pair of metallic plates 201.
When construction is conducted in such a manner that a plurality of vertical type magnetic shield panels B are arranged in the substantially horizontal direction, the magnetic shield room shown in
In the substantially same manner as that of the embodiment explained referring to
As shown in
As shown in
On the two magnetic shield panels B which are adjacent and connected to each other via the pillar member 237, it is preferable that the distance “b” between the magnetic shield members 202, which are located at the closest positions to the pillar member 237, is smaller than the interval “a” of the magnetic shield members 202 arranged between the metallic plate members 201 of one magnetic shield panel B. Due to the foregoing, deterioration of the magnetic shielding property of the magnetic shield member can be prevented. Concerning the magnetic shield room, a portion or all of at least one face of the ceiling face 210, the floor face 211 and the wall face 212 can be composed of the above magnetic shield panel B.
As shown in
The pillar outline member 237a can be formed by bending the same metallic plate as the metallic plate 201. The engaging recess portion 239 and the engaging protruding portion 238 can be formed by means of folding. The magnetic shield member 202 is accommodated inside the pillar outline member 237a all over the length in the perpendicular direction. As shown in
In the same manner as that of the embodiment explained referring to
The horizontal type magnetic shield panel B includes a pair of metallic plates 201, a magnetic shield member 202 and a heat insulating member 203. The horizontal type magnetic shield panel B can be substantially composed in the same manner as that of the vertical type magnetic shield panel B except that the magnetic shield member 202 is formed into a rectangular plate shape, which is long in the horizontal direction, and not provided with the engaging portion 216. The metallic plate 201 is substantially composed in the same manner as that of the metallic plate of the vertical type magnetic shield panel B except that the longitudinal direction of the metallic plate 201 is substantially horizontal.
Between a pair of metallic plates 201 arranged being opposed to each other, a plurality of magnetic shield members 202 and the heat insulating member 203 are arranged. The magnetic shield members 202 are arranged between the pair of metallic plates 201 so that the magnetic shield members 202 can be perpendicularly directed to the metallic plates 201. In this case, even in the case of the horizontal type magnetic shield panel B, it is preferable that the expression (1) is satisfied. When this condition is satisfied, the magnetic shielding property can be effectively obtained.
In the case of the horizontal type magnetic shield panel B, the magnetic shield panels B, which are adjacent to each other on the upper and lower sides, are connected to each other by the engagement of the engaging protrusion with the engaging recess in the same manner as the case in which the vertical type magnetic shield panels B are connected to each other in the horizontal direction. Shapes of the engaging protrusion and the engaging recess of the magnetic shield panels B are the same as those of the case shown in
In the case of the horizontal type magnetic shield panel B, the magnetic shield member 202 is not fixed to the metallic plate member 201. Therefore, the magnetic shield member 202 can be moved in the horizontal direction. Accordingly, there is a possibility that an intermediate portion of the magnetic shield member 202 is bent and deformed. However, as described above, when the magnetic shield member 202 is interposed between the heat insulating members 203 adjacent to each other, deflection of the magnetic shield member 202 can be prevented. Therefore, deterioration of the magnetic shielding performance of the magnetic shield panel B can be prevented.
In the same manner as that of the embodiment explained before referring to
The horizontal type magnetic shield panels B are applied substantially in the same manner as that of the vertical type magnetic shield panels B. The magnetic shield panels B, which are located at the uppermost and the lowermost position, are respectively fixed to the ceiling structural member 25 and the floor structural member 27 (
The forward end portion 240 of the magnetic shield member 202 protruding outside (on the side) of the end portion of a pair of metallic plate member 201 is adjacent to the horizontal type magnetic shield panels B adjoining in the horizontal direction. As explained below referring to
Next, another embodiment is shown in
On the magnetic shield panel B of this embodiment, the heat insulating member 203 is formed into a hollow body. Other points of the constitution are the same as those of the embodiment explained referring to
The heat insulating member 203 is filled between the magnetic shield members 202 adjacent to each other and bonded onto the inner face (the opposing face) of the metallic plate 201 by adhesive. When the magnetic shield member 202 and the heat insulating member 203 are tightly contacted with each other, the magnetic shield member 202 can be interposed between the heat insulating members 203, which are adjacent to each other, and held at a predetermined position. When the hollow heat insulating member 203 is used as described above, the weight of the magnetic shield panel B can be reduced as compared with the case in which the solid heat insulating member 203 is used. When it is necessary to enhance the rigidity of the magnetic shield panel B, the heat insulating member 203, the rigidity of which is relatively high, is used.
Next, referring to
First, the heat insulating members 203 and the magnetic shield members 202 are arranged at predetermined positions on the metallic plate 201. In order to arranged the heat insulating members 203 and the magnetic shield members 202 on the metallic plate 201, the heat insulating members 203 and the magnetic shield members 202 can be alternately arranged on the metallic plate 201. Alternatively, a unit is made by alternately arranging the heat insulating members 203 and the magnetic shield members 202, and the thus made unit can be put on the metallic plate 201.
The metallic plate 201, on which the heat insulating members 203 and the magnetic shield members 202 are arranged, is held on the elevating holding device 103. Next, the other metallic plate 201 is reversed by the reversal device 104 and put on the heat insulating members 203 arranged on the metallic plate 201 which is held on the elevating holding device 103. In this case, the metallic plate 201 to be reversed is coated with adhesive. In this way, the heat insulating members 203 and the magnetic shield members 202 can be arranged between the pair of metallic plates 201.
In this connection, the heat insulating members 203 and the magnetic shield members 202 may be arranged on the metallic plate 201 under the condition that the metallic plate 201 is held on the elevating holding device 103. Alternatively, the heat insulating members 203 and the magnetic shield members 202 may be arranged on the metallic plate 201 under the condition that the metallic plate 201 is not held on the elevating holding device 103. It is preferable that the elevating holding device 103 includes a holding fixture 105 for holding the metallic plate 201, on which the heat insulating members 203 are arranged, at a predetermined position. The reversal device 104 includes a sucking fixture 106 composed of a magnet or a vacuum suction pad. Further, there is provided a holding fixture 107 for holding the metallic plate 201 to be reversed at a predetermined position with respect to the reversal device 104. Furthermore, there is provided a compressing device 108 for pushing and compressing end portions of the heat insulating members 203 so that the metallic plate 201 can be easily put on the heat insulating members 203.
In this connection, even in the case of the magnetic shield panel B explained referring to
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2003-321808 | Sep 2003 | JP | national |
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2004-037428 | Feb 2004 | JP | national |
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PCT/JP2004/013598 | 9/10/2004 | WO | 00 | 7/31/2006 |
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