JP4715643B2 - Radio wave directivity control device - Google Patents

Description

  The present invention relates to an apparatus for controlling the directivity of radio waves in an antenna of an electronic device or the like.

  In recent years, a wireless local area network (LAN) is rapidly spreading in the construction of a network for interconnecting personal computers and printers. The wireless LAN is a LAN that transmits and receives data by wireless communication, and is notable because it has no restrictions such as wiring by cables. However, since most of the built-in antennas of electronic devices used for this wireless LAN are non-directional, when using a wireless LAN in a place with a large number of households such as office buildings and condominiums, the radio waves radiated from the antennas are not. Also leaks to nearby rooms. For this reason, some measures are necessary from the security aspect. Conventionally, various techniques for controlling the directivity have been proposed (for example, see Patent Documents 1 to 3).

  In Patent Document 1, as shown in FIG. 1 of the publication, an antenna element (12) is arranged in the center of the cavity (15), and a U-shaped conductor is arranged around the antenna (12). An antenna is described. In this antenna, bi-directionality is obtained by such a structure.

  Patent Document 2 describes an antenna device in which a reflector is arranged around a standing omnidirectional antenna. The reflector has a detachable roof portion extending upward from the antenna, and the radiation pattern (directivity) in the vertical plane is inclined downward by attaching the roof portion as appropriate. .

Patent Document 3 describes an antenna configured by inserting a cylindrical reflector into an element portion (antenna element). In this antenna, directivity in a specific direction is formed by appropriately rotating a cylindrical reflector.
JP 2002-305410 A (Claim 1, paragraphs 0044 to 0047, FIG. 1) JP 2004-282316 A (Claim 1, paragraphs 0018 to 0023, FIG. 2) JP 2002-322010 A (Claim 1, paragraphs 0030 and 0031, FIG. 2)

  However, in the prior art, in order to change the direction of the radio wave radiated from the built-in antenna of the electronic device, the outer case of the electronic device is removed in order to attach / detach the reflector or change the direction of the reflector. Without it, I couldn't work. Therefore, it has been difficult for a general user to control the directivity of a built-in radio wave according to the usage state of each electronic device.

  Therefore, in order to solve such a problem, it is an object to provide a radio wave directivity control device that allows a general user to easily control the radio wave directivity according to the use state of an electronic device in a wireless LAN. And

As a means for solving the above-mentioned problems, the invention according to claim 1 is a radio wave directivity control device including a shielding unit main body in which an electronic device having an antenna is installed. The shielding unit main body , comprising: an opening having a shielding property and an opening in a predetermined direction; and an opening adjusting unit capable of adjusting an opening area and an opening position of the opening and having a radio wave shielding property ; Each of the opening adjustment portions is formed in a substantially semi-cylindrical shape, and is configured to be combined in a substantially cylindrical shape when the opening adjustment portion covers the opening. The part is configured to be slidable along the curved surface of the shielding part main body .

According to such a radio wave directivity control device, by installing the electronic device inside the shielding unit main body, the antenna of the electronic device is shielded from the radiated radio wave by the shielding unit main body, and its directivity changes. It is done. Further, by adjusting the opening area and the opening position of the opening by the opening adjusting unit, the direction and range of radio waves radiated from the antenna are changed, and are directed in a predetermined direction. Thereby, the directivity of the radio wave can be controlled. Furthermore, the radio wave radiated from the antenna can be shielded and changed in direction and range only by sliding the opening adjustment unit, and is directed in a predetermined direction. Thereby, the directivity of the radio wave can be controlled within a predetermined range.

The invention according to claim 2 is a radio wave directivity control device including a shielding unit main body in which an electronic device having an antenna is installed, and the shielding unit main body has radio shielding properties and has a predetermined direction. And an opening adjustment portion that can adjust an opening area and an opening position of the opening and has a radio wave shielding property, and the opening adjustment portions move with each other along the same rail. It is composed of a pair of possible sliding doors, and at least a part of the edge of the opening is provided with a flange having conductivity so as to be orthogonal to the sliding door at the edge. To do.

According to such a radio wave directivity control device, by installing the electronic device inside the shielding unit main body, the antenna of the electronic device is shielded from the radiated radio wave by the shielding unit main body, and its directivity changes. It is done. In addition, by simply sliding the sliding door that constitutes the opening adjustment section, the opening adjustment section adjusts the opening area and opening position of the opening so that the radio waves radiated from the antenna can be shielded and The range is changed and heads in a predetermined direction. Thereby, the directivity of the radio wave can be controlled within a predetermined range.

The invention according to claim 3 is the radio wave directivity control apparatus according to claim 2, wherein the shield body and the opening adjusting unit, while being formed substantially semi-cylindrical shape, respectively, the opening adjuster Is configured to be combined in a substantially cylindrical shape when covering the opening, and the opening adjusting portion is configured to be slidable along the curved surface of the shielding portion main body. .

  According to such a radio wave directivity control device, the radio wave radiated from the antenna is changed in the shielding direction and range only by sliding the opening adjustment unit, and is directed in a predetermined direction. Thereby, the directivity of the radio wave can be controlled within a predetermined range.

According to a fourth aspect of the present invention, in the radio wave directivity control device according to any one of the first to third aspects, a radio wave radiated from the antenna is provided on at least a part of a portion facing the electronic device. It has a radio wave absorptivity that absorbs water.

  According to such a radio wave directivity control device, of the radio waves radiated from the antenna, the radio waves of the respective parts (the first shielding part, the second shielding part, the third shielding part, the shielding part main body, the opening part adjusting part). The radio wave radiated toward the absorber is attenuated. Thereby, it is possible to prevent the interference phenomenon and the resonance phenomenon between the radio wave radiated from the antenna and the radio wave reflected from each part.

The invention according to claim 5 is the radio wave directivity control apparatus according to claim 4 , wherein the radio wave absorptivity is achieved by including a λ / 4 type radio wave absorber.

  According to such a radio wave directivity control device, it becomes easy to deal with radio waves in a specific frequency band.

The invention according to claim 6 is the radio wave directivity control device according to any one of claims 1 to 5 , wherein the shielding part main body includes a magnetic sheet.

  According to such a radio wave directivity control device, it is possible to effectively prevent eddy currents generated inside the conductive plate due to the radio waves radiated from the antenna. As a result, it is possible to prevent a phenomenon in which radio waves wrap around the shielding unit main body. In particular, it is preferable to attach a magnetic sheet to the conductive plate on the back side opposite to the opening.

The invention according to claim 7 is the radio wave directivity control apparatus according to claim 4 , wherein the radio wave absorptivity is achieved by having a broadband radio wave absorber.

  According to such a radio wave directivity control device, since the frequency band that can be absorbed is wide, various types of electronic devices can be selected. The broadband wave absorber is, for example, a resistive film sheet (impedance 1088Ω), a spacer (38 mm), a resistive film sheet (impedance 280Ω), a spacer (38 mm), a protective film (aluminum plate (foil)) )) In the order of arrangement.

The invention according to claim 8 is the radio wave directivity control apparatus according to any one of claims 1 to 7 , wherein the shielding unit body includes a metal casing having radio wave shielding properties. It is characterized by.

  According to such a radio wave directivity control device, radio waves radiated from the antenna toward the housing can be reliably prevented from leaking from the inside of the shielding unit main body in a specific direction. Can effectively prevent the emission of radio waves.

The invention according to claim 9 is the radio wave directivity control device according to claim 8 , wherein the casing is configured by assembling a plurality of metal members, and the plurality of metal members are joined by welding. It is characterized by being.

  According to such a radio wave directivity control device, radio waves radiated from the antenna toward the housing can be reliably prevented from leaking from the joint portion of the metal member. Can effectively prevent radio waves from being emitted.

The invention according to claim 10 is the radio wave directivity control apparatus according to claim 8 or 9 , wherein the casing is made of aluminum or an aluminum alloy.

  According to such a radio wave directivity control device, it is possible to reduce the weight of the casing, to treat the surface with an anodized film, and to provide a radio wave directivity control device with a beautiful appearance. it can.

The invention according to claim 11 is the radio wave directivity control device according to any one of claims 1 to 10 , wherein the shielding body is prevented from being interfered with by radio waves from outside the shielding body. It is characterized by having an EMI duct that enables wiring of cables inside.

  According to such a radio wave directivity control device, a cable can be wired from the outside to the inside while preventing radio wave interference. An EMI (Electro Magnetic Interference) duct is a cable that wraps a noise suppression sheet such as magnetic tape around a cable and passes a part of this cable through a duct installed in the shield body. It is provided and is provided in the shielding part main body through a gasket having insulation resistance. According to this EMI duct, electromagnetic interference can be suitably prevented by wiring the cable so that a predetermined length (for example, 100 mm or more) of the cable passes through the EMI duct.

According to a twelfth aspect of the present invention, in the radio wave directivity control device according to the eleventh aspect , a cable is disposed from the outside to the inside of the shielding portion main body via the EMI duct, and the cable is a noise It is characterized by being coated with a noise absorber that absorbs water.

  According to such a radio wave directivity control device, it is possible to reliably prevent noise from being generated from the cable, and to reliably prevent malfunction of the electronic device.

The invention according to claim 13 is the radio wave directivity control device according to any one of claims 1 to 12 , characterized in that the shielding part main body includes illumination therein.

  According to such a radio wave directivity control device, the inside of the shielding unit main body can be illuminated brightly. Illumination includes incandescent bulbs and LED lamps (Light Emitting Diode Lump), and LED lamps are particularly preferable. This is because, unlike a fluorescent lamp, an LED lamp hardly generates noise when blinking.

The invention according to claim 14 is the radio wave directivity control device according to any one of claims 1 to 13 , wherein the shielding unit main body is arranged so as to cover the electronic device installed inside the building. It is provided.

  According to such a radio wave directivity control device, it is possible to control the radio wave directivity within a predetermined range even for an electronic device installed inside a building, by simply adjusting the opening of the shield main body. it can. In addition, since the shielding unit body has radio wave shielding and radio wave absorption properties, radio waves radiated from electronic devices in directions other than the opening are attenuated inside the shielding unit body, so interference and The resonance phenomenon can be prevented.

  According to the present invention, the general user can easily control the directivity of the radio wave according to the usage state of the electronic device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate. In the following embodiments, a case where the present invention is applied to a wireless LAN router as a target electronic device will be described.

[First Embodiment]
FIG. 1 is a diagram illustrating an environment in which the radio wave directivity control apparatus according to the first embodiment is used, and FIG. 2 is a perspective view of the radio wave directivity control apparatus according to the first embodiment.

  As shown in FIG. 1, a wireless LAN router R is installed in each of the rooms A1 and A2 such as an office building or a condominium. The router R is a device that relays communication between networks, and has an antenna Ra that transmits and receives radio waves. The radio wave directivity control device 1 according to the present embodiment is installed around the router R, and controls the radio wave directivity so that the radio waves of the antenna Ra of the router R do not leak into the rooms A1 and A2. Device.

  As shown in FIG. 2, the radio wave directivity control device 1 includes a back surface portion (first shielding portion) 11, a louver (second shielding portion) 12 connected to an upper end portion of the back surface portion 11, and a back surface portion 11. And a mounting table 13 fixed to the lower end of the.

  The back surface portion 11 has a rectangular metal plate 11a that reflects radio waves, and a radio wave absorber 14 having substantially the same shape as the metal plate 11a is provided on the front side (radio wave incident surface side) of the metal plate 11a. In addition. The metal plate 11a is, for example, aluminum or an aluminum alloy. Details of the radio wave absorber 14 will be described later.

  The louver 12 is connected to the upper end portion of the back surface portion 11 via a hinge H, and is rotatable with respect to the back surface portion 11. The louver 12 has a rectangular metal plate 12a that reflects radio waves, similarly to the back surface portion 11, and has a radio wave having substantially the same shape as the metal plate 12a on the front side (radio wave incident side) of the metal plate 12a. An absorber 14 is further provided. The metal plate 12a is, for example, aluminum or an aluminum alloy. Since the structure of the radio wave absorber 14 in the louver 12 is the same as that of the radio wave absorber 14 in the back surface part 11, the detailed description thereof will be made later with the description of the radio wave absorber 14 in the back surface part 11. Is omitted.

  The mounting table 13 is a table on which the router R is mounted. The mounting table 13 is fixed so as to be orthogonal to the lower end portion of the back surface portion 11, and is held horizontally when installed in the room of each of the rooms A1 and A2 (see FIG. 1). Is done. The mounting table 13 includes a mounting table main body 13a and a radio wave absorbing sheet 13b provided on the upper surface of the mounting table main body 13a and having radio wave absorption. Thereby, the radio wave radiated from the antenna Ra of the router R is absorbed by the radio wave absorbing sheet 13b, and the resonance of the radio wave due to reflection is suppressed.

  As the radio wave absorbing sheet 13b, for example, a radio wave absorbing sheet called a dipole type can be used. The dipole type electromagnetic wave absorbing sheet is (1) a sheet that is formed from a compound such as carbon powder and titanium oxide, and that absorbs radio waves by utilizing the electric field of this compound (for example, change in electronic configuration) (2) As described in, for example, Japanese Patent No. 3040953, a magnetic field formed by a compound of Mn—Zn ferrite powder, carbonyl iron, etc. and EPDM (ethylene propylene diene monomer) rubber is included. A sheet that absorbs radio waves when used (for example, a magnetic field changes), or (3) a sheet in which a resin (for example, polyurethane) and a magnetic material are combined. Specifically, for example, Lumidion (registered trademark) manufactured by Toyo Service Co., Ltd. and HTD-101 manufactured by Hitachi Metals Co., Ltd. can be used as the radio wave absorbing sheet. In addition, since such a radio wave absorption sheet absorbs radio waves in a wide band, it may be referred to as a broadband absorber.

FIG. 3 is an enlarged cross-sectional view of the side surface of the back surface portion.
As shown in FIG. 3, the radio wave absorber 14 is a λ / 4 type radio wave absorber, and in order from the metal plate 11a side, a spacer 14a and a resistive film sheet 14b having a function of transmitting half of the radio wave, And a protective film 14c for protecting the resistance film sheet 14b. The metal plate 11a and the radio wave absorber 14 have functions of radio wave shielding and radio wave absorptivity in the back surface part 11 (or louver 12).

  The spacer 14a is for setting the interval between the metal plate 11a and the resistive film sheet 14b to λ / 4 when the wavelength of the radio wave radiated from the router R is λ, and has a thickness T1 of λ / 4. Have. The spacer 14a has radio wave permeability and is made of, for example, foamed plastic such as polystyrene foam. Thus, when formed from a polystyrene foam, thickness T1 of the spacer 14a can be adjusted easily.

  The resistance film sheet 14b is a thin sheet adjusted so that the surface resistance value thereof is substantially equal to the impedance (376.6Ω) of free space. As such a resistance film sheet 14b, a sheet obtained by applying a carbon conductive paint to an appropriate base sheet, a film formed by adjusting the resistance value of the ITO film, or the like can be used.

  The protective film 14c is laminated on the surface of the resistance film sheet 14b, and protects the surface of the resistance film sheet 14b.

  And the surface of such a wave absorber 14 is flat. Thereby, compared with the case where a some convex wave absorber is provided, the external shape can be made small as a whole, for example.

Here, the mechanism of radio wave absorption by the radio wave absorber 14 will be described.
When the radio wave W1 radiated from the antenna Ra (see FIG. 1) of the router R is incident from the vertical direction of the protective film 14c, after passing through the protective film 14c, half of it passes through the resistive film sheet 14b. 1/2 is reflected by the resistive film sheet 14b. Here, a radio wave that has passed through the resistive film sheet 14b is a radio wave W2, and a reflected radio wave is a radio wave W3. After traveling through the spacer 14a, the radio wave W2 is reflected by the metal plate 11a and becomes radio wave W4. Note that the phase of the radio wave is inverted upon reflection on the resistance film sheet 14b and the metal plate 11a.

  Then, after the reflection on the metal plate 11a, the radio wave W4 reaching the resistance film sheet 14b is twice the thickness T1 of the spacer 14a with respect to the radio wave W3 reflected on the resistance film sheet 14b, that is, “λ / 4 × 2 = λ / 2 ”, and the phases of the radio wave W3 and the radio wave W4 are reversed. Accordingly, the radio wave W3 and the radio wave W4 cancel each other, and as a result, the radio wave W1 incident on the resistive film sheet 14b is absorbed in a pseudo manner.

  The operation of the radio wave directivity control apparatus 1 configured as described above will be described with reference to FIG. FIG. 4 is a side view for explaining the operation of the radio wave directivity control device.

  As shown in FIG. 4, the radio wave directivity control device 1 has the back surface portion 11 attached to the walls of the rooms A <b> 1 and A <b> 2 with the router R mounted on the mounting table 13 (see FIG. 1). ). In the radio wave directivity control device 1, radio waves radiated from the antenna Ra of the router R are absorbed by the back surface portion 11, and leakage to a room adjacent to the back surface side is prevented.

  In the radio wave directivity control device 1, the directivity of radio waves radiated from the antenna Ra of the router R is controlled by rotating the louver 12 with respect to the back surface portion 11. That is, when the angle of the louver 12 with respect to the back surface portion 11 is large, the radio wave radiated from the antenna Ra is directed upward without any interference. For example, the radio wave is emitted from the room A2 shown in FIG. As shown in FIG. 4, if the angle of the louver 12 with respect to the back surface portion 11 is reduced, the radio wave radiated from the antenna Ra is reflected to the louver 12 to shield the radio wave going upward and downward. Can be controlled to go to. This angle can be set as appropriate.

According to the above, the following effects can be obtained in the present embodiment.
According to such a radio wave directivity control device 1, the antenna Ra included in the router R is shielded by the back surface portion 11 and the louver 12 by being installed around the router R.

  Further, by appropriately rotating the louver 12, the radio wave radiated from the antenna Ra is changed in the shielding direction and range and is directed in a predetermined direction. Thereby, the directivity of the antenna Ra can be controlled.

  Furthermore, since the back surface portion 11 and the louver 12 have radio wave absorptivity, the radio waves radiated from the antenna Ra of the router R toward the back surface portion 11 and the louver 12 are attenuated. Thereby, the interference phenomenon and resonance phenomenon of the radio wave radiated from the antenna Ra and the radio wave reflected from the back surface part 11 and the louver 12 can be prevented.

  As mentioned above, although this Embodiment was demonstrated, this invention is not limited to the said embodiment, It can implement with a various form.

FIG. 5 is a side view of a radio wave directivity control apparatus according to a modification of the first embodiment.
As shown in FIG. 5, in the radio wave directivity control device 1 </ b> A according to the modification, the slide unit 15 may be provided on the louver 12 of the radio wave directivity control device 1 (see FIG. 4). The slide portion 15 includes a slide body 15a having the same structure as the back surface portion 11 and a slide body case 15b. The slide body 15a is configured to be able to appear and retract from the slide body case 15b. In this radio wave directivity control device 1, by pulling out the slide body 15a from the slide body case 15b, it is possible to secure a wide range in which the radio wave radiated upward from the antenna Ra is reflected, and to better control the directivity. can do.

  In the embodiment, the radio wave absorber 14 is a λ / 4 type radio wave absorber, but the radio wave absorber is not particularly limited. For example, from the side of the radio wave absorber 13b described above, that is, from the metal plate 11a (or 12a) side, a resistive film sheet (impedance 1088Ω), a spacer (38mm), a resistive film sheet (impedance 280Ω), a spacer (38mm ) And a protective film (aluminum plate (foil)) in this order. According to such a configuration, two types of radio waves around 880 MHz and 2050 MHz can be absorbed.

  The material of the metal plates 11a and 12a is not limited to aluminum or the like, and may be other materials such as steel, stainless steel, or copper as long as it has conductivity.

[Second Embodiment]
Next, the radio wave directivity control apparatus according to the second embodiment will be described.
FIG. 6 is a perspective view of the radio wave directivity control apparatus according to the second embodiment. Note that in the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

  As shown in FIG. 6, the radio wave directivity control device 2 according to the second embodiment is installed around a router R having an antenna Ra. Then, the radio wave directivity control device 2 controls the directivity of the radio wave so that the radio wave of the antenna Ra does not leak in a predetermined direction, as in the first embodiment.

  The radio wave directivity control device 2 includes a rear surface portion (first shielding portion) 21 and louvers (second and third shielding portions) 22 and 22 attached to both ends of the rear surface portion 21 via hinges H. I have. In other words, the louver 22 is attached to one end portion of the back surface portion 21, and the louver 22 is attached to the opposite end portion.

  The back surface portion 21 has a rectangular metal plate 21a that reflects radio waves, and a radio wave absorber 14 having substantially the same shape as the metal plate 21a is provided on the front side (radio wave incident surface side) of the metal plate 21a. In addition. The metal plate 21a is, for example, aluminum or an aluminum alloy.

  The louvers 22, 22 are connected to both sides of the back surface portion 21 via hinges H, and are rotatable with respect to the back surface portion 21. The louver 22 has a rectangular metal plate 22a that reflects radio waves, like the back surface portion 21, and has a radio wave having substantially the same shape as the metal plate 22a on the front side (radio wave incident side) of the metal plate 22a. An absorber 14 is further provided. The metal plate 22a is, for example, aluminum or an aluminum alloy. The radio wave absorption mechanism of the louver 22 and the back portion 21 is the same as that in the first embodiment.

  The operation of the radio wave directivity control device 2 configured as described above will be described with reference to FIG. FIG. 7 is a plan view for explaining the operation of the radio wave directivity control device.

  As shown in FIG. 7, the radio wave directivity control device 2 is installed around the router R in each room (not shown). In the radio wave directivity control device 2, radio waves radiated from the antenna Ra of the router R are absorbed by the back surface portion 21, and leakage of radio waves to the back surface side is prevented.

  Further, the radio wave directivity control device 2 controls the directivity of radio waves radiated from the antenna Ra of the router R by rotating the louvers 22 and 22 with respect to the back surface portion 21. That is, when the angle of the louvers 22 and 22 with respect to the back surface portion 21 is large, the radio wave from the antenna Ra is radiated in a wide range without any interference, and the radio wave leaks in the left-right direction. As shown in FIG. 4, if the angle of the louver 22 with respect to the back surface portion 21 is reduced, the radio wave radiated from the antenna Ra is reflected to the louver 22 so that the radio wave directed to the left and right is shielded and radiated to a narrow range. can do. This angle can be set as appropriate.

According to the above, the following effects can be obtained in the present embodiment.
According to such a radio wave directivity control device 2, the antenna Ra included in the router R is shielded by the back surface portion 21 and the louver 22 by being installed around the router R.

  Further, by appropriately rotating the louver 22, the radio wave radiated from the antenna Ra is changed in the shielded direction and range, and is directed in a predetermined direction. Thereby, the directivity of the antenna Ra can be controlled.

  Furthermore, since the back surface portion 21 and the louver 22 have radio wave absorptivity, the radio waves radiated from the antenna Ra of the router R toward the back surface portion 11 and the louver 12 are attenuated. Thereby, the interference phenomenon and resonance phenomenon of the radio wave radiated from the antenna Ra and the radio wave reflected from the back surface part 11 and the louver 12 can be prevented.

  As mentioned above, although this Embodiment was demonstrated, this invention is not limited to the said embodiment, It can implement with a various form.

  For example, the thickness of the radio wave absorber 14 used for the louver 22 may be set so as to gradually decrease from the base end side toward the front end side (according to the direction in which radio waves are emitted). Since the incident angle of the radio wave radiated from the antenna Ra of the router R to the louver 22 becomes smaller toward the tip side, the radio wave can be effectively absorbed according to the above-described configuration. The radio wave absorption characteristics can be effectively exhibited by designing the radio wave absorber 14 in consideration of the frequency and incident angle of radio waves used in advance.

[Third Embodiment]
Next, a radio wave directivity control apparatus according to the third embodiment will be described.
FIG. 8 is a perspective view of the radio wave directivity control device according to the third embodiment, FIG. 9A is a plan sectional view for explaining the operation of the radio wave directivity control device, and FIG. It is a principal part enlarged view of the slide door of FIG. Note that in the third embodiment, identical symbols are assigned to configurations identical to those in the first embodiment and descriptions thereof are omitted.

  As shown in FIG. 8, the radio wave directivity control device 3 according to the third embodiment has a router R having an antenna Ra installed therein. Then, similarly to the first embodiment, the radio wave directivity control device 3 controls the directivity of the radio wave so that the radio wave of the antenna Ra does not leak in a predetermined direction.

  The radio wave directivity control device 3 includes a shielding body 31, a pair of sliding doors (opening adjustment parts) 32, 32 provided on the shielding body 31, and opposite ends of the sliding doors 32, 32. And flange portions 33, 33 provided on the.

  The shielding part main body 31 includes, for example, a main body (housing) 31a formed of a metal such as aluminum or aluminum alloy in a substantially U-shaped cross section, and a radio wave absorber provided on the inner surface side of the main body 31a. 14. Rails 31b are provided on the opposing surfaces of the top plate and the bottom plate of the shielding portion main body 31 so as to follow the outer peripheral edge thereof. As shown in FIG. 9A, both end portions of the rail 31b extend in parallel so as not to cross each other on the back side. The main body 31a is made of a metal such as aluminum or an aluminum alloy, for example.

  As shown in FIG. 9B, the slide doors 32, 32 have a plurality of elongated rectangular metal members 32a and the radio wave absorber 16 provided on the inner surface side of the metal members 32a.

  The metal member 32a is made of, for example, an extruded material such as aluminum or aluminum alloy. The metal member 32a is formed in a shape in which both end portions are bent along the longitudinal direction, and the radio wave absorber 16 is disposed so as to be fitted inside the metal member 32a. Has been. The radio wave absorber 16 is not particularly limited as long as it has a function of absorbing radio waves, and may be the same as the radio wave absorber 14 described above. Further, a spherical fitting portion K1 and a fitting portion K2 having a C-shaped cross section that can be externally fitted to the fitting portion K1 are formed at the tip of the metal member 32a. The plurality of metal members 32a are externally fitted to the fitting portions K1 of the metal members 32a adjacent to each other, and are connected to each other.

  The flange parts 33 and 33 are comprised by the rectangular-shaped metal plate 33, and are attached to the metal members 32a and 32a of both ends among the connected metal members 32b via the hinge H. . The electromagnetic wave absorption mechanism of the shielding part main body 31 and the slide door 32 is the same as that of the first embodiment.

  The slide doors 32, 32 configured as described above further have a roller (not shown) on the upper end surface or the lower end surface thereof, and this roller is fitted into the rail 31b (see FIG. 9A) of the shielding portion main body 31. It is. Then, in a state where the flange portions 33 face each other and come into contact with each other, the end portions of the slide doors 32 and 32 opposite to the flange portions 33 and 33 extend to the back side of the shielding portion main body 31, and the shielding portion main body 31. All the openings are covered. Further, the slide doors 32 and 32 are movable along the rail 31b, respectively, and an opening 31c formed by the shielding portion main body 31 and the slide door 32 (FIG. 9A) by appropriately moving the slide doors 32 and 32. The area and position can be adjusted.

The operation of the radio wave directivity control device 3 configured as described above will be described.
As shown in FIG. 9A, the radio wave directivity control device 3 has a router R installed therein. In this radio wave directivity control device 3, radio waves radiated from the antenna Ra of the router R are absorbed by the shielding part main body 31 to prevent leakage of radio waves in a predetermined direction on the back side, top side, and bottom side. .

  Further, in the radio wave directivity control device 3, the directivity of the radio waves radiated from the antenna Ra of the router R is controlled by appropriately moving the slide doors 32 and 32 along the rail 31b. Specifically, the area of the opening 31c can be increased by moving the flanges 33 and 33 side of the sliding doors 32 and 32 in a direction away from each other, and the radio wave from the antenna Ra is radiated in a wide range. Can be made. Further, the area of the opening 31c can be reduced by moving the flange portions 33, 33 side of the slide doors 32, 32 in the direction close to each other, and the radio wave from the antenna Ra is directed in a certain narrow range. It can be controlled to be emitted only to

  Moreover, the position of the opening part 31c can be changed by changing how the slide doors 32 and 32 are opened. For example, by opening only one of the slide doors 32, 32, the position of the opening 31c can be brought closer to one side. Thereby, the area and position of the opening 31c from which radio waves are radiated can be set as appropriate.

  Further, since the flange portions 33 and 33 can be appropriately rotated, for example, by raising the flange portions 33 and 33 so as to be orthogonal to the opening portion 31c, the radio wave radiated from the antenna Ra is changed to the opening portion. The phenomenon of diffraction at the edge of 31c can be prevented, and the directivity of radio waves can be more reliably controlled within a predetermined range.

According to the above, the following effects can be obtained in the present embodiment.
According to such a radio wave directivity control device 3, by installing the router R inside, the antenna Ra included in the router R is shielded from the radiated radio waves by the shielding body 31 and the slide doors 32 and 32. The

  Further, by appropriately moving the slide doors 32, 32, the radio wave radiated from the antenna Ra is changed in the direction and range of shielding, in other words, the area and position of the opening 31c are changed, and a predetermined direction is obtained. Head for. Thereby, the directivity of the antenna Ra can be controlled.

  Furthermore, since the shielding part main body 31 and the slide doors 32 and 32 have radio wave absorptivity, the radio wave radiated from the antenna Ra of the router R is radiated toward the shielding part main body 31 and the sliding doors 32 and 32. Radio waves are attenuated. Thereby, the interference phenomenon and the resonance phenomenon of the radio wave radiated from the antenna Ra and the radio wave reflected from the shield main body 31 and the slide doors 32 and 32 can be prevented.

  As mentioned above, although this Embodiment was demonstrated, this invention is not limited to the said embodiment, It can implement with a various form.

  In the above embodiment, the flange portion 33 is rotatably attached to the slide door 32. However, the flange portion 33 may be omitted, or the flange portion 33 may be fixed to the slide door 32.

  In the above embodiment, the radio wave absorber 14 is provided as it is on the metal member 32a of the slide door 32. However, for example, the metal member 32a may be coated with a magnetic material.

  In the said embodiment, although the shielding part main body 31 was formed in cross-sectional substantially U shape, the shape of the shielding part main body 31 is not limited, What is formed in the box shape etc. which only one surface with a rectangular parallelepiped opened. It may be.

FIG. 10 is a plan sectional view of a radio wave directivity control apparatus according to a modification of the third embodiment.
As shown in FIG. 10, the radio wave directivity control device 3 </ b> A is attached to a box-shaped shielding part main body 35 having only one surface opened, and to an opening end of the shielding part main body 35 so as to be rotatable via a hinge H. A pair of door portions 36 and 36 can also be used.

  The shield body 35 is welded in a state where, for example, five metal plates 35a formed of aluminum or aluminum alloy are assembled in a box shape, and the radio wave absorber 14 is provided on the inner surface side of each of the metal plates 35a. ing. Further, an LED lamp (illumination) 37 is provided inside the shielding part main body 35 so that the inside can be illuminated. The LED lamp 37 is suitable because it hardly generates noise when blinking. Further, an EMI duct 38 is provided outside the shielding part main body 35. The cable C of the router R is covered with a noise absorber, and the cable C can be inserted into the EMI duct 38 and wired in the shielding unit main body 35. Thereby, electromagnetic interference can be suitably prevented. Note that a magnetic sheet may be provided on the metal plate 35 a of the shielding unit main body 35. By providing the magnetic sheet, eddy currents generated in the metal plate 35a can be prevented.

  The magnetic sheet is a sheet in which a magnetic particle filler is dissolved in a binder and printed or coated on a base material such as PET to form the magnetic particles as a thin layer on one surface of the base material. The surface on which the magnetic particles are formed is attached to the inner surface of the metal plate 35a. When the magnetic sheet is attached in this way, the thin layer of magnetic particles is placed in close contact with the inner surface of the metal plate 35a. The magnetic field strength of the electromagnetic wave is increased at the interface of the metal plate 35a. However, when the magnetic material sheet is attached, the thin layer of the magnetic material particles is brought into close contact with the inner surface of the metal plate 35a, and the electromagnetic wave absorption characteristics are effectively exhibited.

The thickness of the magnetic material sheet is preferably 100 to 500 μm. When the thickness is less than 100 μm, it is not preferable because the magnetic particles do not sufficiently function with respect to the electromagnetic field. When the thickness exceeds 500 μm, it is not preferable because it is a thickness of a region where the effect of magnetic particles is reduced. The average particle size of the magnetic material is preferably 5 to 30 μm. When the average particle size is less than 5 μm, the magnetic particles are aggregated and a uniform thin layer cannot be formed. When the average particle diameter of the magnetic material exceeds less than 30 μm, the radio wave absorption characteristics are deteriorated. The shape of the magnetic body is preferably a flat shape or a needle shape. In the case of a flat magnetic body, the flatness is preferably 10 or more. When the flatness is less than 10, it is necessary to make the average particle size very small in order to form a thin layer, making it difficult to efficiently form a thin layer. The magnetic body should have a high magnetic permeability, preferably a magnetic permeability of 1000 [NA ⁻² ] or more, and more preferably 5000 [NA ⁻² ] or more.

[Fourth Embodiment]
Next, a radio wave directivity control apparatus according to the fourth embodiment will be described.
FIG. 11 is a perspective view of the radio wave directivity control device according to the fourth embodiment, and FIG. 12 is a plan sectional view for explaining the operation of the radio wave directivity control device. Note that in the fourth embodiment, identical symbols are assigned to configurations identical to those in the first embodiment and descriptions thereof are omitted.

  As shown in FIG. 11, the radio wave directivity control device 4 according to the third embodiment installs a router R having an antenna Ra inside. Then, similarly to the first embodiment, the radio wave directivity control device 4 controls the directivity of the radio waves so that the radio waves of the antenna Ra do not leak into each room.

  The radio wave directivity control device 4 includes a shielding part main body 41 and a slide door (opening adjustment part) 42 provided on the shielding part main body 41.

  The shielding part main body 41 is formed in a semicylindrical shape as a whole, and the upper surface is formed in a shape in which a large semicircle and a small semicircle are opposed to each other. In addition, a flange portion 43A is provided on one of the open end portions of the shielding portion main body 41 along the vertical direction. Such a shielding unit main body 41 includes, for example, a main body (housing) 41a formed in a shape described above from a metal such as aluminum or aluminum alloy, and a radio wave absorber provided on the inner surface side of the main body 41a. 14.

  The slide door 42 is formed in a semi-cylindrical shape that is slightly smaller than the shielding part main body 41 and is accommodated in the shielding part main body 41. The upper surface of the sliding door 42 is configured to be rotatable with respect to the shielding unit main body 41 by being attached to the upper surface of the shielding unit main body 41 via a pin P. When the sliding door 42 is combined with the shielding part main body 41, the sliding door 42 has a substantially cylindrical shape. And the area of the opening part 41c of the shielding part main body 41 can be suitably adjusted with rotation of the slide door 42. FIG. The bottom surface of the slide door 42 is formed in a circular shape so that the router R can be installed. A flange portion 43B is formed on one of the open ends of the slide door 42 along the vertical direction. The slide door 42 configured as described above includes, for example, a main body 42a formed in a shape as described above from a metal such as aluminum or aluminum alloy, and a radio wave absorber 14 provided on the inner surface side of the main body 41a. ,have. Note that the electromagnetic wave absorption mechanism of the shielding unit main body 41 and the slide door 42 is the same as that of the first embodiment.

The operation of the radio wave directivity control device 4 configured as described above will be described.
As shown in FIG. 12, the radio wave directivity control device 4 is placed with a router R installed therein in each room (not shown). In the radio wave directivity control device 4, radio waves radiated from the antenna Ra of the router R are absorbed by the shielding unit main body 41, and leakage of radio waves in a predetermined direction on the back side, the top side, and the bottom side is prevented. .

  In the radio wave directivity control device 4, the directivity of the radio wave radiated from the antenna Ra of the router R is controlled by appropriately rotating the slide door 42. Specifically, by rotating the flange portion 43B side of the slide door 42 in a direction away from the flange portion 43A side, the area of the opening 41c can be increased, and the radio wave from the antenna Ra can be spread over a wide range. Can be emitted. Further, by rotating the flange portion 43B side of the slide door 42 in the direction approaching the flange portion 43A side, the area of the opening 41c can be reduced, and the radio wave from the antenna Ra can be transmitted within a certain narrow range. It can be controlled to radiate only in the direction.

According to the above, the following effects can be obtained in the present embodiment.
According to such a radio wave directivity control device 4, by installing the router R inside, the antenna Ra included in the router R shields the radiated radio waves by the shield main body 41 and the slide door 42.

  Further, by appropriately rotating the slide door 42, the direction and range of radio waves radiated from the antenna Ra can be changed. In other words, the area and position of the opening 41c can be changed, and the predetermined direction can be obtained. Head. Thereby, the directivity of the antenna Ra can be controlled.

  Furthermore, since the shielding part main body 41 and the slide door 42 have radio wave absorptivity, the radio waves radiated from the antenna Ra of the router R toward the shielding part main body 41 and the slide door 42 are attenuated. The Thereby, the interference phenomenon and the resonance phenomenon of the radio wave radiated from the antenna Ra and the radio wave reflected from the shielding part main body 41 and the slide door 42 can be prevented.

  The flange portions 43A and 43B can prevent the phenomenon in which the radio wave radiated from the antenna Ra is diffracted at the edge of the opening 41c, and more reliably control the directivity of the radio wave within a predetermined range. be able to.

  As mentioned above, although this Embodiment was demonstrated, this invention is not limited to the said embodiment, It can implement with a various form.

  In the said embodiment, although flange part 43A, 43B was comprised as a part of shielding part main body 41 or the slide door 42, you may comprise separately, so that attachment is possible.

It is a figure which shows the environment where the radio wave directivity control apparatus which concerns on 1st Embodiment is used. 1 is a perspective view of a radio wave directivity control device according to a first embodiment. It is a cross-sectional enlarged view of the side surface of a back part. It is a side view explaining the effect | action of a radio wave directivity control apparatus. It is a side view of the radio wave directivity control device concerning the modification of a 1st embodiment. It is a perspective view of the radio wave directivity control device according to the second embodiment. It is a top view explaining the effect | action of a radio wave directivity control apparatus. It is a perspective view of the radio wave directivity control device concerning a 3rd embodiment. (A) is a plane sectional view explaining an operation of the radio wave directivity control device, and (b) is an enlarged view of a main part of the slide door of (a). It is a plane sectional view of the radio wave directivity control device concerning the modification of a 3rd embodiment. It is a perspective view of the electromagnetic wave directionality control apparatus which concerns on 4th Embodiment. It is a plane sectional view explaining operation of a radio wave directivity control device.

Explanation of symbols

1, 1A, 2, 3, 3A, 4 Radio wave directivity control device 11 Back surface portion 12 louver 14 Radio wave absorber 15 Slide portion 21 Back surface portion 22 Louver 31 Shield portion main body 31c Opening portion 32 Slide door 33 Flange portion 35 Shield portion main body 36 Door 37 LED Lamp 38 EMI Duct 41 Shield Body 41c Opening 42 Slide Door 43A, 43B Flange H Hinge

Claims (14)

A radio wave directivity control device including a shielding unit body for installing an electronic device having an antenna inside,
The shield body has radio wave shielding,
An opening that opens in a predetermined direction;
An opening adjustment section capable of adjusting an opening area and an opening position of the opening, and having radio wave shielding,
The shield main body and the opening adjustment portion are each formed in a substantially semi-cylindrical shape, and are configured to be combined in a substantially cylindrical shape when the opening adjustment portion covers the opening. ,
The radio wave directivity control apparatus, wherein the opening adjustment unit is configured to be slidable along a curved surface of the shielding unit main body. A radio wave directivity control device including a shielding unit body for installing an electronic device having an antenna inside,
The shield body has radio wave shielding,
An opening that opens in a predetermined direction;
An opening adjustment section capable of adjusting an opening area and an opening position of the opening, and having radio wave shielding,
The opening adjustment part is composed of a pair of sliding doors that can move with each other along the same rail,
A radio wave directivity control device comprising a flange having conductivity so as to be orthogonal to the sliding door at the edge at at least a part of the edge of the opening . The shield main body and the opening adjustment portion are each formed in a substantially semi-cylindrical shape, and are configured to be combined in a substantially cylindrical shape when the opening adjustment portion covers the opening. ,
The radio wave directivity control apparatus according to claim 2 , wherein the opening adjustment unit is configured to be slidable along a curved surface of the shielding unit main body. The radio wave pointing according to any one of claims 1 to 3 , wherein at least a part of a portion facing the electronic device has a radio wave absorptivity for absorbing radio waves radiated from the antenna. Sex control device. The radio wave directivity control apparatus according to claim 4 , wherein the radio wave absorptivity is achieved by including a λ / 4 type radio wave absorber. The radio wave directivity control device according to any one of claims 1 to 5 , wherein the shield main body includes a magnetic sheet. The radio wave directivity control device according to claim 4 , wherein the radio wave absorptivity is achieved by having a broadband radio wave absorber. The radio wave directivity control apparatus according to any one of claims 1 to 7 , wherein the shielding unit main body includes a metal casing having radio wave shielding properties. The radio wave directivity control device according to claim 8 , wherein the casing is configured by assembling a plurality of metal members, and the plurality of metal members are joined by welding. The radio wave directivity control device according to claim 8 or 9 , wherein the casing is made of aluminum or an aluminum alloy. It said shielding body, while preventing jamming any one of claims 1 to 10, characterized in that with an EMI duct to allow the cables to the inside from the outside of the shielding body The radio wave directivity control device according to 1. 12. The cable according to claim 11 , wherein a cable is disposed from the outside to the inside of the shielding unit main body via the EMI duct, and the cable is covered with a noise absorber that absorbs noise. Radio wave directivity control device. The radio wave directivity control device according to any one of claims 1 to 12 , wherein the shielding unit main body includes illumination therein. The radio wave directivity control device according to any one of claims 1 to 13 , wherein the shielding unit main body is disposed so as to cover the electronic device installed in a building.

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