JP2015153245A - Electric wave sensor device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric wave sensor device that can be easily installed and can detect not only the presence or absence of any person but also the condition of the person.SOLUTION: An electric wave sensor device 1 comprises an electric wave sensor 3 that transmits an electric wave medium for detecting the condition of a person and detects the condition of the person and a person sensor 2 that can detect the presence or absence of any person. A transmission part 6 of the electric wave sensor 3 transmits, in addition to the electric wave medium, a transmission medium for transmitting the result of detection by the person sensor 2. This dispenses with the need for individual adjustment of a plurality of sensors and confirmation of the reception conditions of the sensors, and thereby enabling the electric wave sensor device 1 to be easily installed.

Description

  The present invention relates to a radio wave sensor device including a radio wave sensor for detecting a human condition.

  The transmitter of the radio wave sensor emits a radio wave medium in order to detect a human condition. The emitted radio wave medium reaches the receiver of the radio wave sensor while reflecting off a wall or window in a building (for example, a house). Since the amount of information in the radio wave medium changes depending on the route through which the radio wave medium passes, the change in the information volume is analyzed to detect the intrusion of people into the building and the activity of people in the building. be able to.

JP-A-7-220188

  However, in the prior art, when there is no change in the path through which the radio wave medium passes, it is distinguished whether there is a person but the person is not moving in the detection range through which the radio wave medium has passed. I couldn't. There is also a need for a radio wave sensor device that can be easily installed without the trouble of installation.

  An object of the present invention is to provide a radio wave sensor device that can be easily installed, detects the presence or absence of a person, and can detect the state of the person.

  The radio wave sensor device of the present invention is different from a radio wave sensor having a transmission unit that transmits a radio wave medium for detecting a human condition and a reception unit that receives the radio wave medium. The transmission medium for transmitting the detection result by the human sensor is transmitted from the transmission unit of the radio wave sensor.

  According to this radio wave sensor device, it is possible to detect whether or not a person is present by the human sensor, and it is possible to detect the state of the human by the radio wave sensor. Since the transmission unit of this radio wave sensor transmits a transmission medium for transmitting the detection result of the human sensor in addition to the radio wave medium for detecting the state of the person, the radio wave sensor device includes a plurality of sensors. However, it is not necessary to individually adjust transmission / reception of the radio wave medium of the radio wave sensor and transmission / reception of the transmission medium for transmitting the detection result of the human sensor, and it is not necessary to individually check the reception state. Therefore, it can be simply installed, and troublesomeness such as adjustment when installing the radio wave sensor can be eliminated.

  The radio wave sensor device preferably includes a common power supply circuit that supplies power to both the transmitter of the radio wave sensor and the human sensor. Thereby, it is not necessary to separately provide a power supply circuit for the transmission unit of the radio wave sensor and the human detection sensor, and a simple configuration can be achieved, and the troublesomeness at the time of installation can be eliminated.

  The human sensor is preferably an infrared sensor. Thereby, it can be detected whether or not a person is present by the infrared sensor, and the detection result by the infrared sensor can be transmitted from the transmission unit of the radio wave sensor.

  The infrared detector of the infrared sensor is preferably rotatable about an axis extending in the vertical direction. Thereby, the infrared detection unit can be rotated to easily change the infrared detection range, and the human detection range by the infrared sensor can be expanded.

  It is preferable that the transmission unit of the radio wave sensor and the human sensor are housed in a common housing. Thereby, the transmission part of a radio wave sensor and a human sensor can be attached only by installing one housing.

  The casing is provided with a fixing portion that is fixed to the head portion or the vertical portion of the joinery frame installed at the entrance of the building, and the fixing portion preferably includes a pair of holding pieces that sandwich the head portion or the vertical portion. . Thereby, since a fixing | fixed part is inserted from the inner side of a joinery frame and a duck part or a standing part can be pinched | interposed with a pair of clamping pieces, a radio wave sensor apparatus can be easily attached to a joinery frame. By installing the radio wave sensor at the entrance / exit of the building, it is possible to detect the person entering / exiting the building and to monitor the state of the person near the entrance / exit.

  It is preferable that the surface of the housing is provided with a plug that protrudes outward from the surface and can be inserted into an outlet installed on the wall of the building. As a result, the radio wave sensor can be attached to the wall surface of the building simply by inserting the plug into the outlet. For example, home electrical wiring work is not required.

  Further, it is preferable that the transmission unit and the infrared sensor of the radio wave sensor are housed in a handrail installed on the wall surface of the building, and the infrared irradiation unit of the infrared sensor is exposed from the handrail. In this way, the transmission unit and the infrared sensor of the radio wave sensor can be accommodated in the handrail installed on the wall surface of the building, so the transmission unit and the infrared sensor of the radio wave sensor are installed on the wall surface of the building simultaneously with the installation of the handrail. can do.

  It is preferable that a transmission plate of the radio wave sensor is provided with a shielding plate that shields the radio wave medium, and the emission range of the radio wave medium can be adjusted by attaching and detaching the shielding plate. Thereby, the emission range of the radio wave medium can be easily adjusted by simply attaching and detaching the shielding plate.

  According to the present invention, it is possible to provide a radio wave sensor device that can be easily installed, can detect the presence or absence of a person, and can detect the state of a person.

It is a schematic block diagram which shows the electromagnetic wave sensor apparatus of one Embodiment of this invention. It is a figure which shows the transmitter of the state attached to the door frame. It is sectional drawing which shows the fixing | fixed part of a transmitter. It is a perspective view which shows the state with which the housing | casing of the handrail type transmitter was attached to the wall. It is an exploded side view of a handrail type radio wave sensor device. It is a front view which shows the attachment state of the electric wave sensor apparatus of an outlet plug type. It is a front sectional view of a plug-in type radio wave sensor device. It is side surface sectional drawing of a plug-in type radio wave sensor apparatus. It is a top view which shows the shielding board which concerns on a modification. It is a figure which shows an example of a carrier wave.

  Hereinafter, embodiments of a radio wave sensor device according to the present invention will be described in detail with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic configuration diagram showing a radio wave sensor device 1. The radio wave sensor device 1 includes an infrared sensor 2, a radio wave sensor 3, a signal processing calculation unit 4, and a power supply circuit 5. The radio wave sensor device 1 is installed in a house, for example, and detects the presence or absence of an indoor person and also detects the state of the indoor person.

  The radio wave sensor device 1 includes an infrared sensor 2 as a human sensor capable of detecting whether or not a person is present. The infrared sensor 2 includes a projector that irradiates infrared rays and an infrared detection unit (for example, a lens) that detects infrared rays that have been reflected by being reflected by an object. For example, the infrared rays emitted from the projector are reflected by hitting a person who is the object, and the reflected infrared rays are detected by the infrared detector.

  The radio wave sensor 3 includes a transmission unit 6 that transmits a radio wave medium for detecting a human condition, and a reception unit 7 that receives the transmitted radio wave medium. The transmission unit 6 is disposed on one side of the detection range, and the reception unit 7 is disposed on the other side of the detection range. That is, the area between the transmission unit 6 and the reception unit 7 is a detection range. The transmission unit 6 of the radio wave sensor 3 outputs a carrier wave as a radio wave medium. A plurality of array antennas can be used as the receiving unit 7 of the radio wave sensor 3.

  The radio wave sensor device 1 includes a transmitter 8 that integrally includes the transmission unit 6 of the radio wave sensor 3 and the infrared sensor 2. The transmitter 8 includes a common power supply circuit 5 that supplies power to both the transmitter 6 of the radio wave sensor 3 and the infrared sensor 2. Hereinafter, when referring to both the transmission unit 6 of the radio wave sensor 3 and the infrared sensor 2, they are referred to as sensors. The power supply circuit 5 may supply power to the sensors. For example, the power supply circuit 5 may supply power to the infrared sensor 2 via the transmission unit 6 of the radio wave sensor 3.

  The transmitter 8 has a housing 9 that houses sensors and the power supply circuit 5. In the housing 9, the sensors and the power supply circuit 5 are electrically connected.

  The transmitter 8 may have a plurality of casings and may be configured as a single unit by connecting the plurality of casings. The transmitter 8 includes, for example, a first housing that houses the infrared sensor 2 and a second housing that houses the transmission unit 6 and the power supply circuit 5 of the radio wave sensor 3, and these first housings And the structure where the 2nd housing | casing is connected may be sufficient.

  Here, the transmission unit 6 of the radio wave sensor 3 transmits a transmission medium that transmits the detection result of the infrared sensor 2 in addition to the radio wave medium. The receiving unit 7 of the radio wave sensor 3 receives both the radio wave medium and the transmission medium. The transmitter 6 of the radio wave sensor 3 and the infrared sensor 2 are electrically connected. The detection result by the infrared sensor 2 is transmitted to the transmission unit 6 of the radio wave sensor 3. The transmission unit 6 of the radio wave sensor 3 transmits a carrier wave as a radio wave medium and a transmission medium.

  FIG. 10 is a diagram illustrating an example of a carrier wave transmitted from the transmission unit 6 of the radio wave sensor 3. In FIG. 10, the horizontal axis indicates the passage of time, and the vertical axis indicates the amplitude. In this carrier wave, a portion (radio wave medium) P1 for detecting the human state by the radio wave sensor 3 and a portion (transmission medium) P2 for transmitting the detection result by the infrared sensor 2 are alternately transmitted every time. ing. Thereby, while detecting the state of a person as radio wave sensor 3, the detection result by infrared sensor 2 is transmitted.

  The transmission unit 6 transmits a carrier wave having a constant amplitude, for example, as the part P1 for detecting the human state by the radio wave sensor 3. The transmission unit 6 transmits “0” and “1” by changing the frequency, for example, as the portion P2 for transmitting the detection result by the infrared sensor 2.

  The signal processing calculation unit 4 is electrically connected to the reception unit 7 of the radio wave sensor 3. The carrier wave received by the receiving unit 7 is transmitted to the signal processing calculation unit 4. The signal processing calculation unit 4 includes a CPU, and analyzes the detection result by the infrared sensor 2 and the detection result by the radio wave sensor 3. Based on the detection result of the infrared sensor 2, the signal processing calculation unit 4 can determine whether or not there is a person in the detection range. Further, the signal processing calculation unit 4 determines the state of the person based on the detection result by the radio wave sensor 3. Since the amount of information of the carrier wave varies depending on the transmission path, the signal processing calculation unit 4 analyzes the carrier wave, calculates the transmission path of the carrier wave, and detects the state of the person within the detection range. For example, the signal processing calculation unit 4 detects a person's state (activity state) based on the strength of the carrier wave.

  The radio wave sensor device 1 also has an output unit that outputs the analysis result obtained by the signal processing calculation unit 4. Examples of the output unit include a display unit that displays an image.

Next, the operation of the radio wave sensor device 1 will be described.
In the radio wave sensor device 1, infrared rays are emitted from the infrared sensor 2. The irradiated infrared rays hit a person and are reflected, and are detected by the detection unit of the infrared sensor 2. The detection result by the infrared sensor 2 is transmitted to the transmission unit 6 of the radio wave sensor 3.

  The transmission unit 6 of the radio wave sensor 3 transmits a carrier wave as a transmission medium for transmitting a detection result by the infrared sensor 2 and a radio wave medium for detecting the state of a person. This carrier wave has a part P1 for transmitting information for detecting a human condition and a part P2 for transmitting a detection result by the infrared sensor 2.

  The reception unit 7 of the radio wave sensor 3 receives the carrier wave transmitted from the transmission unit 6 of the radio wave sensor 3. Information on the carrier wave received by the receiving unit 7 is transmitted to the signal processing calculation unit 4 and analyzed. The signal processing calculation unit 4 detects the presence or absence of a person based on the detection result by the infrared sensor 2. Moreover, the signal processing calculation part 4 calculates the conveyance path | route of an electric medium as a detection result by the electromagnetic wave sensor 3, and detects about a person's state. The signal processing calculation unit 4 detects, as the state of the person, whether or not the person is moving within the detection range, the range where the person is moving, and the like.

  According to such a radio wave sensor device 1, it is possible to detect whether or not a person is present by the infrared sensor 2, and it is possible to detect the state of the person by the radio wave sensor 3. The transmission unit 6 of the radio wave sensor 3 transmits both the radio wave medium for detecting the state of the person and the transmission medium for transmitting the detection result by the infrared sensor 2. Even if the configuration includes the infrared sensor 2, the transmission / reception of the radio wave medium of the radio wave sensor 3 and the transmission / reception of the transmission medium of the infrared sensor 2 do not need to be individually adjusted. Therefore, the radio wave sensor device 1 can be easily installed and used, and troublesome work such as adjustment and confirmation when installing the radio wave sensor can be eliminated. Further, the radio wave sensor device 1 can be easily installed even by a person who has no specialized knowledge.

  In addition, since the radio wave sensor device 1 includes the common power supply circuit 5 that supplies power to the sensors, it is not necessary to provide a separate power supply circuit, and the sensors can be easily integrated. In the radio wave sensor device 1, the sensors 8 and the power supply circuit 5 are housed and integrated in a common housing 9, so that the transmitter 8 can be easily installed. As a result, there is no need to install sensors separately. The radio wave sensor device 1 eliminates the need for individual wiring work. In the radio wave sensor device 1, the detection result by the radio wave sensor 3 and the detection result by the infrared sensor 2 can be analyzed by a common signal processing calculation unit (for example, a personal computer) 4.

(Second Embodiment)
Next, the radio wave sensor device according to the second embodiment will be described. 2nd Embodiment demonstrates the case where the transmitter of an electromagnetic wave sensor apparatus is attached to the door frame of the entrance door. In the description of the second embodiment, the same description as in the first embodiment is omitted.

  As shown in FIG. 2, the radio wave sensor device 21 of the second embodiment includes a transmitter 22 attached to the door frame (joint frame) 12 of the entrance door 11. The transmitter 22 includes sensors and the power supply circuit 5. The transmitter 22 includes an upper housing 23 that houses the infrared sensor 2, and a lower housing 24 that houses the transmitter 6 and the power supply circuit 5 of the radio wave sensor 3.

  The upper housing 23 and the lower housing 24 are connected vertically and integrated. The infrared sensor 2 in the upper housing 23 and the transmitter 6 of the radio wave sensor 3 in the lower housing 24 are connected by, for example, a USB connection mechanism (see, for example, FIG. 7).

  The transmitter 22 of the radio wave sensor device 21 is fixed to a vertical portion 13 that extends in the vertical direction of the door frame 12. The entrance door 11 is, for example, a one-sided door, and a transmitter 22 is attached to a vertical portion 13 opposite to the hinge 11a. The transmitter 22 may be attached to the head portion 14 extending in the horizontal direction in the door frame 12.

  The transmitter 22 is disposed on the outdoor side 15 a of the wall 15 of the house, and is disposed at a height corresponding to the head of the person 16. The infrared projector (irradiation unit) and the detection unit of the infrared sensor 2 are directed to the inside of the opening of the door frame 12.

  FIG. 3 is a cross-sectional view showing a state where the transmitter 22 is attached to the door frame 12. As shown in FIG. 3, the transmitter 22 is provided with a fixing bracket (fixing portion) 25 attached with the door frame 12 interposed therebetween.

  The fixing bracket 25 is formed to have a U-shape when the metal plate is bent and viewed from above. The fixing bracket 25 includes a holding piece 25a arranged on the outdoor side 15a of the wall 15 of the house, a holding piece 25b arranged on the indoor side 15b of the wall 15, and a connecting piece 25c for connecting these holding pieces 25a and 25b. Have.

  A convex shape 25d is provided at the center of the connecting piece 25c so as to correspond to the convex portion 12a protruding into the opening of the door frame 12. The back surface of the transmitter 22 is fixed to the sandwiching piece 25a by being bonded, for example. Bolt holes 25e penetrating in the plate thickness direction are provided in the clamping piece 25b on the indoor side, and adjusting bolts 26 are inserted into the bolt holes 25e.

  The adjustment bolt 26 is inserted from the indoor side toward the upright portion 13, and the tip portion protrudes toward the upright portion 13 rather than the sandwiching piece 25 b. A contact plate 27 is disposed at a position corresponding to the adjustment bolt 26, and by screwing the adjustment bolt 26, the contact plate 27 is pressed against the wall 15 and the holding piece 25 b is separated from the wall 15. Move to. Thereby, the fixing bracket 25 is pulled as a whole, and the holding piece 25 a on the indoor side is pressed against the vertical portion 13. Therefore, the fixing bracket 25 can be securely attached by sandwiching the upright portion 13 from both sides by the sandwiching piece 25a and the contact plate 27.

  In addition, the reception unit and the signal processing calculation unit of the radio wave sensor device 21 are arranged in a house. The radio wave medium transmitted from the transmission unit 6 of the radio wave sensor 3 passes through the wall 15 and is transmitted into the house, so that the state of the person inside can be detected.

  According to the radio wave sensor device 21 of the second embodiment as described above, since the infrared sensor 2 is attached to the vertical portion 13 of the door frame 12 of the entrance door 11, it is possible to detect the presence or absence of the person 16 passing through the entrance. It is possible to determine whether or not there is a person 16 in the house.

  Further, the transmitter 22 is provided with a fixing bracket 25, and the transmitter 22 can be simply fixed to the door frame 12 by fitting the fixing bracket 25 so as to sandwich the vertical portion 13 of the door frame 12.

  In the second embodiment, the infrared sensor 2 and the transmission unit 6 of the radio wave sensor 3 are integrally provided. However, the infrared sensor 2 and the transmission unit 6 of the radio wave sensor 3 are separately provided and connected by electric wires. May be. For example, the infrared sensor 2 is arranged outdoors, the transmission unit 6 of the radio wave sensor 3 is arranged indoors across a wall, and the detection result by the infrared sensor 2 is transmitted to the transmission unit 6 of the radio wave sensor 3 through an electric wire. . The radio wave sensor device having such a configuration may be used. Further, the transmitter 6 and the receiver 7 of the radio wave sensor 3 may be arranged outdoors to monitor the state of an outdoor person.

  Moreover, in 2nd Embodiment, although the transmitter 22 was attached to the door frame 12 of a front door, you may attach the transmitter 22 to the door frame of the entrance / exit in the room | chamber interior of a building. Further, the transmitter 22 may be attached to an entrance / exit of a building other than the entrance (for example, an entrance / exit leading to the rooftop). Moreover, the joinery frame to which the transmitter 22 is attached is not limited to the door frame of the entrance, and may be a window frame. Further, the joinery is not limited to a single-opening type, and may be a double-opening type, a sliding door type, or any other type.

(Third embodiment)
Next, the radio wave sensor device 31 according to the third embodiment will be described. In the third embodiment, a case where the transmitter 32 of the radio wave sensor device 31 is incorporated in the handrail 33 will be described. In the description of the third embodiment, the same description as in the above embodiment is omitted.

  As shown in FIG. 4, a handrail 33 is provided on the indoor wall 17 of the house. The handrail 33 is disposed in the vicinity of the switch 18 for turning on / off indoor lighting, for example. The handrail 33 includes a cylindrical handrail main body 34 and a support portion 35 that supports the handrail main body 34. The handrail main body 34 extends, for example, in the vertical direction, and a plurality of support portions 35 are provided apart from each other in the vertical direction. The support unit 35 includes a support ring that supports the handrail body 34 by inserting the support rail 34. The support ring is fixed to the indoor wall 17.

  As shown in FIG. 5, the support portion 35 includes a semicircular receiving portion 33 a that is in close contact with the outer peripheral surface of the handrail main body 34, and a cylindrical connection disposed between the receiving portion 33 a and the indoor wall 17. A portion 33b and a support plate 33c fixed to the base end of the connecting portion 33b may be provided.

  The transmitter 32 of the radio wave sensor device 31 according to the third embodiment includes sensors and a power circuit 5, and these sensors and the power circuit 5 are accommodated in a handrail body 34. That is, the casing of the transmitter 32 also serves as the handrail main body 34.

  On the upper side of the handrail main body 34, a housing portion for housing the sensors and the power supply circuit 5 is formed. The handrail main body 34 can be separated into a front side 34a and a back side 34b. A front opening 34c for exposing the lens portion 2a of the infrared sensor 2 is formed on the front side 34a.

  Further, a back surface opening 34 d is formed at a position corresponding to the support portion 35 on the back surface side 34 b of the handrail main body 34. The electric cord 37 that supplies power to the power supply circuit 5 passes through the rear opening 34 d and the connecting portion 33 b and is wired in the indoor wall 17.

  According to the radio wave sensor device 31 of the third embodiment, the casing of the transmitter 32 also serves as the handrail main body 34. Therefore, the transmitter 32 of the radio wave sensor device 31 can be easily provided by installing the handrail 33. Can be installed. Further, since the sensors and the power supply circuit 5 are arranged in the handrail main body 34, there is little possibility that the user will feel uncomfortable. Further, since the transmitter 32 is installed in the vicinity of the indoor lighting switch 18, when a person operates the switch 18 when entering or leaving the room, the person is reliably detected. And the state of a person can be detected.

(Fourth embodiment)
Next, the radio wave sensor device 41 according to the fourth embodiment will be described. In the fourth embodiment, a radio wave sensor device 41 including a plug-in type transmitter 42 will be described. In the fourth embodiment, the same description as in the above embodiment is omitted.

  As shown in FIGS. 7 to 9, the transmitter 42 of the radio wave sensor device 41 of the fourth embodiment includes an upper housing (first housing) 43 that accommodates the infrared sensor 2 and transmission of the radio wave sensor 3. And a lower housing (second housing) 44 that accommodates the portion 6. The upper housing 43 and the lower housing 44 are box-shaped and have the same width and thickness. The width is the length along the left-right direction when the state shown in FIG. 6 is the front, and the thickness is the length between the front and the back.

  As shown in FIGS. 7 and 8, the upper housing 43 and the lower housing 44 are connected by a USB (Universal Serial Bus) connection mechanism 45. The upper housing 43 is provided with a USB protrusion 45a, and the lower housing 44 is provided with a USB receiving portion 45b. By simply inserting the USB protrusion 45a into the receiving portion 45b, the upper housing 43 and the lower housing 44 can be connected to bring the bottom surface of the upper housing 43 into close contact with the top surface of the lower housing 44. .

  The lens portion 2 a of the infrared sensor 2 is supported so as to be rotatable with respect to the upper housing 43. The upper housing 43 is provided with a support pin 46 that rotatably supports the lens unit 2a. The support pin 46 is disposed along the vertical direction, and the lens holder (rotary body) 40 that holds the lens portion 2 a is rotatable about the support pin (axis) 46.

  A long hole 43e for exposing the lens portion 2a of the infrared sensor 2 is formed in the front plate 43a of the upper housing 43. As shown in FIG. 7, the inner diameter of the long hole 43e is longer in the left-right direction than in the up-down direction. The inner diameter along the vertical direction of the long hole 43e corresponds to the outer diameter of the lens portion 2a, and the inner diameter along the left-right direction corresponds to the rotation angle (rotation range) of the lens portion 2a.

  In the lower housing 44, a transmission antenna 47 that is the transmission unit 6 of the radio wave sensor 3 is arranged. The transmitting antenna 47 is fixed to the front plate 44a of the lower housing 44, for example. An AC adapter 48 having the power supply circuit 5 is disposed in the lower housing 44. The AC adapter 48 is fixed to the back plate 44 b of the lower housing 44. A plug (blade) 49 protruding from the AC adapter 48 protrudes outward from the back plate 44 b of the lower housing 44.

  The radio wave sensor device 41 also includes a shielding plate 50 that covers the back plate 44b of the lower housing 44 from the outer surface side. The shielding plate 50 is made of, for example, a metal plate, and is fixed to the back plate 44b by screwing. The shielding plate 50 is configured to be detachable from the lower housing 44.

  In addition, as shown in FIG. 7, an adjustment unit 51 for adjusting the transmission state of the radio wave medium is arranged in the lower housing 44, and an adjustment dial 51 a is attached to the adjustment unit 51. Yes. A part of the outer peripheral portion of the adjustment dial 51 a projects outward from the bottom plate 44 c of the lower housing 44. The user can easily adjust the carrier wave by rotating the dial 51a. Specifically, the frequency of the carrier wave can be changed.

  In addition, the radio wave sensor device 41 has a removable camera 52. A receiving portion 53 for inserting the USB of the camera 52 is accommodated in the lower housing 44, and an insertion port leading to the receiving portion 53 is formed in the side plate 44 d of the lower housing 44. The USB of the camera 52 can be inserted into the receiving portion 53 and attached. Data captured by the camera 52 is transmitted to the receiving unit 7 by the carrier wave transmitted from the transmitting unit 6 of the radio wave sensor 3 and processed by the signal processing calculation unit 4. FIG. 7 shows a state where the camera 52 is not attached.

  According to the radio wave sensor device 41 of the fourth embodiment as described above, the upper housing 43 and the lower housing 44 can be integrated using the USB connection mechanism 45, and the infrared sensor 2 and the radio wave sensor 3 can be integrated. The transmitter 6 can be electrically connected. Thereby, while being able to supply electric power to the infrared sensor 2, the detection result by the infrared sensor 2 can be sent to the transmission unit of the radio wave sensor 3. As a result, the detection result of the infrared sensor 2 can be transmitted using the carrier wave transmitted from the transmission unit 6 of the radio wave sensor 3.

  Moreover, since the upper housing | casing 43 and the lower housing | casing 44 are integrated, the installation of the transmitter 42 is easy and the design property can also be improved.

  Since the transmitter 42 is provided with the plug 49, the transmitter 42 can be easily installed simply by inserting the plug 49 into the outlet 54. Since it can be arranged at the position of the outlet 54, the transmitter 42 can be made inconspicuous.

  Moreover, since the lens part 2a of the infrared sensor 2 can be rotated around a rotation axis extending in the vertical direction, the detection range of the infrared sensor 2 can be expanded by changing the direction of the lens part 2a. Therefore, the installation position of the infrared sensor 2 is not limited, and even if the transmitter 42 is arranged at the position of the outlet, the object can be reliably detected by directing the lens portion 2a of the infrared sensor 2 to a predetermined position. Can do.

  Moreover, since the shielding plate 50 is attached to the back side of the transmitter 42, the radio wave medium emitted from the transmission unit 6 and the range (direction) of the transmission medium can be limited. By attaching / detaching the shielding plate 50, the emission range of the radio wave medium and the transmission medium can be easily adjusted.

  Next, a shielding plate according to a modification will be described with reference to FIG. By attaching the shielding plates 55 and 56 as shown in FIG. 9 to the transmitter, the radio wave medium emitted from the transmission unit 6 of the radio wave sensor 3 and the range of the transmission medium may be limited.

  The shielding plate 55 shown in FIG. 9A is formed to have an L shape. The shielding plate 55 has a main body 55 a that covers the back surface of the lower housing 44 of the transmitter 42, and a side portion 55 b that is bent from the main body 55 a and covers the side surface of the lower housing 44. Thereby, the range of the radio wave medium and the transmission medium emitted from the transmission unit 6 can be limited to the side where the front surface and the side portion 55b are not disposed.

  The shielding plate 56 shown in FIG. 9B is formed to have a U shape. The shielding plate 56 includes a main body 56 a that covers the back surface of the lower housing 44 of the transmitter 42, and a pair of side portions 56 b that are bent from the main body 56 a and cover both side surfaces of the lower housing 44. Thereby, the range of the radio wave medium radiate | emitted from the transmission part 6 can be limited to a front.

  In addition, the shape of a shielding board is not limited to these, The thing which covers a bottom part and the top part may be covered. Moreover, the shape which has a curved part like U shape may be sufficient.

  The present invention is not limited to the above-described embodiments, and various modifications as described below are possible without departing from the gist of the present invention.

  In the above embodiment, the configuration including an infrared sensor as the human sensor is illustrated, but the human sensor is not limited to the infrared sensor, and may be other sensors such as a television camera, a doorbell switch, and a proximity switch. In addition, a detection result by a sensor other than the human sensor may be transmitted from the transmission unit of the radio wave sensor 3. Examples of sensors other than the human sensor include a temperature sensor and a humidity sensor.

  Further, the rotation direction of the lens portion of the infrared sensor is not limited to the rotation direction in the horizontal direction, and may be the rotation direction in the vertical direction or the rotation direction in other directions.

  Further, the outer shape of the casing of the transmitter is not limited to a box shape, and may be a cylindrical shape or other shapes. Moreover, in the said embodiment, although the housing | casing which accommodates an infrared sensor is arrange | positioned in the upper part, and the housing | casing which accommodates the transmission part 6 of the electromagnetic wave sensor 3 are arrange | positioned in the lower part, you may make the up-down direction reverse, You may connect with right and left, and may connect with front and back (front side or back side).

  The radio wave sensor device is not limited to home use, and may be installed in places such as a residence for elderly people, a rental housing for single people, a hospital, a store, a factory, a station, and an office.

  1, 2, 31, 41 ... Radio wave sensor device, 2 ... Infrared sensor (human sensor), 2a ... Lens part (infrared detector), 3 ... Radio wave sensor, 5 ... Power supply circuit, 6 ... Transmission part of radio wave sensor, DESCRIPTION OF SYMBOLS 7 ... Reception part of a radio wave sensor, 8 ... Transmitter, 9 ... Housing, 12 ... Door frame (joint frame), 13 ... Standing part, 25 ... Fixing bracket (fixing part), 33 ... Handrail, 34 ... Handrail body (common) 49) plug, 50, 55, 56 ... shielding plate.

Claims (9)

A radio wave sensor having a transmitter for transmitting a radio wave medium for detecting a human condition and a receiver for receiving the radio wave medium;
Unlike the radio wave sensor, comprising a human sensor capable of detecting whether or not a person exists,
The radio wave sensor device, wherein a transmission medium for transmitting a detection result by the human sensor is transmitted from a transmission unit of the radio wave sensor.   The radio wave sensor device according to claim 1, further comprising a common power supply circuit that supplies power to both the transmitter of the radio wave sensor and the human sensor.   The radio wave sensor device according to claim 1, wherein the human sensor is an infrared sensor.   The radio wave sensor device according to claim 3, wherein the infrared detection unit of the infrared sensor is rotatable about an axis extending in a vertical direction.   The radio wave sensor device according to claim 1, wherein the transmission unit of the radio wave sensor and the human sensor are housed in a common housing. The housing that accommodates the human sensor is provided with a fixing portion that is fixed to a duck part or a vertical part of a joinery frame installed at a doorway of a building,
The radio wave sensor device according to claim 4, wherein the fixing portion includes a pair of clamping pieces that clamp the head portion or the vertical portion.   5. A plug that protrudes outward from the surface and that can be inserted into an outlet installed on a wall surface of a building is provided on a surface of a housing that houses a transmission unit of the radio wave sensor. The radio wave sensor device described in 1.   The transmission unit of the radio wave sensor and the infrared sensor are housed in a handrail installed on a wall surface of a building, and the infrared detection unit of the infrared sensor is exposed from the handrail. Radio wave sensor device.   The transmission unit of the radio wave sensor is provided with a shielding plate that shields the radio wave medium, and an emission range of the radio wave medium can be adjusted by attaching and detaching the shielding plate. The radio wave sensor device according to claim 7.

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