JP6275894B2 - Electromagnetic shielding container - Google Patents

Description

  The present invention relates to a container capable of shielding electromagnetic waves.

  2. Description of the Related Art Conventionally, for example, containers that store electronic components or the like have been required to have electromagnetic shielding properties that shield electromagnetic waves (see, for example, Patent Document 1). The container of patent document 1 is comprised by the upper side member and the lower side member. The upper member includes an upper wall portion and a peripheral wall portion extending downward, and a conductor layer made of a conductor is provided in an intermediate portion in the thickness direction of the upper wall portion and the peripheral wall portion. This conductor layer is also provided so as to cover the lower end surface of the peripheral wall portion. Further, the lower member includes a lower wall portion and a peripheral wall portion extending upward, and similarly, a conductor layer is provided on the lower wall portion and the peripheral wall portion. The conductor layer of the lower member is also provided so as to cover the upper end surface of the peripheral wall portion. A convex portion on the lower end surface of the peripheral wall portion of the upper member and a concave portion on the upper end surface of the peripheral wall portion of the lower member are fitted to constitute one container.

JP-A-6-169190

  By the way, when a single container is configured by combining the upper member and the lower member as in Patent Document 1, the coupling structure of both members becomes a problem. That is, if a gap is generated between the upper member and the lower member, the conductor layer on the lower end surface of the peripheral wall portion of the upper member is separated from the conductor layer on the upper end surface of the peripheral wall portion of the lower member. As a result, electromagnetic waves pass between them, resulting in a decrease in shielding properties of the electromagnetic waves.

  In particular, when the member constituting the container is made of resin from the viewpoint of weight reduction, a gap is likely to be generated between the upper member and the lower member due to, for example, deformation due to thermal deformation or aging. In addition, when a heavy object such as a battery for an electric vehicle is accommodated in the container, a member constituting the container is deformed by the weight, and a gap is generated between the upper member and the lower member. Sometimes. However, in the container of Patent Document 1, since the upper member and the lower member are simple concave-convex fitting, it is not a structure that can effectively prevent the opening of both members.

  The present invention has been made in view of such a point, and the object of the present invention is to prevent a gap from being formed between members when an electromagnetic wave shielding container is constituted by a plurality of members including resin members. In addition, the electromagnetic wave shielding property is maintained well so that the conductive portions of the members are not separated.

  In order to achieve the above object, in the present invention, a plurality of members are fastened by a fastening member, and the conductive portions of the respective members are brought into contact with each other at a joining portion of the plurality of members.

The first invention is
A first member made of a resin material, resin material or Rannahli, and a second member which defines a receiving space of the article with the first member is attached,
A first fastening portion is provided on the side of the first member that is coupled to the second member so as to extend outward from the housing space.
On the side of the second member that is coupled to the first member, a second fastening portion that extends outward from the housing space is provided so as to correspond to the first fastening portion,
The first member is provided with a conductor layer for providing electromagnetic shielding properties,
Above the second member, conductive layer for imparting an electromagnetic wave shielding property is provided,
The conductor layer of the first member is composed of a sheet material that extends to a side that is coupled to the second member in the first fastening portion, and the surface of the sheet material is the second member in the first fastening portion. Arranged to be exposed from the side to be joined,
In the first fastening portion, a holding member for holding the sheet material at a predetermined position at the time of resin molding is inserted in a state in which the portion exposed from the first fastening portion in the sheet material is in contact with the back side Molded,
The holding member insert-molded in the first fastening portion protrudes from the side opposite to the side joined to the second member in the first fastening portion, and the side in contact with the sheet material is the first side. 1 formed wider than the side protruding from the fastening part,
The conductor layer of the second member is composed of a sheet material extending to the side coupled to the first member in the second fastening portion, and the surface of the sheet material is the same as that of the first member in the second fastening portion. Arranged to be exposed from the side to be joined,
In the second fastening portion, a holding member for holding the sheet material in a predetermined position at the time of resin molding is inserted in a state in which the portion exposed from the second fastening portion in the sheet material is in contact with the back side Molded,
The holding member insert-molded in the second fastening portion protrudes from the opposite side of the second fastening portion to the side joined to the first member, and the side in contact with the sheet material is the first side. 2 formed wider than the side protruding from the fastening part,
In a state in which the first fastening portion and the second fastening portion are fastened by a fastening member, the conductor layer of the first member is in contact with the conductive portion of the second member.

According to this configuration, since at least the first member is made of resin, it is possible to reduce the weight of the electromagnetic shielding container. And the 1st fastening part of the 1st member and the 2nd fastening part of the 2nd member are fastened in the state which made the conductor layer of the 1st member and the part which has the conductivity of the 2nd member contact. Therefore, no gap is generated between the first member and the second member due to a temperature change, an aging change, or the like. Therefore, it becomes possible to maintain the conductor layer of the first member and the conductive portion of the second member in contact with each other, and the electromagnetic wave shielding property is well maintained .

  According to the first invention, the first fastening portion of the first member and the second fastening portion of the second member are fastened by the fastening member, and the conductive layer of the first member and the conductivity of the second member are provided. Since the portions are brought into contact with each other, the electromagnetic wave shielding properties can be maintained well.

It is a perspective view of the electromagnetic wave shielding container which concerns on embodiment. It is the perspective view which looked at the lower member of the electromagnetic shielding container from the upper part. It is sectional drawing equivalent to the III-III line | wire of FIG. 1, (a) shows the state before couple | bonding an upper member and a lower member, (b) after couple | bonding an upper member and a lower member. Shows the state. FIG. 6 is a view corresponding to FIG. 3 according to Modification 1 of the embodiment. FIG. 6 is a view corresponding to FIG. 3 according to a second modification of the embodiment. It is FIG. 3 equivalent view which concerns on the modification 3 of embodiment. It is FIG. 3 equivalent view which concerns on the modification 4 of embodiment. It is sectional drawing of the metal mold | die explaining the molding point of the lower member which concerns on the modification 4. It is sectional drawing of the metal mold | die explaining the molding point of the upper member which concerns on the modification 4. It is FIG. 3 equivalent view which concerns on the modification 5 of embodiment. It is FIG. 3 equivalent view which concerns on the modification 6 of embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature, and is not intended to limit the present invention, its application, or its use.

  FIG. 1 shows an electromagnetic wave shielding container 1 according to an embodiment of the present invention. The electromagnetic wave shielding container 1 is a large container that can accommodate, for example, a battery (article) mounted on an electric vehicle. The electromagnetic shielding container 1 may contain, for example, an electronic component that is weak against electromagnetic waves, or an electronic component that generates electromagnetic waves, in addition to the battery of the electric vehicle. Moreover, the magnitude | size of the electromagnetic shielding container 1 can be arbitrarily set according to the thing to accommodate.

  The electromagnetic wave shielding container 1 is formed by combining a lower member 10 and an upper member 20, and an accommodation space R for articles is defined in the interior by the lower member 10 and the upper member 20. The lower member (second member of the present invention) 10 constitutes a lower portion than the substantially central portion in the vertical direction of the electromagnetic shielding container 1 and has a concave shape that opens upward. The concave member may be one of the lower member 10 and the upper member 20. In this case, the other member is formed into a lid shape.

  As shown in FIG. 2, the lower member 10 includes a bottom wall portion 11, a peripheral wall portion 12 extending upward from a peripheral edge portion of the bottom wall portion 11, and an upper end portion of the peripheral wall portion 12 (the side coupled to the upper member 20. ) And a lower flange portion 13 as a first fastening portion extending outward from the housing space R. The bottom wall portion 11, the peripheral wall portion 12, and the lower flange portion 13 are integrally formed using a non-conductive resin material. The bottom wall portion 11 is substantially flat and has a substantially rectangular shape in plan view. The peripheral wall portion 12 extends so as to incline so that the horizontal cross section increases as it approaches the upper end.

  The lower flange portion 13 is continuous in the circumferential direction of the peripheral wall portion 12 and extends in a substantially horizontal direction. In the lower flange portion 13, a plurality of holes 13a for inserting bolts B (shown in FIG. 1) as fastening members for fastening the lower member 10 and the upper member 20 are spaced apart from each other in the circumferential direction. Is formed. The hole 13a extends in the vertical direction. The site | part in which the hole 13a in the lower side flange part 13 was formed has extended largely compared with another site | part. A female screw member C is fitted into the hole 13a. The female screw member C has a screw hole into which the bolt B is screwed, and is fixed to the inner surface of the hole portion 13a.

  As shown in FIG. 3, the upper surface 13d of the lower flange portion 13 extends substantially horizontally, and a seal groove 13b into which the seal material S is fitted is formed on the upper surface 13d. The seal groove 13 b is positioned on the inner side in the extending direction than the hole 13 a in the upper surface 13 d of the lower flange portion 13, and is configured by an annular groove surrounding the open portion above the lower member 10. The sealing material S is for sealing between the lower member 10 and the upper member 20 to mainly ensure water tightness, and is made of an elastic material such as rubber, for example. The sealing material S has an annular shape corresponding to the shape of the sealing groove 13b. The upper flange portion 23 may be formed with a seal groove into which the seal S is fitted on the lower surface 23d.

  Further, a step portion 13c is formed on the upper surface 13d of the lower flange portion 13 on the inner side in the extending direction than the seal groove 13b. The step portion 13 c is a housing portion that houses a protruding portion 23 a of the upper member 20 described later, and is continuous in the circumferential direction of the lower flange portion 13. The bottom surface of the step 13c extends substantially horizontally. Further, the side surface 13s of the step portion 13c extends in the vertical direction.

  A conductor layer 15 is provided on the inner surface of the lower member 10. The conductor layer 15 is composed of a sheet material. As the sheet material, for example, a conductive sheet such as a metal-deposited sheet, a sheet made of metal fibers, or a metal sheet having a large number of pores can be used. The conductor layer 15 is obtained by insert-molding a sheet material. That is, a sheet material is placed inside a mold for molding the lower member 10, and in this state, the molten resin is injected into the mold and the sheet material is molded simultaneously with the molding of the molten resin. 10 is attached.

  Note that the method for forming the conductor layer 15 is not limited to insert molding, and is a formation method by so-called manual pasting in which an operator manually pastes the sheet material after molding the lower member 10. May be.

  The conductor layer 15 is continuously provided from the side surface 13 s to the bottom surface of the step portion 13 c of the lower flange portion 13 of the lower member 10.

  The upper member (first member of the present invention) 20 shown in FIG. 1 constitutes an upper portion of the electromagnetic shielding container 1 from the substantially vertical central portion, and has a concave shape that opens downward. The upper member 20 includes an upper wall portion 21, a peripheral wall portion 22 extending downward from the peripheral edge portion of the upper wall portion 21, and a lower end portion (side coupled to the lower member 10) of the peripheral wall portion 22. And an upper flange portion 23 as a second fastening portion extending in the direction. The upper wall portion 21, the peripheral wall portion 22, and the upper flange portion 23 are integrally formed using a non-conductive resin material. The upper wall portion 21 is substantially flat and is formed in a substantially rectangular shape in plan view. The peripheral wall portion 22 is inclined and extended so that the horizontal cross section is enlarged as it approaches the lower end.

  The upper flange portion 23 corresponds to the lower flange portion 13 and extends in a substantially horizontal direction continuously in the circumferential direction of the peripheral wall portion 22. A plurality of insertion holes (not shown) through which the bolts B are inserted are formed in the upper flange portion 23 so as to coincide with the hole portions 13 a of the lower member 10. The portion of the upper flange portion 23 where the insertion hole is formed extends greatly similarly to the lower flange portion 13.

  As shown in FIG. 3, the lower surface 23 d of the upper flange portion 23 extends substantially parallel to the upper surface 13 d of the lower flange portion 13, and protrudes downward from the inner end of the lower surface 23 d in the extending direction. A portion 23a is formed. The protrusion 23 a constitutes a protrusion that continues in the circumferential direction of the upper flange portion 23. The cross section of the protrusion 23a in the vertical direction is substantially rectangular. The inner side surface facing the accommodation space R in the projecting portion 23 a extends in the vertical direction so as to form the same surface as the inner surface of the peripheral wall portion 22. Further, the outer side surface 23s opposite to the inner side surface in the protruding portion 23a also extends in the vertical direction, and is formed along the side surface of the step portion 13c. Furthermore, the protrusion direction front end surface of the protrusion 23a extends substantially horizontally and is formed along the bottom surface of the step 13c. As shown in FIG. 3A, the protruding height dimension H of the protruding portion 23a may be the same as the depth dimension D of the stepped portion 13c. Is set longer than the depth dimension D of the stepped portion 13c. Thereby, in a state where the protruding portion 23a is accommodated in the stepped portion 13c and the front end surface of the protruding portion 23a is brought into contact with the bottom surface of the stepped portion 13c, the protruding portion 23a is not completely accommodated in the stepped portion 13c. The base end portion of the protruding portion 23 a comes out of the step portion 13 c, and a predetermined gap is formed between the upper surface 13 d of the lower flange portion 13 and the lower surface 23 d of the upper flange portion 23.

  Except for the portion where the protruding portion 23a is formed on the lower surface 23d of the upper flange portion 23, the upper flange portion 23 is formed substantially flat. The sealing material S comes into contact with this flat portion.

  A conductor layer 25 is provided on the inner surface of the upper member 20. The conductor layer 25 is made of a sheet material similar to the conductor layer 15 of the lower member 10.

  The conductor layer 25 is continuously provided from the inner side surface of the protruding portion 23a of the upper flange portion 23 of the upper member 20 to the distal end surface 23t in the protruding direction and the outer side surface 23s.

  Next, a case where an article is stored in the electromagnetic shielding container 1 configured as described above will be described. For example, after a battery for running an electric vehicle is accommodated in the lower member 10, the upper member 20 is placed on the battery so as to cover the battery from above. Then, the upper flange portion 23 of the upper member 20 and the lower flange portion 13 of the lower member 10 are matched with each other, and the protruding portion 23a of the upper flange portion 23 is fitted into the step portion 13c of the lower flange portion 13. Keep it in a housed state. In this state, the conductor layer 25 covering the tip end surface 23t of the protrusion 23a and the conductor layer 15 covering the bottom surface of the stepped portion 13c are in contact with each other, and the conductor layer 25 covering the outer side surface 23s of the protrusion 23a The conductor layer 15 covering the side surface 13s of the step portion 13c comes into contact with each other or forms a slight gap.

  Then, the bolt B is inserted into the insertion hole of the upper flange portion 23 of the upper member 20 and screwed into the female screw member C of the lower flange portion 13 of the lower member 10, so that the upper flange portion 23 and the lower flange portion 13 are engaged. And conclude. At this time, the protruding height dimension H of the protruding portion 23a is set longer than the depth dimension D of the stepped portion 13c, and a predetermined height is provided between the upper surface 13d of the lower flange portion 13 and the lower surface 23d of the upper flange portion 23. Since the gap is formed, the conductor layer 25 covering the tip end surface 23t of the protruding portion 23a and the conductor layer 15 covering the bottom surface of the stepped portion 13c can be strongly contacted by the fastening force of the bolt B. . As long as the protrusion 23a and the step 13c are in contact with each other, the gap may be slightly opened.

  If the lower member 10 and the upper member 20 are made of resin, a gap may be formed between the lower member 10 and the upper member 20 due to thermal deformation, aging, the weight of the article, and the like. Then, the opening of the lower flange portion 13 and the upper flange portion 23 is suppressed by fastening the lower flange portion 13 and the upper flange portion 23 at a plurality of locations. As a result, it is possible to prevent the conductor layer 25 covering the tip end surface 23t of the protruding portion 23a from separating from the conductor layer 15 covering the bottom surface of the stepped portion 13c.

  As explained above, according to the electromagnetic wave shielding container 1 according to this embodiment, the lower flange portion 13 of the lower member 10 and the upper flange portion 23 of the upper member 20 are fastened by the bolt B, and the lower member Since the ten conductor layers 15 and the conductor layer 25 of the upper member 20 are brought into contact with each other, the electromagnetic wave shielding property can be maintained well.

  Further, since the protrusion 23a is formed on the upper flange portion 23 of the upper member 20, and the conductor layer 25 is provided on the inner peripheral surface so as to continue from the outer side surface 23s to the tip surface 23t of the protrusion 23a, The shielding property can be further improved.

  In addition, a step portion 13c for accommodating the protruding portion 23a of the upper member 20 is formed on the lower flange portion 13 of the lower member 10, and the conductor layer is continuous from the side surface 13s to the bottom surface of the step portion 13c. Since 15 is provided on the inner peripheral surface, the electromagnetic wave shielding property can be further improved.

  Moreover, you may provide the groove part 13e in the bottom face of the step part 13c of the lower side flange part 13 of the lower side member 10 like the modification 1 shown in FIG. The groove portion 13e is continuous over the entire circumference of the lower flange portion 13. A conductor layer 15 is provided on the inner surface of the groove 13e. A bulging portion 13 f is formed on the lower surface of the lower flange portion 13 by forming a groove portion 13 e. A groove portion 23e is formed on the lower surface 23d of the upper flange portion 23 of the upper member 20 of the first modification. The groove 23 e is continuous over the entire circumference of the upper flange portion 23. The groove part 23e is located on the outer side in the extending direction of the upper flange part 23 relative to the protruding part 23a, and the protruding part 23a and the groove part 23e are adjacent to each other in the extending direction of the upper flange part 23. Further, a bulging portion 23f is formed on the upper surface of the upper flange portion 23 by forming the groove portion 23e.

  By providing the groove portions 13e and 23e, when the conductor layers 15 and 25 are pasted manually, the terminal portions of the conductor layers 15 and 25 can be made difficult to peel off by inserting them into the groove portions 13e and 23e. Processing work becomes easy.

  Further, as in Modification 2 shown in FIG. 5, a protruding portion 23 g may be provided at the intermediate portion in the extending direction on the lower surface 23 d of the upper flange portion 23 of the upper member 20. The protruding portion 23g is continuous in the circumferential direction of the upper flange portion 23. The conductor layer 25 is provided from the side surface of the protrusion 23g to the front end surface 23t in the protrusion direction. The inner side in the extending direction of the upper flange portion 23 is formed by a flat surface 23h extending in the horizontal direction with respect to the formation portion of the protruding portion 23g on the lower surface 23d. The conductor layer 25 is also provided on the flat surface 23h.

  In addition, a concave portion 13g is formed on the upper surface 13d of the lower flange portion 13 of the lower member 10 of the modified example 2 as an accommodating portion for accommodating the protruding portion 23g. The conductor layer 15 is provided from the side surface to the bottom surface of the recess 13g. The inner side in the extending direction of the lower flange portion 13 than the portion where the concave portion 13g is formed on the upper surface 13d is constituted by a flat surface 13h extending in the horizontal direction. The conductor layer 15 is also provided on the flat surface 13h.

  As shown in FIG. 5B, in a state in which the lower member 10 and the upper member 20 are coupled, the protruding portion 23g is fitted and accommodated in the concave portion 13g. Furthermore, the conductor layer 25 covering the protruding portion 23g and the conductor layer 15 covering the recess 13g are in contact with each other, and the conductor layer 25 covering the flat surface 23h and the conductor layer 15 covering the flat surface 13h are in contact with each other.

  As in Modification 3 shown in FIG. 6, the concave portion 13 i and the convex portion 13 j may be provided on the upper surface 13 d of the lower flange portion 13 of the lower member 10. The recessed portion 13i is positioned on the outer side in the extending direction of the lower flange portion 13 with respect to the step portion 13c. The conductor layer 15 is also provided on the inner surface of the recess 13i.

  The upper flange portion 23 of the upper member 20 of Modification 3 is provided with a convex portion 23i that is accommodated in the concave portion 13i and a concave portion 23j that accommodates the convex portion 13j. The conductor layer 25 is also provided on the outer surface of the convex portion 23i.

  As shown in FIG. 6B, in a state where the lower member 10 and the upper member 20 are coupled, the convex portion 23i is fitted into the concave portion 13i and accommodated.

  In the fourth modification shown in FIG. 7, the insert member 50 may be insert-molded in the lower flange portion 13 of the lower member 10 having the shape shown in the first modification. The insert member 50 is a holding member for intermittently holding the sheet material T used as a conductor layer 25 in a predetermined position in a mold during molding. That is, as shown in FIG. 8A, a first mold 100 and a second mold 101 are prepared as molds for molding the lower member 10. A holding hole 101a for inserting and holding the insert member 50 is formed in the second mold 101. Further, the first mold 100 is provided with a convex portion 100a for forming the groove portion 13e. The sheet material T to be the conductor layer 15 is disposed in the cavity, and the insert member 50 is held in the holding hole 101a. In this state, the sheet material T is sandwiched between the insert member 50 and the convex portion 100a. When the molten resin material A is injected into the cavity as shown in FIG. 8B, the sheet material T is pressed by the flow pressure of the resin and deformed along the inner surface of the first mold 100 and molded. Integrate with resin material. When the sheet material T is deformed so as to be along the inner surface of the first mold 100, the sheet material T moves so as to slide between the insert member 50 and the convex portion 100a. Is press-fitted by the injection pressure, and is further press-fitted into the flange end. Therefore, the moldability does not deteriorate.

  In the fourth modification, the insert member 40 is insert-molded in the upper flange portion 23 of the upper member 20. The insert member 40 is a holding member for holding the sheet material to be the conductor layer 15 in a predetermined position in the mold. That is, as shown in FIG. 9A, a first mold 102 and a second mold 103 are prepared as molds for molding the upper member 20. In the first mold 102, a holding hole 102a for inserting and holding the insert member 40 is formed. Further, the second mold 103 is provided with a convex portion 103a for forming the groove portion 23e. The sheet material T to be the conductor layer 25 is disposed in the cavity, and the insert member 40 is held in the holding hole 102a. In this state, the sheet material T is sandwiched between the insert member 40 and the convex portion 103a. When the molten resin material A is injected into the cavity as shown in FIG. 9B, the sheet material T is pressed by the flow pressure of the resin and deformed along the inner surface of the second mold 103 and molded. Integrate with resin material. When the sheet material T is deformed along the inner surface of the first mold 103, the sheet material T moves so as to slide between the insert member 40 and the convex portion 103a, so that the formability is deteriorated. There is no.

  Each sheet material T needs to be not attached to a portion where the seal material S is provided on the lower surface 23 d of the upper flange portion 23 and the upper surface 13 d of the lower flange portion 13. The reason is that the sheet material T is sandwiched on the bottom surface of the groove 13b into which the seal material S is fitted, or the sheet material T is attached to the lower surface 23d of the upper flange portion 23 with which the upper end of the seal material S abuts. This is because the sealing performance may not be guaranteed.

  As a countermeasure, when the sheet material T is insert-molded, the sheet material T can be prevented from rolling up by sandwiching the vicinity of the end of the sheet material T with the mold using the insert members 40 and 50, and the protruding portion. Since the front end surface 23t in the protruding direction of 23a and the bottom surface of the stepped portion 13c are reliably covered, the sheet material T (conductor layer 25) covering the front end surface 23t of the protruding portion 23a and the bottom surface of the stepped portion 13c are covered. The covering sheet material T (conductor layer 15) can be brought into contact with each other, and the electromagnetic wave can be reliably shielded.

  As in Modification 5 shown in FIG. 10, the insert member 40 similar to Modification 4 is insert-molded on the upper flange portion 23 of the upper member 20 of Modification 3 above, and the lower member 10 of the modification 3 is below the lower member 10. An insert member 50 similar to that of the modified example 4 may be insert-molded in the side flange portion 13.

  Moreover, you may comprise the lower member 10 with the metal material which has electroconductivity like the modification 6 shown in FIG. In this case, a groove 23 k into which the sealing material S is inserted is formed in the upper flange portion 23 of the upper member 20. As shown in FIG. 11B, in a state where the lower member 10 and the upper member 20 are coupled, the conductor layer 25 covering the protruding portion 23c and the conductive portion of the lower member 10 are in contact with each other. . The lower member 10 and the upper member 20 are fastened with bolts (not shown).

  In the above embodiment, the conductor layer 15 of the lower member 10 is provided on the inner surface of the lower member 10, but may be provided on the outer surface of the lower member 10. Further, the conductor layer 25 of the upper member 20 may be provided on the outer surface of the upper member 20.

  Further, either one of the upper member 20 and the lower member 10 may be formed in a plate shape so as to be a lid for the other.

  Further, in the present embodiment, the protruding portion is formed on the upper member 20 and the stepped portion and the accommodating portion are formed on the lower member 10, but the stepped portion and the accommodating portion are formed on the upper member 20, and the lower member 10 is formed. A protrusion may be formed.

  The above-described embodiment is merely an example in all respects and should not be interpreted in a limited manner. Further, all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

  As described above, the electromagnetic wave shielding container according to the present invention can be used to accommodate, for example, a battery for running an electric vehicle.

1 Electromagnetic wave shielding container 10 Lower member (second member)
13 Lower flange (second fastening part)
13c Step (container)
15 Conductor layer 20 Upper member (first member)
23 Upper flange (first fastening part)
23a Protruding portion 23s Outer side surface 23t Front end surface 25 Conductor layer T Sheet material

Claims (1)

A first member made of a resin material (20), a resin material or Rannahli, the second member (10) which partitions and forms the first member (20) accommodating the article with the space (R) and are coupled,
A first fastening portion (23) is provided on the side of the first member (20) that is coupled to the second member (10) so as to extend outward from the housing space (R).
On the side of the second member (10) that is coupled to the first member (20), a second fastening portion (13) extending outward from the housing space (R) is provided on the first fastening portion (23). It is provided to correspond to
The first member (20 ) is provided with a conductor layer (25) for providing electromagnetic shielding properties,
Above the second member (10), the conductor layer for imparting an electromagnetic wave shielding property (1 5) is provided,
The conductor layer (25) of the first member (20) is composed of a sheet material (T) extending to the side coupled to the second member (10) in the first fastening portion (23), and the sheet The material (T) is arranged such that the surface is exposed from the side of the first fastening portion (23) that is coupled to the second member (10),
The first fastening portion (23) includes a holding member (40) for holding the sheet material (T) in a predetermined position during resin molding, and the first fastening portion (23) in the sheet material (T). ) Is insert molded in a state of contact from the back side to the exposed part from
The holding member (40) insert-molded in the first fastening portion (23) protrudes from the opposite side of the first fastening portion (23) to the side coupled to the second member (10), and The side in contact with the sheet material (T) is formed wider than the side protruding from the first fastening portion (23),
The conductor layer (15) of the second member (10) is composed of a sheet material (T) extending to the side coupled to the first member (20) in the second fastening portion (13), and the sheet The material (T) is arranged such that the surface is exposed from the side of the second fastening portion (13) that is coupled to the first member (20),
The second fastening portion (13) includes a holding member (50) for holding the sheet material (T) at a predetermined position during resin molding, and the second fastening portion (13) in the sheet material (T). ) Is insert molded in a state of contact from the back side to the exposed part from
The holding member (50) insert-molded in the second fastening portion (13) protrudes from the opposite side of the second fastening portion (13) to the side coupled to the first member (20), and The side in contact with the sheet material (T) is formed wider than the side protruding from the second fastening part (13),
In a state where the first fastening portion (23) and the second fastening portion (13) are fastened by the fastening member (B), the conductor layer (25) of the first member (20) is the second member. An electromagnetic shielding container (1), wherein the electromagnetic shielding container (1) is in contact with the conductive part (15) of (10).

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