JP5047059B2 - Antenna device and load control system using the same - Google Patents

Description

  The present invention relates to an antenna device that transmits or receives a signal using a loop antenna, and a load control system that transmits or receives a signal using the antenna device and controls a load according to the signal.

  For example, in the load control system described in Patent Document 1, a switch for turning on / off a load is disposed on a construction surface such as a wall surface, the switch receives a radio signal from a transmitter, and performs a load opening / closing operation based on the signal. It is configured as follows. By using wireless communication in this way, instead of existing switches or newly, for example, a highly functional switch can be easily used without performing wiring work between other parts of the load control system. It can be arranged. Examples of the highly functional switch include a hot-wire automatic switch that automatically opens and closes a load by detecting the presence or absence of a person, and a timer switch that opens and closes a switch at a set time.

  By the way, in such a load control system, it may be more desirable depending on the use to transmit and receive a radio signal between the transmitter and the switch by radio communication using radio waves than when transmitting and receiving by infrared light. That is, according to such wireless communication, there is a merit that, for example, a transmitter area capable of transmitting a signal to the switch is wider than that by infrared light due to radio wave transmission and diffraction. . In a small switch or transmitter used in a load control system, a minute loop antenna is usually preferable as an antenna for transmitting and receiving signals by wireless communication. The micro loop antenna has a feature that the total length is as small as 1/10 or less of the transmission wavelength, and that it is more resistant to a noise electric field than a micro dipole antenna.

  15 and 16 show an example of an antenna device incorporating a loop antenna used as a conventional switch or transmitter. The antenna device 81 has a circuit board 82 on which a control circuit 85 and the like are mounted. On the circuit board 82, an antenna element 84 that is a conductive wire is erected substantially vertically on the circuit board 82. The antenna element 84 is connected to the conductive pattern 83 on the circuit board 82 in the vicinity of both ends thereof, and the antenna element 84 and the conductive pattern 83 constitute an annular loop antenna 80. The loop antenna 80 and the circuit board 82 are covered with a housing 850.

By the way, in such an antenna device 81, it is necessary to increase the antenna gain by increasing the area (loop area) surrounded by the loop antenna 80. On the other hand, the loop antenna 80 is downsized and the antenna device 81, There is also a desire to reduce the size of the transmitter and the switch, contrary to the improvement of the antenna gain. That is, in the antenna device 81 as described above, in order to enlarge the loop antenna 80, the housing 850 must be enlarged. However, when the transmitter becomes large, there arises a problem that the transmitter becomes difficult to handle. In addition, the switch may need to be small enough to fit in the installation box provided on the construction surface, especially when the size of the switch in the depth direction is increased, the switch is mounted in the installation box. Cannot be installed easily.
JP 2006-253092 A

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an antenna device that has a large antenna gain and can be miniaturized, and a load control system using the antenna device.

To achieve the above object, the invention of claim 1 is a circuit board having a conductive pattern, and a substantially U-shaped antenna mounted on the circuit board and forming a loop antenna together with a part of the conductive pattern. In the antenna device comprising an element and a housing for housing the circuit board and the antenna element, the housing is made of synthetic resin, and a front panel on the front side and a base member on the back side of the antenna device, The antenna element has two legs perpendicular to the mounting surface of the circuit board and a parallel portion formed between the two legs and parallel to the mounting surface. and, wherein the front panel of the housing, the whole or part corresponding to a part of the parallel portion of the antenna element, an opening portion having a shape corresponding to all or part of the parallel portion is formed All or part of the parallel portion of the antenna element is penetrated in the opening, in which are located on the outer peripheral surface and substantially the same surface of the front panel.

  According to a second aspect of the present invention, in the first aspect of the invention, the opening is covered with an insulating seal pasted from the surface side of the housing, whereby the antenna element is not exposed from the opening. It is comprised as follows.

According to a third aspect of the present invention, in the first or second aspect of the present invention, the circuit board is formed with a through hole, and the antenna element has a portion in the vicinity of both ends of the antenna element. The antenna element is fixed on the circuit board so as to penetrate from the vicinity of each end of the antenna element toward the outside of the circuit board so that the loop area of the loop antenna is widened. There are two extending portions that are extended and connected to the two leg portions, respectively, and two portions corresponding to the leg portions of the side surface of the front panel correspond to the leg portions, respectively. side openings of the shape and is further formed, a part of the two legs is penetrated into the side opening, situated in the outer peripheral surface and substantially the same surface side of said front panel It is intended.

According to a fourth aspect of the present invention, in the method according to any one of the first to third aspects of the present invention, a conductive material is insert-molded at least at a position facing the loop antenna on the inner surface of the base member , thereby providing conductivity. A paste is applied or printed, or a conductive tape is attached.

According to a fifth aspect of the present invention, there is provided the dielectric according to any one of the first to third aspects, wherein the dielectric material has a relative dielectric constant greater than that of air at least on a portion of the inner surface of the base member facing the loop antenna. Is arranged.

  A sixth aspect of the present invention is generated when the resonance frequency of the loop antenna is adjustable and a signal is output from the loop antenna according to any one of the first to fifth aspects. A reflected wave measuring means for measuring the magnitude of the reflected wave, and a control circuit section for variably controlling the capacitance of the variable capacitor so that the magnitude of the reflected wave measured by the reflected wave measuring means is minimized. Are further provided.

  According to a seventh aspect of the present invention, in the invention according to any one of the first to fifth aspects, a capacitance value between a variable capacitor capable of adjusting a resonance frequency of the loop antenna and a surrounding is detected. And a control circuit unit that variably controls the capacitance of the variable capacitor according to the capacitance value detected by the capacitance sensor.

  The invention of claim 8 includes a control device that is connected to a load and controls at least on / off of the load, and one or a plurality of transmitters that transmit signals as radio waves, and the control device includes: Receiving means for receiving a signal transmitted as a radio wave; opening and closing means for opening and closing a power supply path from a power supply to a load; and control means for controlling a load in accordance with the signal received by the receiving means. A load control system comprising: a transmission unit that transmits a signal as a radio wave; and a control unit that controls the transmission unit and causes the signal to be transmitted from the transmission unit, wherein the control device and the one or more transmitters At least one of them is the antenna device according to any one of claims 1 to 7.

  According to the invention of claim 1, since all or a part of the parallel part of the antenna element is located on the substantially same surface as the outer peripheral surface of the housing through the opening, without increasing the size of the antenna device, The loop area of the loop antenna can be increased by the thickness of the casing of the portion of the antenna element. Therefore, it is possible to reduce the size of the antenna device while ensuring the necessary antenna gain.

  According to the invention of claim 2, it is possible to prevent the antenna circuit from being damaged due to electrostatic discharge or the like to the antenna element. Further, since the antenna element is not exposed to the outside of the antenna device, entry of dust or water droplets into the device, corrosion of the antenna element, and the like can be prevented, and the reliability of the antenna device can be improved. Furthermore, the appearance of the antenna device can be improved in appearance.

  According to the invention of claim 3, since the extending portion is provided in the antenna element, the antenna element is formed along the inner surface of the casing or the surface of the casing regardless of the position of the through hole of the circuit board. can do. Further, in addition to the parallel portion, a part of the leg portion is located on the substantially same surface as the outer peripheral surface of the housing through the side opening, so that the thickness of the housing of the portion of the antenna element is further increased. The loop area of the loop antenna can be increased. Therefore, it is possible to reduce the size of the antenna device while efficiently increasing the loop area of the loop antenna and ensuring the necessary antenna gain with respect to the size of the housing.

  According to the invention of claim 4, even if an external conductor comes close to the loop antenna of the antenna device through a conductor, a conductive paste, or a conductive tape, the back side of the conductor from the loop antenna is Since it does not appear electrically and the external conductor does not significantly affect the resonance frequency of the loop antenna, the change in the resonance frequency of the loop antenna can be reduced. Therefore, it is possible to reduce the decrease in antenna gain at a desired transmission frequency regardless of the surrounding environment.

  According to the invention of claim 5, even if the conductor approaches the loop antenna of the antenna device through the dielectric, the effect of the proximity of the conductor to the loop antenna is affected by the wavelength shortening effect of the high dielectric. Since it becomes comparatively difficult to receive, the change in the resonance frequency of the loop antenna can be reduced. Therefore, it is possible to reduce the decrease in antenna gain at a desired transmission frequency regardless of the surrounding environment.

  According to the sixth aspect of the invention, since the control circuit unit variably controls the capacitance of the variable capacitor so that the magnitude of the reflected wave is minimized, even if the resonance frequency shifts due to the installation environment of the antenna device. The resonance frequency shift can be automatically corrected, and the decrease in antenna gain can be reduced at a desired transmission frequency.

  According to the invention of claim 7, since the control circuit unit variably controls the capacitance of the variable capacitor according to the capacitance value, even if the resonance frequency shifts due to the proximity of the conductor to the antenna device, The shift of the resonance frequency can be automatically corrected, and the decrease in antenna gain can be reduced at a desired transmission frequency.

  According to the invention of claim 8, the control device and / or the transmitter is provided with the through-hole in the housing as described above, and the control device or the transmitter is downsized while maintaining the antenna gain. can do. Accordingly, the transmitter can be made easier to handle, or the control device can be securely stored in a metal box or the like and easily disposed on the construction surface.

(First embodiment)
FIG. 1 shows an illumination control system as an example of a load control system according to the first embodiment of the present invention. The illumination control system 101 includes an illumination load 150, a transmitter (antenna device) 151 that transmits a radio signal, a power source (commercial AC power source) 153, and a switch (control device; Antenna device) 152 and the like. The switch 152 has an operation handle 152a that can be operated by the user from the outside, and turns on or off the illumination load 150 in accordance with the operation of the operation handle 152a or the received wireless signal transmitted from the transmitter 151. The transmitter 151 is provided with operation buttons (not shown) that can be operated by the user. Here, although the illumination load 150 which consists of an incandescent lamp is illustrated as a load, it is not the main point limited to this, It is loads other than illumination loads other than other illumination loads, such as a fluorescent lamp and a fluorescent lamp electronic ballast. Also good.

  FIG. 2 shows a block configuration of the transmitter 151. The transmitter 151 includes a sensor unit 151a, a control circuit unit (control unit) 151b that generates a control signal such as a lighting signal for lighting the illumination load 150, and a modulation circuit 151c that modulates and amplifies the control signal. As will be described later, a signal transmission unit (transmission unit) 151d having a loop antenna, a switch circuit unit 151e, and a power supply unit 151f are included. For example, the transmitter 151 is configured in a box shape in which each unit is housed in a housing, and is used by being mounted on a wall surface, for example. The transmitter 151 is an antenna device that can transmit a radio signal.

  The sensor unit 151a includes a human sensor that detects the presence or absence of a person in the detection area by detecting a heat ray radiated from a human body by a pyroelectric element, and an illuminance that detects ambient brightness by a photoelectric conversion element or a solar cell. The sensor includes a sensor, and sends to the control circuit unit 151b detection results of ambient brightness detected by the illuminance sensor and the presence / absence of a person detected by the human sensor. The control circuit unit 151b is configured by a microcomputer or the like. When the sensor unit 151a detects that the surrounding brightness is darker than the reference value and the human body is present, or an operation signal described later is generated. Generates a lighting signal when input. The lighting signal is modulated and amplified by the modulation circuit 151c, and then transmitted as a radio signal from the signal transmission unit 151d. The switch circuit unit 151e sends an operation signal to the control circuit unit 151b when the user operates the operation button. That is, the user can forcibly turn on or off the lighting load 150 by operating the operation button regardless of the presence or absence of a person detected by the sensor unit 151a. The power supply unit 151f supplies operation power to each unit using, for example, a battery as a power source.

  FIG. 3 shows a block configuration of the switch 152. The switch 152 includes a control circuit unit (control unit) 152b, a load control unit (opening / closing unit) 152c, a signal receiving unit (receiving unit) 152d that receives a radio signal, and a signal received by the signal receiving unit 152d. A demodulating circuit 152e for amplification, a display unit 152f, a switch input unit 152g, and a power supply circuit unit 152h are provided. The switch 152 is formed in a two-module size of a wide handle type continuous switch (see JIS C 8304) having, for example, a rectangular box-shaped body made of synthetic resin, and is attached to a mounting frame or the like conforming to the standard. And placed in an outlet box embedded in the wall surface. The switch 152 is an antenna device that can receive a radio signal.

  The load control unit 152c includes a switching element (for example, a triac) that opens and closes a power supply path from the power source 153 to the illumination load 150. The control circuit unit 152b is configured by a microcomputer or the like, and controls switching of the switching element of the load control unit 152c. As will be described later, the signal receiving unit 152d is configured to be able to receive a radio signal by a loop antenna. The display unit 152f includes, for example, a light emitting element such as a light emitting diode, and displays a control state such as control validity / invalidity by the transmitter 151 based on the control of the control circuit unit 152b. The switch input unit 152g has a tact switch that is pushed by the operation handle 152a, and sends an operation signal to the control circuit unit 152b when the tact switch is turned on. That is, every time the operation handle 152a is pushed and an operation signal is sent from the switch input unit 152g, the switching element of the load control unit 152c is switched by the control of the control circuit unit 152b, and the lighting load 150 is turned on. The light is switched off. The power supply circuit unit 152h supplies operating power to the control circuit unit 152b and the like. When the load control unit 152c closes the power supply path from the power supply 153 to the illumination load 150, the power supply circuit unit 152h generates power by supplying power from the power supply 153 and charges a capacitor (not shown). On the other hand, when the load control unit 152c opens a power supply path from the power source 153 to the lighting load 150, the power circuit unit 152h generates an operating power source using the charge charged in the capacitor. For this reason, the switch 152 of this embodiment can be connected in series to the power source 153 and the illumination load 150 with two wires. Since this type of power supply circuit unit 152h is well known in the art (see, for example, Japanese Patent Laid-Open No. 2000-357443, etc.), illustration and description of a detailed configuration and operation are omitted.

  By the way, in this embodiment, a part of the loop antennas of the signal transmission unit 151d of the transmitter 151 and the signal reception unit 152d of the switch 152 are respectively close to the surface of the casing of the transmitter 151. The switch 152 is formed so as to be located near the surface of the casing. This increases the loop area of the loop antenna and increases the gain of the loop antenna as compared with the case where the loop antenna is housed inside the housing. Hereinafter, for the sake of simplification, instead of explaining the configuration of the loop antenna of the transmitter 151 or the switch 152, it is used for the transmitter 151 or the switch 152, and the loop antenna has the same characteristics as described above. A configuration of the antenna device 1 capable of transmitting or receiving a radio signal will be described. The antenna device 1 includes the control circuit units 151b and 152b, the modulation circuit 151c and the demodulation circuit 152e, the signal transmission unit 151d and the signal reception unit 152d, among the transmitter 151 and the switch 152 described above. Illustrations and descriptions of parts not related to direct wireless transmission, such as the operation handle 152a, the sensor unit 151a, and the load control unit 152c, are omitted.

  4 and 5 show the antenna device 1. The antenna device 1 is configured by housing, for example, a substantially rectangular circuit board 2 inside a box-shaped housing 50. The housing 50 is made of, for example, a synthetic resin, and is configured by joining a front panel 51 on the front side of the antenna device 1 and a base member 52 on the back side of the antenna device 1. The circuit board 2 is mounted on the base member 52 by, for example, screwing a screw (not shown) penetrating the circuit board 2 onto a boss (not shown) provided on the base member 52. ing.

  The circuit board 2 includes a conductive pattern 3 formed on the circuit board 2, a part of the conductive pattern 3, a substantially U-shaped antenna element 4 mounted on the circuit board 2, and a conductive pattern. 3, a loop antenna 10 composed of a capacitor (capacitor) 5 inserted in 3, a radio circuit unit 12 and a control circuit unit 13 mounted on the circuit board 2 are provided. On the circuit board 2, a ground pattern 6, a ground line 7 that is a part of the conductive pattern 3 and connects the loop antenna 10 and the ground pattern 6, a feed line 8 that supplies a signal to the loop antenna 10, and the like. Is provided. Among the parts of the transmitter 151 and the switch 152, the control circuit units 151b and 152b correspond to the control circuit unit 13 of the antenna device 1, and the modulation circuit 151c and the demodulation circuit 152e, and the signal transmission unit 151d and the signal reception. The unit 152d corresponds to the radio circuit unit 12, the loop antenna 10, and the like. In the antenna device 1, the radio circuit unit 12 is configured to be able to switch between signal transmission and reception. However, the present invention is not limited to this, and only one of transmission and reception is possible. You may be comprised so that it can perform.

  A through hole 2 a is formed in the vicinity of the left and right upper end portions of the circuit board 2 and in the vicinity of the conductive pattern 3. The through hole 2a is provided at a position slightly away from the end of the circuit board 2 to the inside of the circuit board 2 so that the through hole 2a can be easily formed, and the circuit board 2 is punched. It is formed by. The antenna element 4 has two leg portions 4a perpendicular to the mounting surface of the circuit board 2 and a parallel portion 4b formed between the two leg portions 4a and parallel to the mounting surface. The antenna element 4 is fixed on the circuit board 2 so as to be electrically connected to the conductive pattern 3 using solder (not shown) or the like with both end portions inserted into the respective through holes 2a. Has been.

  Assuming that the frequency of the wireless communication performed by the antenna device 1 is f, the wireless circuit unit 12 outputs a signal of the frequency f when transmitting a wireless signal. The width and height of the loop antenna 10 are designed so that the total length of one loop of the loop is about 1/10 or less of the transmission wavelength λ, and the loss is minimized at the frequency f (= 2π / λ). The impedance is adjusted so as to reduce the decrease in antenna gain. Specifically, the resonance frequency of the loop antenna 11 is adjusted by appropriately selecting the capacitance of the capacitor 5. Further, assuming that the resonance frequency of the antenna is a desired frequency, by adjusting the distance from the connection point between the feed line 8 and the conductive pattern 3 to the connection point between the ground line 7 and the conductive pattern 3, The antenna input impedance can be adjusted.

  Here, in the present embodiment, an opening 51 a is formed in the front panel 51, and the parallel part 4 b of the antenna element 4 penetrates into the opening 51 a and is substantially flush with the outer peripheral surface of the front panel 51. It is comprised so that it may be located in. The portion of the antenna element 4 is covered with an insulating seal 55 attached to the front panel 51. In addition, a conductive tape 56 is attached to a portion of the inner surface of the base member 52 facing the loop antenna 10 so as not to contact the circuit board 2.

  FIG. 6 shows a portion of the antenna device 1 where the loop antenna 10 is provided. The opening 51 a is formed in the front panel 51 at a position corresponding to the parallel portion 4 b that is substantially horizontal to the circuit board 2 in the antenna element 4. The opening 51a is slightly larger than the width dimension (shown by a dimension line in the drawing) of the parallel part 4b of the antenna element 4, and is formed in such a size that the parallel part 4b can penetrate into the opening 51a. ing. As shown in the figure, the antenna element 4 has a front panel so that the parallel portion 4b penetrates into the opening 51a from the inner surface of the front panel 51 and does not protrude outward from the surface of the front panel 51. It is formed so as to be positioned substantially flush with the flat outer peripheral surface 51. That is, the parallel portion 4b of the antenna element 4 is positioned forward by several millimeters by the thickness of the front panel 51 as compared with the case where the opening 51a is not provided. The loop area (the area of the portion shown by shading in the figure) is widened.

  The insulating seal 55 is, for example, a paste applied to one surface of an insulating resin film, and is pasted from the front side of the front panel 51 so as to cover the opening 51a. By attaching the insulating seal 55, the antenna element 4 is configured not to be exposed to the outside of the housing 50 from the opening 51a.

  The conductive tape 56 is disposed at a position close to the loop antenna 10, thereby affecting the resonance frequency of the antenna device 1. Therefore, the antenna device 1 is designed so that matching can be achieved at a desired resonance frequency with the conductive tape 56 arranged in this manner. With such a configuration, even if the antenna device 1 is close to a window glass, a wall, a desk, or the like, the back side of the conductive tape 56 is not electrically visible from the loop antenna 10, so the surface of the surface to be attached is used. Regardless, the change in the resonance frequency can be reduced, and the decrease in antenna gain can be further reduced at the desired transmission frequency.

  Thus, in this embodiment, since the parallel part 4b of the antenna element 4 is formed along the surface of the housing | casing 50 through the opening part 51a, without enlarging the antenna apparatus 1, The loop area of the loop antenna 10 can be increased. Accordingly, it is possible to reduce the size of the antenna device 1 while ensuring the antenna gain necessary for wireless communication. In other words, with such a configuration, a larger antenna gain can be obtained while the antenna device 1 is kept small. In addition, since the antenna element 4 is covered with the insulating seal 55 and is not exposed to the outside, the appearance of the antenna device 1 can be maintained and the circuit can be maintained by electrostatic discharge to the antenna element 4 or the like. It is possible to prevent the elements constituting the radio circuit unit 12 and the control circuit unit 13 on the substrate 2 from being damaged. Further, it is possible to prevent dust and water droplets from entering the antenna device 1 and corrosion of the antenna element 4, and the reliability of the antenna device 1 can be improved.

  In this embodiment, as shown in FIG. 7A, instead of the conductive tape 56, the base member 52 is inserted by inserting a conductor 57 into at least a portion of the base member 52 facing the loop antenna 10. Molding may be performed and matching may be performed at a desired resonance frequency in that state. Further, even if a conductive paste (not shown) is applied or printed on the inner surface of the base member 52, the same effect as described above can be obtained. In addition, the conductive tape 56, the conductor 57, and the conductive paste may be provided on a portion facing the front surface of the circuit board 2, and not only a portion facing the loop antenna 10, but also one surface of the housing 50. It may be provided over the entire surface.

  In this embodiment, as shown in FIG. 7B, instead of the conductive tape 56, for example, a sheet-like dielectric 58 is provided at least on the inner surface of the base member 52 at a location facing the loop antenna 10. You may arrange. By disposing the dielectric 58 in this manner, even if the conductor approaches the loop antenna 10 via the dielectric 58, the loop antenna 10 is affected by the conductor due to the wavelength shortening effect of the high dielectric. Thus, the change in the resonance frequency of the loop antenna 10 can be reduced. Therefore, it is possible to reduce the decrease in antenna gain at a desired transmission frequency regardless of the surrounding environment. As the dielectric 58, for example, a dielectric having a relative dielectric constant of 10 or more is particularly effective. However, when a dielectric having a relative dielectric constant larger than that of air is used, the dielectric 58 is not used. As compared with the above, the effect of reducing the decrease in antenna gain can be obtained.

(Second Embodiment)
Next, an antenna device used in the illumination control system according to the second embodiment of the present invention will be described. FIGS. 8A and 8B show the antenna device 21 in the second embodiment. In the following, the same components as those in the first embodiment described above are denoted by the same reference numerals, and only the portions different from the first embodiment will be described. The antenna device 21 is different from the antenna element 4 in the shape of the antenna element 24, so that the loop antenna 20 has a larger loop area than the loop antenna 10, and the antenna device 1 in the first embodiment described above. It is comprised substantially the same.

  Similarly to the antenna element 4, the antenna element 24 is mounted on the circuit board 2 in a state where the portions near both ends are inserted into the through holes 2 a of the circuit board 2. The antenna element 24 has extended portions 20a extending from the vicinity of both end portions penetrating the through hole 2a toward the outside of the circuit board 2 and connected to the two leg portions 4a. The extending portion 20 a extends to the vicinity of the inner surface of the housing 50, and each leg portion 4 a is arranged along the inner peripheral surface of the housing 50. Similar to the first embodiment, the front panel 51 is provided with an opening 51a. The opening 51a is formed in a shape corresponding to the penetration portion 24b which is a part of the central portion of the parallel portion 4b of the antenna element 24. The penetration portion 24b is formed on the outer periphery of the front panel 51 as shown in the figure. It is formed so as to be located in substantially the same plane as the plane. Further, the other part of the penetration part 24 b in the parallel part 4 b is located in the vicinity of the inner surface of the front panel 51.

  Thus, in the second embodiment, regardless of the position of the through hole 2a of the circuit board 2 of the antenna device 21, a part of the antenna element 24 is along the inner surface of the housing 50, and The other part can be formed so as to be positioned substantially on the same surface as the outer peripheral surface of the front panel 51. As a result, the loop area of the loop antenna 20 can be further increased, and the antenna device 21 can be further reduced in size while ensuring the necessary antenna gain. Therefore, the transmitter 151 and the switch 152 of the illumination control system 101 can be made easier to handle and can be easily arranged on the construction surface.

  In addition, when it has the above extended parts 20a, the shape of an antenna element is not restricted above, Various can be selected with the shape of a front panel. 9 (a) and 9 (b), for example, the extended portion 20a is provided in the same manner as described above, and the entire parallel portion 4b extends over the substantially entire width of the casing 50 and the outer periphery of the front panel 51 of the casing 50. The structure of the antenna apparatus 31 which has the antenna element 34 formed so that it may be located in the substantially same surface as a surface is shown. In the antenna device 31, the front panel 51 has an opening 351 a formed in a shape corresponding to the parallel part 4 b so as to open over substantially the entire width of the front panel 51. The opening 351 a is covered with an insulating seal 355 having a width that is longer than that of the above-described insulating seal 55, and the antenna element 34 is formed so as not to be exposed to the outside of the antenna device 31. Thus, by increasing the portion of the antenna element 34 that is located near the surface of the front panel 51, the loop area of the loop antenna 30 of the antenna device 31 can be further expanded.

  Further, in FIGS. 10A and 10B, for example, an extending portion 20 a is provided in the same manner as described above, and a part of the leg portion 4 a is similar to the parallel portion 4 b, respectively. The structure of the antenna apparatus 41 which has the antenna element 44 formed so that it may be located in the substantially same surface as an outer peripheral surface is shown. In this antenna device 41, an opening 451a is formed on the front surface of the front panel 51 in a shape corresponding to the parallel portion 4b, and the left side surface and the right side surface of the front panel 51 are respectively provided with leg portions 4a. Side openings 451b and 451c are formed in a shape corresponding to a part. The opening 451a and the side openings 451b and 451c are formed so as to leave a corner 451e where the front surface and the side surface of the front panel 51 intersect. As shown in FIG. 10 (b), the parallel part 4b of the antenna element 44 is formed so as to be positioned on the substantially same surface as the outer peripheral surface of the front panel 51 through the opening 451a. In addition, each part of the two leg portions 4a is formed so as to be located substantially on the same surface as the outer peripheral surface of the front panel 51 via the side opening portions 451b and 451c. Both the opening 451a and the side openings 451b and 451c are covered with a single insulating seal 455 which is attached to the surface of the front panel 51 and whose longitudinal dimension is longer than that of the insulating seal 355. Thus, the antenna element 44 is formed so as not to be exposed to the outside of the antenna device 41. As described above, by providing a portion of the antenna element 44 that is substantially flush with the outer peripheral surface of the front panel 51 not only in the parallel portion 4b but also in a part of the leg portion 4a, the loop of the loop antenna 40 is obtained. The area can be further expanded. Thereby, the antenna gain can be further increased while the antenna device 41 is downsized.

(Third embodiment)
A third embodiment of the antenna device of the present invention will be described. FIG. 11 shows a block configuration of an antenna apparatus according to the third embodiment. The antenna device 61 according to the third embodiment includes a variable capacitor 65 inserted in series with the capacitor 5 in the loop of the loop antenna 10, and detection for measuring the magnitude of the reflected wave of the signal output from the radio circuit unit 12. A circuit (reflected wave measuring means) 66, and the control circuit unit 13, that is, the transmitter 151 or the control circuit units 151b and 152b of the switch 152 are configured so that the resonance frequency of the loop antenna 10 can be automatically adjusted. It is. The detection circuit 66 is disposed in a path for transmitting a signal from the radio circuit unit 12 to the loop antenna 10, and is separated by the directional coupler 66a that separates the reflected wave from the loop antenna 10 and the directional coupler 66a. And a high-frequency voltage measuring unit 66b for measuring the magnitude of the input reflected wave. For example, a circulator or the like is used as the directional coupler 66a. In the antenna device 61, there is a changeover switch 67 for switching the connection path to the loop antenna 10 between the TX (transmission side) terminal and the RX (reception side) terminal of the radio circuit unit and switching between transmission and reception. Is provided.

  In the shipping inspection process of the antenna device 61, for example, the control circuit unit 13 is set to the test mode, the correction capacitance amount of the variable capacitor 65 is set to a predetermined value, and the changeover switch 67 is set to the TX (transmission side) terminal side. In this state, a test signal is output from the radio circuit unit 12. At this time, a reflected wave is generated by the matching state of the output impedance of the radio circuit unit 12 and the input impedance of the loop antenna 10. The magnitude of this reflected wave is measured by the detection circuit 66 in the radio circuit unit 12. Next, the correction capacitance amount of the variable capacitor 65 is set to another value by the control signal from the control circuit unit 13, and the magnitude of the reflected wave is measured in the same manner. In this way, the magnitude of the reflected wave is measured for each of the plurality of corrected capacitance amounts, and the control circuit unit 13 obtains the corrected capacitance amount that minimizes the reflected wave. When the correction capacitance amount is set so that the reflected wave is minimized, the changeover switch 67 remains unchanged when the antenna device 61 performs transmission, and the changeover switch 67 is set to the RX (reception side) terminal side when performing reception. , Transmission or reception can be executed.

  According to such a configuration, in the shipping inspection process of the antenna device 61, the adjustment of the correction capacitance amount that has been performed manually in the past can be automated, so that the manufacturing cost of the antenna device 61 can be reduced. Further, by periodically executing the test mode in the actual use state, it is possible to periodically correct the deviation of the resonance frequency due to the installation environment, and to reduce the decrease in the antenna gain at the desired transmission frequency. In the test mode, since it is necessary to output a test signal from the radio circuit unit 12, it is not possible to execute the originally performed communication and the test mode at the same time. For example, in the illumination control system 101 as described above, in the case where communication is performed intermittently between the transmitter 151 and the switch 152, a time during which communication is not performed immediately after one communication sequence is completed. Exists. By executing the test mode using the time during which this communication is not performed, the test mode can be reliably executed and a large antenna gain can be maintained without interfering with the communication that should be performed.

(Fourth embodiment)
A fourth embodiment of the antenna device of the present invention will be described. FIG. 12 shows a block configuration of an antenna apparatus according to the fourth embodiment. Similar to the antenna device 61 according to the third embodiment, the antenna device 71 according to the fourth embodiment includes a variable capacitor 65 and is configured such that the control circuit unit 13 can adjust the resonance frequency of the loop antenna 10. Furthermore, in place of the detection circuit 66, a capacitance sensor 76 for detecting a capacitance value between the detector and the surroundings is provided. For example, the capacitance sensor 76 is connected to the ground potential on the circuit board 2 and is provided in the vicinity of the loop antenna 10.

  In the antenna device 71, adjustment values of the variable capacitor 65 corresponding to various capacitance values that can be detected by the capacitance sensor 76 are set in the control circuit unit 13 in advance as a control table. Yes. In this control table, for example, an adjustment value of the variable capacitor 65 is set so that the antenna gain of the loop antenna 10 is increased in a state where a conductor or the like is brought close to the antenna device 71, and the adjustment at that time is performed. The value and the capacitance value detected by the capacitance sensor 76 are set in association with each other. When the antenna device 71 is used, the control circuit unit 13 uses the adjustment value corresponding to the capacitance value detected by the capacitance sensor 76 periodically or at a time before signal transmission or the like. Adjust the capacity.

  According to such a configuration, for example, a conductor approaches the loop antenna 10 using the capacitance value of the capacitance sensor 76 that changes according to a change in the environment where the antenna device 71 is placed. However, the decrease in the antenna gain of the loop antenna 10 can be reduced. Regardless of whether or not a radio signal is transmitted / received using the loop antenna 10, the deviation of the resonance frequency of the loop antenna 10 can be automatically and appropriately corrected using the capacitance value. The antenna gain can be maintained.

  In addition, this invention is not limited to the structure of the said embodiment, A various deformation | transformation is possible in the range which does not change the meaning of invention. For example, the configuration of the antenna device may be used not only in the transmitter and the switch but in either the transmitter or the switch in the above-described lighting control system. In the antenna device, the insulating seal is not necessarily attached. Furthermore, the antenna device can adjust the antenna gain by measuring the reflected wave as shown in the third embodiment in the antenna device as shown in FIGS. 8A and 8B, for example. As shown in the fourth embodiment, the antenna gain may be adjustable or configured based on the capacitance value, and the antenna device can be configured by appropriately combining these characteristic portions.

  Further, the antenna device is not applicable only to the transmitter and the switch (control device) disposed on the wall surface as described above. FIG. 13 shows an operation of turning on / off the illumination load 150 and adjusting the brightness by using a remote control device 251 that can be operated by the user, for example, in a living room of the house and using the configuration of the antenna device 1 described above. 1 shows a lighting control system 201 configured to be able to perform The illumination control system 201 is different from the illumination control system 101 described above in that a remote controller 251 is used instead of the transmitter 151 grounded to the wall surface. The remote controller 251 does not have the sensor unit 151a in the transmitter 151 described above, and is configured to be able to transmit a radio signal to the switch 152 in accordance with an operation of an operation button (not shown). The switch 152 receives a radio signal transmitted from the remote control device 251 and controls on / off and brightness (luminance) of the illumination load 150 based on the radio signal. As described above, by using the configuration of the antenna device 1 described above for the remote control device 251, the remote control device 251 can be downsized while maintaining a large antenna gain and reliably transmitting a radio signal to the switch 152 within a necessary area. , Can be more manageable. Further, the remote control device 251 is provided with the conductive tape 56 facing the loop antenna 10, so that the antenna gain is unlikely to decrease even when a conductor is close to the surrounding. Therefore, the operation of the illumination control system 201 can be reliably performed without paying much attention to the environment where the remote control device 251 is placed, and the remote control device 251 can be further handled easily. Furthermore, a plurality of remote control devices 251 may be used in combination with one switch 152, and a plurality of switches 152 and remote control devices 251 are provided for one illumination load 150. A set may be provided.

  FIGS. 14A and 14B show an example in which a wireless communication device using any one of the antenna devices described above is applied to an illumination control system 301 for on / off control and dimming control of a toilet lighting fixture. . Fig.14 (a) is the cross-sectional side view which looked at the toilet from the side, FIG.14 (b) is the see-through | perspective perspective view seen through diagonally from the upper right toward the toilet. In the example shown in FIG. 14, the transmitter 151 is provided on the wall surface in the toilet room, and the switch 152 is an illumination operation switch that includes an operation handle that is connected to the illumination load 150 by wire to operate the illumination load 150 on and off. And is provided on the outside wall of the toilet entrance. The switch 152 that functions as a receiver is formed in, for example, an outer dimension (two module dimensions of a wide handle type continuous switch) defined by JIS C8304 of the Japanese JIS standard. The transmitter 151 is provided integrally with a hot-wire human body sensor (not shown) or the like. When the human body sensor detects the presence of a human body, the transmitter 151 sends an illumination load 150 from the transmitter 151 toward the switch 152. A radio wave signal for lighting is transmitted. When the switch 152 receives a signal from the transmitter 151, the switch 152 turns on the illumination load 150 through a wiring provided on the back side of the wall (via an illumination control control unit (not shown)). Here, when the communication between the transmitter 151 and the switch 152 is performed by the signal of the LED light instead of the wireless signal, when the toilet door is closed as shown in FIGS. 14 (a) and 14 (b). When the toilet door is arranged so that the straight light path between the transmitter 151 and the switch 152 is blocked, it is almost impossible for the switch 152 to sense a human body immediately after entering the toilet. Therefore, in this lighting control system 301, in order to solve the problem of blocking the LED optical path, a radio wave type is adopted instead of the LED light, and communication between the transmitter 151 and the switch 152 is performed by transmission / reception of a radio signal. In wireless communication using radio waves, the radio wave signal from the transmitter 151 is reliably received by the switch 152. Therefore, even if there is an obstacle for LED light on the straight optical path for wireless transmission / reception between the transmitter 151 and the switch 152, the illumination load 150 can be quickly turned on by radio communication using radio waves. Such an application example is not limited to a toilet, but may be a closet. The transmitter 151 and the switch 152 are separately arranged inside and outside the partition member of the closet that accommodates clothing, and there is an obstacle for the LED light on the linear optical path of wireless transmission / reception between the transmitter 151 and the switch 152. Cases can occur. Therefore, the use of the antenna device of the present invention is suitable as with a toilet.

  In the example shown in FIG. 14, the transmitter 151 is provided in a remote control device operated by a user. The switch 152 is provided integrally with, for example, a switch of the lighting load 150 provided on the wall surface, but may be provided directly on the lighting load 150. The user can adjust the dimming level (brightness) of the illumination load 150 to a desired level by operating a button on the remote control device. In FIG. 14, since the transmitter 151 emits a radio signal by radio waves, it is not necessary to intentionally direct the transmitter of the transmitter 151 to the switch 152 as compared with the conventional remote controller having strong directivity by LED transmission. That is, since it is easy to deliver the wireless remote control signal to the switch 152 regardless of which transmitter 151 is directed, the operability of the transmitter 151 can be improved.

  In addition to the illumination control system that controls the on / off of the illumination load as described above, the antenna device is an air conditioning system, a hot water supply system, or a transmitter that is turned on / off according to a signal transmitted from the transmitter. It can also be used in a load control system used for other purposes, such as a security system that receives a predetermined signal transmitted from the terminal and performs a notification operation. That is, a transmitter or a remote control device used to remotely control the operation of the load control system by transmitting a radio signal, or a control device such as a switch that receives such a radio signal is described above. By using the configuration of the antenna device, the transmitter, the remote control device, the control device, or the like can be reduced in size while maintaining the antenna gain.

The figure which shows an example of the illumination control system which concerns on 1st Embodiment of this invention. The block diagram which shows the structure of the switch of the said illumination control system, and illumination load. The block diagram which shows the structure of the transmitter of the said illumination control system. The perspective view which shows an example of the antenna apparatus used for the said illumination control system. The disassembled perspective view of the said antenna apparatus. The upper cross section in the site | part in which the loop antenna of the said antenna apparatus is provided. (A) is an upper sectional view showing a modified example of the antenna device, (b) is an upper sectional view showing still another modified example of the antenna device. (A) is a perspective view which shows an example of the antenna device used for the illumination control system which concerns on 2nd Embodiment of this invention, (b) is an upper sectional view in the site | part in which the loop antenna of the same antenna device is provided. (A) is a perspective view which shows the modification of the said antenna apparatus, (b) is an upper sectional view in the site | part in which the loop antenna of the same antenna apparatus is provided. (A) is a perspective view which shows another modification of the said antenna apparatus, (b) is an upper sectional view in the site | part in which the loop antenna of the same antenna apparatus is provided. The circuit diagram which shows an example of the antenna device used for the illumination control system which concerns on 3rd Embodiment of this invention. The circuit diagram which shows an example of the antenna device used for the illumination control system which concerns on 4th Embodiment of this invention. The figure which shows the structure of the modification of the said illumination control system. (A) is a side view which shows the structure of another modification of the said illumination control system, (b) is a perspective view of (a). The perspective view which shows the conventional antenna apparatus. The upper cross section in the site | part in which the loop antenna of the said antenna apparatus is provided.

Explanation of symbols

1, 2, 31, 41, 61, 71 Antenna device 2 Circuit board 2a Through hole 3 Conductive pattern 4, 24, 34, 44 Antenna element 4a Leg portion 4b Parallel portion 10, 20, 30, 40 Loop antenna 12 Radio circuit Part 13 Control circuit part 20a Extension part 50 Case 51a, 351a, 451a, 451b, 451c Opening 55, 355, 455 Insulating seal 56 Conductive tape 57 Conductor 58 Dielectric 65 Variable capacity capacitor 66 Detection circuit (reflection) Wave measurement means)
76 Capacitance sensor 101, 201, 301 Lighting control system (load control system)
150 Lighting load (load)
151 Transmitter (antenna device)
151b, 152b Control circuit section (control means)
151c Modulation circuit (wireless circuit part)
151d Signal transmission unit (transmission means, radio circuit unit)
152 switch (control device; antenna device)
152a Operation handle 152c Load control unit (opening / closing means)
152d Signal receiving unit (receiving means, radio circuit unit)
152e Demodulation circuit (wireless circuit part)
251 Remote control device (antenna device)
451b, 451c Side opening

Claims (8)

A circuit board having a conductive pattern;
A substantially U-shaped antenna element mounted on the circuit board and forming a loop antenna together with a part of the conductive pattern;
In the antenna device comprising the circuit board and a housing for housing the antenna element,
The housing is made of synthetic resin, and is configured by joining a front panel on the front side of the antenna device and a base member on the back side,
The antenna element has two legs perpendicular to the mounting surface of the circuit board and a parallel portion formed between the two legs and parallel to the mounting surface.
An opening of a shape corresponding to all or part of the parallel part is formed in a part of the front panel of the housing corresponding to all or part of the parallel part of the antenna element,
The antenna device according to claim 1, wherein all or part of the parallel portion of the antenna element penetrates into the opening and is positioned substantially on the same surface as the outer peripheral surface of the front panel .   2. The opening is covered with an insulating seal pasted from the surface side of the housing, so that the antenna element is not exposed from the opening. The antenna device described. A through hole is formed in the circuit board,
The antenna element is fixed on the circuit board such that the vicinity of both ends of the antenna element penetrates the through hole,
The antenna element includes two antenna elements extending from the vicinity of each end of the antenna element toward the outside of the circuit board so as to increase a loop area of the loop antenna and connected to the two leg portions, respectively. Has an extension,
Of the side surfaces of the front panel, two portions corresponding to the leg portions are further formed with side openings corresponding to the leg portions, respectively.
The part of the two legs is inserted into the side opening, and is located substantially flush with the outer peripheral surface of the side surface of the front panel . Antenna device. The conductive member is insert-molded, and a conductive paste is applied or printed, or a conductive tape is attached to at least a portion of the inner surface of the base member facing the loop antenna. The antenna device according to any one of claims 3 to 3. 4. The dielectric material according to claim 1, wherein a dielectric material having a relative dielectric constant larger than air is disposed at least on a portion of the inner surface of the base member facing the loop antenna. 5. Antenna device. A variable capacitor capable of adjusting the resonance frequency of the loop antenna;
Reflected wave measuring means for measuring the magnitude of the reflected wave generated when a signal is output from the loop antenna;
The control circuit unit variably controls the capacitance of the variable capacitor so that the magnitude of the reflected wave measured by the reflected wave measuring means is minimized. Item 6. The antenna device according to any one of Items 5 to 6. A variable capacitor capable of adjusting the resonance frequency of the loop antenna;
A capacitance sensor that detects a capacitance value between the surroundings;
The control circuit unit variably controlling the capacitance of the variable capacitor according to the capacitance value detected by the capacitance sensor. The antenna device according to one item. A controller connected to a load and controlling at least on / off of the load; and one or more transmitters for transmitting signals as radio waves,
The control device controls a load according to a signal received by the receiving unit, a receiving unit that receives a signal transmitted as a radio wave from the transmitter, an opening / closing unit that opens and closes a power supply path from a power source to the load, and the signal received by the receiving unit Control means for
In the load control system, the transmitter includes a transmission unit that transmits a signal as a radio wave, and a control unit that controls the transmission unit and causes the signal to be transmitted from the transmission unit.
8. The load control system according to claim 1, wherein at least one of the control device and the one or more transmitters is the antenna device according to claim 1.

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