JP2017188516A - Electromagnetic wave shield structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electromagnetic wave shield structure capable of easily controlling penetration and shielding of an electric wave (electromagnetic wave).SOLUTION: An electromagnetic wave shield structure comprises an elastic structure part penetrating an electromagnetic wave, controls penetration and shielding of an electromagnetic wave in accordance with an elastic deformation of the elastic structure part. The electromagnetic wave shield structure comprises: the elastic structure part penetrating the electromagnetic wave; and an electromagnetic wave shield structure part including an electromagnetic wave shielding member, and an electromagnetic wave shielding function is controlled in the electromagnetic wave shield structure part in accordance with the elastic deformation of the elastic structure part, and the penetration and the shielding of the electromagnetic wave are controlled.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electromagnetic wave shielding structure. In particular, the present invention relates to an electromagnetic wave shielding structure having an elastically deformable structure and capable of controlling transmission and shielding of electromagnetic waves by elastic deformation.

  Electromagnetic waves are classified in various ways according to their wavelengths. In the Radio Law, “electromagnetic waves having a frequency of 3 million megahertz or less” are defined as radio waves. Radio waves are widely used for information transmission in the field of communication, such as various electric and electronic devices capable of communication as represented by mobile terminals as well as broadcasting.

  Although it is a radio wave (electromagnetic wave) that is indispensable for modern life, there are cases where it is not desirable that radio waves (electromagnetic waves) pass through without limitation, and control such as shielding radio waves (electromagnetic waves) is performed as necessary. It has been broken.

  As a method for controlling the transmission of radio waves (electromagnetic waves), electrical and electronic devices such as communication devices and sensors may be used, but there are structures that control the transmission of radio waves without using electrical and electronic devices. doing.

  For example, a frequency selection plate that reflects or transmits radio waves of a specific frequency, a dielectric layer having radio wave permeability laminated on the frequency selection plate, and a dielectric variable mechanism that varies the thickness of the dielectric layer There has been proposed a frequency selection plate that reflects or transmits radio waves having a specific frequency (Patent Document 1).

  The applicant of the present application has also proposed a laminate that can exhibit not only electromagnetic wave noise but also vibrations and noises, in addition to ensuring various electrical functions such as electrical or thermal insulation ( Patent Document 2)

JP 2005-252566 A JP 2013-145778 A

  An object of the present invention is to propose an electromagnetic wave shielding structure that can easily control transmission and shielding of radio waves (electromagnetic waves).

  The electromagnetic wave shielding structure is provided with an elastic structure part that allows electromagnetic waves to pass through, and transmission and shielding of the electromagnetic wave are controlled according to elastic deformation of the elastic structure part.

  Comprising an elastic structure part for passing electromagnetic waves, and an electromagnetic wave shielding structure part including an electromagnetic wave shielding material, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is controlled according to elastic deformation of the elastic structure part, An electromagnetic wave shielding structure in which transmission and shielding of electromagnetic waves are controlled.

  According to the present invention, it is possible to provide an electromagnetic wave shielding structure capable of easily controlling transmission and shielding of radio waves (electromagnetic waves).

BRIEF DESCRIPTION OF THE DRAWINGS It is the schematic sectional drawing which abbreviate | omitted one part explaining one Embodiment of this invention, Comprising: (a) is the state in which the elastic structure part is not elastically deformed, (b) is the state in which the elastic structure part is elastically deformed. It is. The schematic perspective view explaining the other example of one Embodiment of this invention. It is the schematic plan view which abbreviate | omitted one part explaining other embodiment of this invention, Comprising: (a) is a state in which the elastic structure part is not elastically deformed, (b) is an elastic structure part elastically deforming. It is in a state. The schematic perspective view explaining other one Embodiment of this invention. The schematic perspective view explaining other one Embodiment of this invention. The schematic perspective view explaining other one Embodiment of this invention. 4A and 4B are diagrams illustrating another embodiment of the present invention, in which FIG. 5A is a plan view showing a state in which an elastic structure portion is not elastically deformed, and FIG. 4A and 4B are diagrams illustrating another embodiment of the present invention, in which FIG. 5A is a plan view showing a state in which an elastic structure portion is not elastically deformed, and FIG. The schematic perspective view explaining other one Embodiment of this invention. (A), (b) is the schematic sectional drawing which abbreviate | omitted one part explaining other one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to such embodiments, and various modifications can be made within the technical scope grasped from the description of the scope of claims. is there.

(Embodiment 1)
FIG. 1 shows an electromagnetic wave shielding structure 1 in which an electromagnetic wave shielding structure portion 4 including a granular electromagnetic wave shielding material 3 is laminated on an upper side of an elastic structure portion 2 made of a rubber material that transmits radio waves (electromagnetic waves). A schematic configuration will be described.

  In a state where no pressure is applied and the elastic structure portion 2 is not elastically deformed (FIG. 1A), the radio wave from the radio wave transmitter 5 embedded in the elastic structure portion 2 is the electromagnetic wave shielding structure portion 4. Cannot be transmitted. Or permeation | transmission is suppressed.

  On the other hand, in a state where the elastic structure portion 2 is elastically deformed due to pressure (FIG. 1B), a gap is formed between the adjacent electromagnetic wave shielding materials 3 due to elastic deformation of the elastic structure portion 2. (Slit) 6 is generated. The radio wave from the radio wave transmitter 5 embedded in the elastic structure portion 2 can go out through the gap (slit) 6.

  As shown in FIG. 1A, when the pressure applied to the electromagnetic wave shielding structure 1 is removed, the radio wave from the radio wave transmitter 5 cannot pass through the electromagnetic wave shielding structure portion 4. Or permeation | transmission is suppressed.

  Thereby, transmission and shielding of radio waves (electromagnetic waves) can be easily controlled.

  In FIG. 1, the structure is described in which the electromagnetic wave shielding structure portion 4 including the granular electromagnetic wave shielding material 3 is laminated on the upper side of the elastic structure portion 2 made of a rubber material. The electromagnetic wave shielding structure portion 4 configured to include the granular electromagnetic wave shielding material 3 has a gap between adjacent granular electromagnetic wave shielding materials 3 due to elastic deformation of the elastic structure portion 2 made of a rubber material. Since it is only necessary to control transmission and shielding of radio waves (electromagnetic waves) by generating (slits) 6 or closing the gaps (slits) 6, other structures can be used.

  For example, an electromagnetic wave shielding structure portion 4 including a granular electromagnetic wave shielding material 3 is laminated on the upper side of the elastic structure portion 2 made of a rubber material, and further, another structural portion or other A structure in which elastic structure portions made of a rubber material are laminated can also be used.

  In addition, an electromagnetic wave shielding structure portion 4 including a granular electromagnetic wave shielding material 3 is laminated on the lower side of the elastic structure portion 2 made of a rubber material, and this is another structural portion located on the lower side. Also, it can be mounted on or laminated on an elastic structure portion made of another rubber material.

  In the embodiment shown in FIG. 2, an electromagnetic wave shielding structure portion 4 is laminated on the upper side of an elastic structure portion 2 made of a rubber material that transmits radio waves (electromagnetic waves), and further, an elastic structure portion made of another rubber material. It represents an example of a structure in which 2a is laminated.

  As shown in FIG. 2, in the case of the electromagnetic wave shielding structure 21 in which the elastic structure parts 2 and 2a made of a rubber material are laminated on the upper and lower sides of the electromagnetic wave shielding structure part 4, the elastic structure by applying pressure. It is also possible to control the transmission and shielding of radio waves (electromagnetic waves) using the thickness change of the portions 2 and 2a.

  Also in the case of the embodiment shown in FIG. 1, various materials to be adopted as the granular electromagnetic shielding material 3 are selected, or the interval between the adjacent granular electromagnetic shielding materials 3 is adjusted. It is also possible to control the transmission and shielding of radio waves (electromagnetic waves) by, for example.

  That is, it is possible to finely adjust the ease of transmission of radio waves (electromagnetic waves) and the difficulty of transmission, as well as complete shielding and transmission control of radio waves (electromagnetic waves).

(Embodiment 2)
In the first embodiment, the electromagnetic wave shielding structure portion 4 including the granular electromagnetic wave shielding material 3 has been described. However, in the embodiment illustrated in FIG. 3, the electromagnetic wave shielding structure portion 14 is configured by the linear electromagnetic wave shielding member 13. doing.

  Since the other points are the same as those of the first embodiment described with reference to FIG. 1, description of common parts is omitted.

  As shown in FIG. 3A, transmission of radio waves (electromagnetic waves) is blocked by the presence of the electromagnetic wave shielding structure portion 14 in a state where no pressure is applied to the elastic structural portion made of a rubber material. Or permeation | transmission is suppressed.

  On the other hand, as shown in FIG. 3B, in the state in which the pressure is applied to the elastic structure portion made of the rubber material, the interval between the adjacent linear electromagnetic wave shielding materials 13 becomes large, and the gap (slit ) 36 is formed, the shielding function is lowered and radio waves (electromagnetic waves) can be transmitted.

  Also in this embodiment, what is adopted as the electromagnetic wave shielding material is variously selected, the interval between the adjacent linear electromagnetic wave shielding materials 13 is adjusted, or the width of the linear electromagnetic wave shielding material 13 is increased. By adjusting and controlling the transmission and shielding of radio waves (electromagnetic waves), not only complete shielding of radio waves (electromagnetic waves) and ON / OFF control for controlling transmission, but also ease of transmission of radio waves (electromagnetic waves), It is also possible to finely adjust the difficulty of transmission.

(Embodiment 3)
The electromagnetic wave shielding structure 41 shown in FIG. 4 is obtained by forming an elastic structure portion 42 made of a rubber material by dispersing an electromagnetic wave shielding material in a rubber material that transmits radio waves (electromagnetic waves).

  When pressure is applied to the elastic structure portion 42 made of a rubber material, the fact that fluctuation occurs in the interval between the electromagnetic wave shielding materials that have been dispersed in the rubber material by kneading or the like is used. .

  In a state where no pressure is applied, the elastic structure portion 42 is not elastically deformed, and the distance between the electromagnetic wave shielding materials does not vary, so that the function of shielding transmission of radio waves (electromagnetic waves) is exhibited. As a result, transmission of radio waves (electromagnetic waves) is blocked. Or permeation | transmission is suppressed.

  On the other hand, in a state where the elastic structure portion 42 is elastically deformed due to pressure and the interval between the electromagnetic wave shielding materials varies, for example, in a place where the interval between adjacent electromagnetic wave shielding materials is widened, The function of shielding the transmission of (electromagnetic waves) is reduced, and radio waves (electromagnetic waves) can be transmitted.

  As the electromagnetic wave shielding material dispersed in the rubber material by kneading or the like, a granular electromagnetic wave shielding agent, a fibrous electromagnetic wave shielding agent, a dielectric agent, or the like can be adopted.

  The function of shielding transmission of radio waves (electromagnetic waves) can also be adjusted by adjusting the blending amount of the electromagnetic shielding material and the distribution density due to dispersion.

  That is, also in this embodiment, transmission and shielding of radio waves (electromagnetic waves) are controlled by variously selecting materials to be used as electromagnetic shielding materials, or adjusting the blending amount of electromagnetic shielding materials and the distribution density due to dispersion. In addition to complete shielding of radio waves (electromagnetic waves) and ON / OFF control for controlling transmission, it is possible to finely adjust the ease of transmission and difficulty of transmission of radio waves (electromagnetic waves).

(Embodiment 4)
The electromagnetic wave shielding structure 41 shown in FIG. 5 is obtained by replacing the electromagnetic wave shielding structure portions 4 and 34 in Embodiments 1 and 2 described in FIGS. 1 and 3 with a sheet-like electromagnetic wave shielding structure portion 54 made of a yarn material. is there.

  The other points are the same as those of the first embodiment described with reference to FIGS.

  As the sheet-like electromagnetic shielding structure portion 54 made of a thread material, a sheet-like body made of a thread material can be adopted. Examples of the sheet-like material made of yarn material include, for example, a woven-like sheet-like material made of plain weave, twill, lion weave, tangle weave (twisted weave), etc., and weft knitting (yokoami) of yarn material. And knitted sheet-like bodies formed by warp knitting.

  Further, as shown in the drawing, in the case of a structure in which a sheet-like electromagnetic shielding structure portion 54 is laminated on an elastic structure portion 2 made of a rubber material, and an elastic structure portion 2a made of a rubber material is laminated thereon. Can also constitute the sheet-like electromagnetic shielding structure portion 54 by simply superposing warps and wefts.

  As the yarn material, a metal wire such as conductive plating fiber or metal fiber can be used.

  In a state where no pressure is applied, the elastic structure portion 2 is not elastically deformed, and there is no variation in the distance between adjacent yarn materials, so that the function of shielding transmission of radio waves (electromagnetic waves) is exhibited. . As a result, transmission of radio waves (electromagnetic waves) is blocked. Or permeation | transmission is suppressed.

  On the other hand, in a state in which the elastic structure portion 2 is elastically deformed due to pressure and fluctuations occur in the interval between adjacent yarn materials, for example, in a place where the interval between adjacent yarn materials is widened, The function of shielding the transmission of (electromagnetic waves) is reduced, and radio waves (electromagnetic waves) can be transmitted.

  In the state shown in FIG. 5, a sheet-like electromagnetic shielding structure portion 54 is laminated on an elastic structure portion 2 made of a rubber material that transmits radio waves (electromagnetic waves), and an elastic structure portion 2a made of a rubber material is laminated thereon. ing. As described in Embodiment 1 of FIGS. 1 and 2, a structure in which a sheet-like electromagnetic shielding structure portion 54 is laminated on the upper side of an elastic structure portion 2 made of a rubber material, or an elastic structure portion made of a rubber material A sheet-like electromagnetic wave shielding structure portion 54 may be laminated on the upper side of 2, and another structure portion may be further laminated thereon.

  In addition, a sheet-like electromagnetic shielding structure portion 54 is laminated on the lower side of the elastic structure portion 2 made of a rubber material that transmits radio waves (electromagnetic waves), and this is another structural portion or other rubber located on the lower side. It is also possible to adopt a structure that is mounted on or laminated on an elastic structure portion made of a material.

  Also in this embodiment, variously selected metal wires such as conductive plated fibers and metal fibers used as the thread material, adjusting the thickness of the thread material, the thickness of the sheet body itself, By adjusting the density (for example, weave density, knitting density), the transmission and shielding of radio waves (electromagnetic waves) are controlled, and not only the complete shielding of radio waves (electromagnetic waves) and the ON / OFF control for controlling the transmission, It is also possible to finely adjust the ease of transmission of radio waves (electromagnetic waves) and the difficulty of transmission.

(Embodiment 5)
The electromagnetic wave shielding structure 61 shown in FIG. 6 has a structure in which an elastic structure portion 2 made of a rubber material that transmits radio waves (electromagnetic waves) and an electromagnetic wave shielding structure portion 64 containing an electromagnetic wave shielding material are laminated. .

  The electromagnetic wave shielding structure portion 64 includes a plurality of slits 67 on the surface.

  When no pressure is applied to the elastic structure portion 2 made of a rubber material, the slit 67 is closed, and the function of shielding transmission of radio waves (electromagnetic waves) is exhibited. As a result, transmission of radio waves (electromagnetic waves) is blocked. Or permeation | transmission is suppressed.

  On the other hand, when pressure is applied and the elastic structure portion 2 is elastically deformed and the slit 67 is widened, the function of shielding the transmission of the radio wave (electromagnetic wave) is lowered at the portion where the slit 67 is widened, and the radio wave (electromagnetic wave) is generated. It can be transmitted.

  When the elastic structure portion 2 is elastically deformed by applying pressure, for example, when the elastic deformation in which the outer peripheral portion of the elastic structure portion 2 is curved downward in FIG. 6 occurs, the slit 67 of the electromagnetic wave shielding structure portion 64 is formed. It opens greatly on the surface side. The function of shielding transmission of radio waves (electromagnetic waves) is adjusted according to the deformation of the slit 67.

  In FIG. 6, a plurality of slits 67 extending in parallel with each other only in one direction are depicted, but the slits 67 are configured such that a plurality of slits extending in different directions intersect each other. You can also For example, a plurality of slits extending in the orthogonal direction may intersect each other.

  In the case of a slit in which a plurality of slits extending in different directions intersect with each other, an elastic deformation occurs in which the outer peripheral portion of the elastic structure portion 2 is curved downward in FIG. When it occurs, the slits are largely opened on the surface side of the electromagnetic wave shielding structure portion 64 in accordance with the form in which the slits intersect.

  The slit 67 has a depth corresponding to the thickness of the electromagnetic wave shielding structure portion 64, that is, from the surface of the electromagnetic wave shielding structure portion 64 to the bottom surface of the electromagnetic wave shielding structure portion 64 in contact with the upper surface of the elastic structure portion 2 in FIG. A form having a penetrating depth can be employed. Moreover, it can also be set as the slit of the depth shorter than the thickness of the electromagnetic wave shielding structure part 64, ie, the depth to the middle from the surface of the electromagnetic wave shielding structure part 64 to a bottom face.

  When the slit 67a has a depth corresponding to the thickness of the electromagnetic wave shielding structure portion 64a, that is, when the slit 67a penetrates from the surface to the bottom surface of the electromagnetic wave shielding structure portion 64a, the peripheral portion 67b of the electromagnetic wave shielding structure portion 64a. , 67c can be an electromagnetic wave shielding structure 61a having a structure in which only the upper surface of the elastic structure portion 2 is attached.

  In this manner, when the force in the direction indicated by the arrow 65 in FIG. 7A is applied to the elastic structure portion 2 and the elastic structure portion 2 is deformed, the slit 67a moves the electromagnetic wave shielding structure portion 64a up and down in FIG. Since the bottom surface of the portion where the slit 67a of the electromagnetic wave shielding structure portion 64a is formed is not attached to the upper side surface of the elastic structure portion 2 (for example, not joined), As shown in FIG. 7B, the portion where the slit 67a is formed has a hole structure penetrating the electromagnetic wave shielding structure portion 64a, and the upper surface of the elastic structure portion 2 appears.

  The radio wave (electromagnetic wave) transmitted through the elastic structure portion 2 made of a rubber material that transmits the radio wave (electromagnetic wave) is not shielded by the electromagnetic wave shielding structure portion 64a through the hole structure portion.

  The electromagnetic wave shielding structure portions 64 and 64a can be prepared using the dielectric agent described in the third embodiment.

  The other points are the same as those of the first embodiment described with reference to FIGS.

  Also in this embodiment, as described above, radio waves (electromagnetic waves) can be transmitted by adjusting the width of the slit, the density at which the slit is formed, etc. In addition to complete shielding of radio waves (electromagnetic waves) by controlling shielding and ON / OFF control for controlling transmission, it is also possible to finely adjust the ease of transmission and difficulty of transmission of radio waves (electromagnetic waves). It is.

(Embodiment 6)
The electromagnetic wave shielding structure 61b shown in FIG. 8 has a structure in which an elastic structure portion 2 made of a rubber material that transmits radio waves (electromagnetic waves) and an electromagnetic wave shielding structure portion 64b containing an electromagnetic wave shielding material are laminated. .

  The electromagnetic shielding structure portion 64b has a plurality of holes 67b on the surface.

  The electromagnetic wave shielding structure 61b shown in FIG. 8 is different from the electromagnetic wave shielding structures 61 and 61a shown in FIGS. 6 and 7 in that the slits 67 and 67a are formed on the surface of the electromagnetic wave shielding structure portion 64. The shield structure portion 64b is formed.

  When no pressure is applied to the elastic structure portion 2 made of a rubber material, as shown in FIG. 8A, the hole 67b is closed and the function of shielding the transmission of radio waves (electromagnetic waves) is exhibited. As a result, transmission of radio waves (electromagnetic waves) is blocked. Or permeation | transmission is suppressed.

  On the other hand, when the pressure is applied and the elastic structure portion 2 is elastically deformed and the hole 67b is widened as shown in FIG. 8B, the function of shielding the transmission of radio waves (electromagnetic waves) at the location where the hole 67b is widened. Decreases, and radio waves (electromagnetic waves) can be transmitted.

  The hole 67b penetrates from the surface of the electromagnetic wave shielding structure portion 64b to the bottom surface of the electromagnetic wave shielding structure portion 64b that is in contact with the upper surface of the elastic structure portion 2. It can be in the form of a hole having a depth. Moreover, it can also be made into the hole of the depth to the middle from the surface of the electromagnetic wave shielding structure part 64 to the bottom surface by making it the depth shorter than the thickness of the electromagnetic wave shielding structure part 64b.

  When the hole 67b is a hole having a depth corresponding to the thickness of the electromagnetic wave shielding structure portion 64b, that is, when the hole 67b penetrates from the surface to the bottom surface of the electromagnetic wave shielding structure portion 64b, FIG. As described with reference to FIG. 6, only the peripheral portion of the electromagnetic shielding structure portion 64b can be attached to the upper surface of the elastic structure portion 2.

  In this way, when the force in the direction indicated by the arrows 65 and 66 in FIG. 8A is applied to the elastic structure portion 2 and the elastic structure portion 2 is deformed, the hole 67b moves the electromagnetic wave shielding structure portion 64b in FIG. The bottom surface of the portion where the hole 67b of the electromagnetic wave shielding structure portion 64b is formed is not attached to the upper surface of the elastic structure portion 2 (for example, not joined). Thus, as shown in FIG. 8B, the portion where the hole 67b is formed becomes a hole structure penetrating the electromagnetic wave shielding structure portion 64b, and the upper surface of the elastic structure portion 2 appears.

  The radio wave (electromagnetic wave) transmitted through the elastic structure portion 2 made of a rubber material that transmits the radio wave (electromagnetic wave) is not shielded by the electromagnetic wave shielding structure portion 64b through the hole structure portion.

  The other points are the same as those of the fifth embodiment described with reference to FIGS. 6 and 7, and thus the description of the common parts is omitted.

  Also in this embodiment, as described above, transmission of radio waves (electromagnetic waves) can be achieved by adjusting the shape of holes penetrating or not penetrating, the diameter of holes, the density at which holes are formed, and the like. In addition to complete shielding of radio waves (electromagnetic waves) by controlling shielding and ON / OFF control for controlling transmission, it is also possible to finely adjust the ease of transmission and difficulty of transmission of radio waves (electromagnetic waves). It is.

(Embodiment 7)
The electromagnetic wave shielding structure 71 shown in FIG. 9 is obtained by applying a coating material containing an electromagnetic wave shielding material to at least one surface of the elastic structure portion 2 made of a rubber material that allows radio waves (electromagnetic waves) to pass through. Is formed on the surface of the elastic structure portion 2.

  When no pressure is applied to the elastic structure portion 2 made of a rubber material, the thickness of the electromagnetic wave shielding structure portion 74 made of a coating film does not vary. Further, the electromagnetic wave shielding structure portion 74 made of a coating film does not spread laterally. Therefore, the function of shielding transmission of radio waves (electromagnetic waves) is exhibited. As a result, transmission of radio waves (electromagnetic waves) is blocked. Or permeation | transmission is suppressed.

  On the other hand, the pressure is applied, the elastic structure portion 2 is elastically deformed, the thickness of the electromagnetic shielding structure portion 74 made of a coating film varies, and the electromagnetic shielding structure portion 74 made of a coating film spreads in the lateral direction. The function of shielding transmission of radio waves (electromagnetic waves) is reduced. As a result, radio waves (electromagnetic waves) can be transmitted.

  As the electromagnetic wave shielding material used for the coating material containing the electromagnetic wave shielding material, the dielectric agent described in Embodiment 3 can be used.

  The other points are the same as those of the first embodiment described with reference to FIGS.

  Also in this embodiment, what is adopted as the electromagnetic shielding material is variously selected, or the mixing ratio of the electromagnetic shielding material in the paint containing the electromagnetic shielding material, the size of the electromagnetic shielding material, the thickness of the coating film, etc. are adjusted. In addition to controlling the transmission and shielding of radio waves (electromagnetic waves), complete shielding of radio waves (electromagnetic waves) and ON / OFF control for controlling transmission, the ease of transmission of radio waves (electromagnetic waves) is difficult. It is also possible to finely adjust.

(Embodiment 8)
In the embodiment shown in FIG. 10, an electromagnetic wave shielding structure 81 is configured by an outer package 88 made of an elastic material such as a rubber material, and fluids 89 a and 89 b having an electromagnetic wave shielding capability enclosed in the outer package 88. An elastic structure portion is formed.

  As the fluid having electromagnetic wave shielding ability enclosed in the outer package 88, for example, water 89a or gel 89b mixed with an electromagnetic wave shielding material such as a dielectric agent described in the third embodiment is used. Can be adopted.

  In a state where no pressure is applied to the electromagnetic wave shielding structure 81, transmission of radio waves (electromagnetic waves) from the radio wave transmitter 5 is blocked or suppressed depending on the thickness of the fluids 89 a and 89 b surrounding the radio wave transmitter 5. The Therefore, no radio wave (electromagnetic wave) is emitted from the electromagnetic wave shielding structure 81. Alternatively, the generation of radio waves (electromagnetic waves) is suppressed.

  On the other hand, when pressure is applied to the electromagnetic wave shielding structure 81, the outer envelope 88 made of a rubber material is elastically deformed, and the fluids 89a and 89b enclosed therein also change. As a result, the thickness of the fluids 89a and 89b blocking the transmission of radio waves from the radio wave transmitter 5 varies, and the function of blocking the transmission of radio waves (electromagnetic waves) is reduced. As a result, radio waves (electromagnetic waves) can be transmitted.

  Also in this embodiment, what is adopted as the electromagnetic shielding material is selected variously, from the water mixed with the electromagnetic shielding material, the mixing ratio of the electromagnetic shielding material in the gel, the size of the electromagnetic shielding material, the elastic material By adjusting the volume of the fluid that has electromagnetic wave shielding ability enclosed in the outer envelope, the transmission and shielding of radio waves (electromagnetic waves) are controlled, and complete shielding and transmission of radio waves (electromagnetic waves) are achieved. In addition to ON / OFF control, it is possible to finely adjust the ease of transmission of radio waves (electromagnetic waves) and the difficulty of transmission.

  ADVANTAGE OF THE INVENTION According to this invention, the electromagnetic wave shielding structure which can control easily permeation | transmission and shielding of an electromagnetic wave (electromagnetic wave) can be provided.

  This electromagnetic wave shielding structure includes, for example, external radio wave shielding mats (noise shielding mats), sidewalks with security functions, nursing beds and floors for nursing facilities, communication control floors / communication control mats at communication spots, disaster prevention mats (water pressure and earth pressure) Detection / alarm), deformation detection mat / seat (maintenance management), bicycle parking mat (bicycle parking position record), bicycle parking / parking parking (parking / parking position recording), parking assist device (for elderly people), parking It can be used for a wheel / parking position confirmation device and so on.

  In addition, since transmission and shielding of radio waves (electromagnetic waves) are controlled in accordance with the elastic deformation of the elastic structure part through which electromagnetic waves pass, it is also compatible with radio waves (electromagnetic waves) with different frequencies such as 2.4 GHz, 900 MHz, and 433 MHz. Is possible.

1, 21, 31, 41, 51, 61, 71, 81 Electromagnetic wave shielding structure 2, 2a Elastic structure part 3 Granular electromagnetic wave shielding material 4 Electromagnetic wave shielding structure part 5 Radio wave transmitter 6 Clearance (slit)
13 Linear Electromagnetic Wave Shielding Member 14 Electromagnetic Wave Shielding Structure Portion 36 Clearance (Slit)
54 Electromagnetic wave shielding structure portion 61 Electromagnetic wave shielding structure portion 64 Electromagnetic wave shielding structure portion 67 Slit 71 Electromagnetic wave shielding structure 74 Electromagnetic wave shielding structure portion 81 made of a coating film Electromagnetic wave shielding structure 88 Outer package 89a, 89b Fluid having electromagnetic wave shielding ability

Claims (18)

  An electromagnetic wave shielding structure that includes an elastic structure part that allows electromagnetic waves to pass therethrough and that controls transmission and shielding of electromagnetic waves in response to elastic deformation of the elastic structure part.   The electromagnetic wave shielding structure according to claim 1, wherein the elastic structure part forms an outer envelope, and a fluid having an electromagnetic wave shielding ability is enclosed inside the outer envelope.   The electromagnetic wave shielding structure according to claim 1, wherein the elastic structure portion is made of a rubber material.   2. The electromagnetic wave shielding structure according to claim 1, wherein the elastic structure portion is an electromagnetic wave shielding material dispersed in an elastic member that transmits electromagnetic waves.   The electromagnetic wave shielding structure according to claim 4, wherein the elastic member is a rubber material.   Comprising an elastic structure part for passing electromagnetic waves, and an electromagnetic wave shielding structure part including an electromagnetic wave shielding material, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is controlled according to elastic deformation of the elastic structure part, An electromagnetic shielding structure in which transmission and shielding of electromagnetic waves are controlled.   The elastic structure part forms an outer package, and the electromagnetic wave shielding structure part is made of a fluid having an electromagnetic wave shielding ability enclosed in the outer package, and the elastic structure part is not elastically deformed. The electromagnetic wave shielding structure according to claim 6, wherein the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is exhibited, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is lowered when the elastic structure part is elastically deformed.   The electromagnetic wave shielding structure according to claim 6 or 7, wherein the elastic structure portion is made of a rubber material.   The electromagnetic wave shielding structure part includes an electromagnetic wave shielding material part including a granular electromagnetic wave shielding material, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is exhibited in a state where the elastic structure part is not elastically deformed. The electromagnetic wave shielding structure according to claim 6 or 8, wherein an electromagnetic wave shielding function by the electromagnetic wave shielding structure portion is lowered when the structural portion is elastically deformed.   The electromagnetic wave shielding structure part is an electromagnetic wave shielding structure part having a structure in which a plurality of linear electromagnetic wave shielding members are arranged with a predetermined interval between adjacent linear electromagnetic wave shielding members, The electromagnetic wave shielding function by the electromagnetic wave shielding structure part is exhibited in a state where the elastic structure part is not elastically deformed, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is lowered when the elastic structure part is elastically deformed. 8. The electromagnetic wave shielding structure according to 8.   The electromagnetic wave shielding structure part is a sheet-like electromagnetic wave shielding structure part made of a thread material, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is exhibited in a state where the elastic structure part is not elastically deformed, and the elastic structure The electromagnetic wave shielding structure according to claim 6 or 8, wherein an electromagnetic wave shielding function by the electromagnetic wave shielding structure portion is lowered when the portion is elastically deformed.   Sheet-like electromagnetic shielding structure made of yarn material is a woven sheet-like body made by plain weaving, twill weaving, satin weaving, or entangled weaving (twisting weaving), or weft knitting or warp knitting of yarn material The electromagnetic shielding structure according to claim 11, wherein the electromagnetic shielding structure is a knitted sheet-like body.   The electromagnetic wave shielding structure part is laminated with the elastic structure part being brought into contact with the back surface on one side, and provided with a plurality of slits on the surface facing the one side surface, The electromagnetic shielding function by the electromagnetic shielding structure part is exhibited in a state where the elastic structural part is not elastically deformed, and the electromagnetic shielding function by the electromagnetic shielding structure part is lowered when the elastic structural part is elastically deformed. The electromagnetic wave shielding structure according to 6 or 8.   The electromagnetic wave shielding structure according to claim 13, wherein the slit is composed of a plurality of slits extending in parallel to each other only in one direction, or a plurality of slits extending in different directions are intersected.   The slit is a slit having a depth penetrating from the surface facing the back surface of the electromagnetic shielding structure portion to the back surface, or a slit having a depth from the surface of the electromagnetic shielding structure portion to the back surface. The electromagnetic wave shielding structure according to claim 13 or 14.   The electromagnetic wave shielding structure part is laminated with the elastic structure part being in contact with a back surface on one side, and provided with a plurality of holes on the surface facing the one side surface, The electromagnetic shielding function by the electromagnetic shielding structure part is exhibited in a state where the elastic structural part is not elastically deformed, and the electromagnetic shielding function by the electromagnetic shielding structure part is lowered when the elastic structural part is elastically deformed. The electromagnetic wave shielding structure according to 6 or 8.   The hole has a hole structure having a depth penetrating from the surface facing the back surface of the electromagnetic wave shielding structure portion to the back surface, or a depth from the surface of the electromagnetic wave shielding structure portion to the middle of the back surface. The electromagnetic wave shielding structure according to claim 16, which has a hole structure.   The electromagnetic wave shielding structure part is an electromagnetic wave shielding structure part made of a coating film formed by applying a paint containing an electromagnetic wave shielding material to at least one surface of the elastic structure part, and the elastic structure part is elastically deformed. The electromagnetic wave shielding structure according to claim 6 or 8, wherein an electromagnetic wave shielding function by the electromagnetic wave shielding structure part is exhibited in a state where the electromagnetic wave shielding structure is not provided, and the electromagnetic wave shielding function by the electromagnetic wave shielding structure part is lowered when the elastic structure part is elastically deformed.

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