WO2015129150A1 - Motion-sensor-equipped automatic switch system - Google Patents

Abstract

The motion-sensor-equipped automatic switch system (30) comprises: a motion-sensor-equipped automatic switch (10) provided with a heat ray sensor unit (1), a first input determination unit (2), a signal reception unit (3), a control unit (4) for controlling the lighting/extinguishing of a lighting load (52), and a switching device (5) for turning on and off the lighting load (52) based on the control signal from the control unit (4); and an operation console (20) provided with a second input determination unit (22), and a signal sending unit (23) for sending a communication signal based on the second input determination unit (22). In response to the communication signal, the control unit (4) brings the lighting load (52) into a lighting state, and, after a predetermined light-holding time has elapsed, into an extinguished state. If, while the lighting load (52) is in the lighting state, a sensor signal from the heat ray sensor unit (1) is entered, the control unit (4) brings the lighting load (52) into the extinguished state after a predetermined light-holding time since the sensor signal has been entered.

Description

Automatic switch system with human sensor

The present invention relates to an automatic switch system with a human sensor that detects the presence of a human body with a heat ray or the like and controls lighting / extinguishing of a lighting load.

Conventionally, an automatic switch with a heat ray sensor has been used to control the lighting load on / off. In this type of automatic switch with a heat ray sensor, when the light is automatically turned on, when the heat ray sensor detects a person, the illumination load is turned on for the operation holding time (see, for example, Patent Document 1).

In the automatic switch with a heat ray sensor of Patent Document 1, the operation mode of continuous lighting, automatic lighting, and forced extinction of the illumination load is switched by pressing the operation handle.

Also, as an automatic switch system with a heat ray sensor, an illumination system including a switch with a heat ray sensor connected to a plurality of illumination loads, a slave unit, and an external device is known (see Patent Document 2).

In the lighting system of Patent Document 2, each lighting load is turned on when power from a commercial power supply is supplied via a switch with a heat ray sensor. The child unit includes a heat ray sensor having the same function as the heat ray sensor of the switch with heat ray sensor, and is connected to the switch with heat ray sensor. The external device outputs an external signal based on a user operation. The switch with a heat ray sensor turns on and off each illumination load based on an external signal.

JP 2008-109511 A JP 2006-331890 A

By the way, in the automatic switch with a heat ray sensor of patent document 1, for example, when the automatic switch with a heat ray sensor is installed at the entrance, the illumination load remains off in the corridor on the way until the person approaches the entrance. There are cases. Moreover, in the automatic switch with a heat ray sensor of patent document 1, in order to switch automatic lighting and forced extinction, you have to operate the operation handle itself of the automatic switch with a heat ray sensor. Furthermore, in the automatic switch with a heat ray sensor of Patent Document 1, once the operation mode is switched to the forced-off operation mode, the lighting load is turned off and the usability may be poor. Moreover, in the illumination system of the above-mentioned patent document 2, it is only described that lighting on and off of the illumination load is controlled by a user operation on an external device. In the configuration of the automatic switch with a heat ray sensor of Patent Document 1 and the illumination system of Patent Document 2 described above, it is not described that unnecessary power consumption is suppressed in consideration of usability.

The automatic switch system with a heat ray sensor is required to have higher usability, and the configuration of the automatic switch with a heat ray sensor described in Patent Document 1 and the illumination system disclosed in Patent Document 2 are not sufficient, and further improvement is required. Yes.

The present invention has been made in view of the above reasons, and an object thereof is to provide an automatic switch system with a human sensor having higher usability.

The automatic switch system with a human sensor according to the present invention includes an automatic switch with a human sensor and an operation unit. The automatic sensor-equipped automatic switch includes a human sensor unit, a first input determining unit, a signal receiving unit, a control unit, and a switch. The human sensor unit detects the presence or absence of a human body using a heat ray emitted from the human body and outputs a sensor signal. The first input determining unit determines whether or not the first operation switch operated manually is operated. The signal receiving unit receives a transmission signal from the operation unit. The control unit controls the lighting load on / off based on the sensor signal from the human sensor unit, the determination signal from the first input determination unit, and the transmission signal received by the signal reception unit. Output a signal. The switch turns on / off the supply of power to the lighting load based on the control signal from the control unit. The operation unit includes a second input determination unit and a signal transmission unit. The second input determining unit determines whether or not the second operation switch operated manually is present. The signal transmission unit transmits the transmission signal to the human sensor-equipped automatic switch based on an operation signal from the second input determination unit. The control unit of the human sensor-equipped automatic switch is configured to turn on the lighting load according to the transmission signal from the operation unit and turn off the lighting load after a predetermined lighting holding time has elapsed. To control. When the sensor signal from the human sensor unit is input while the lighting load is in a lighting state, the control unit causes the light to be turned off after a predetermined lighting holding time from the input of the sensor signal. Control the switch.

In this automatic switch system with human sensor, it is preferable to further include a sensor slave unit. The sensor slave includes a second human sensor unit and a detection signal transmission unit. The second human sensor unit detects the presence or absence of a human body. The detection signal transmission unit transmits a detection signal to the human sensor-equipped automatic switch based on the second sensor signal from the second human sensor unit. The control unit controls the switch so that the lighting load is turned on in accordance with the detection signal from the sensor slave unit and is turned off after a predetermined lighting holding time elapses. When the sensor signal or the detection signal is input during the lighting holding time, the control unit is configured to turn off the switch after the lighting holding time after the sensor signal or the detection signal is input. Is preferably controlled.

In the automatic switch system with human sensor according to the present invention, when a sensor signal is input while a lighting load is in a lighting state according to a transmission signal, the automatic switching system is turned off after a predetermined lighting holding time after the sensor signal is input. Thus, there is an effect that usability can be further increased.

FIG. 1 is a block diagram illustrating an automatic switch system with a human sensor according to a first embodiment. FIG. 2 is an operation explanatory diagram of the automatic switch system with human sensor according to the first embodiment. FIG. 3 is a perspective explanatory view of the human sensor-equipped automatic switch according to the first embodiment. FIG. 4 is a front explanatory view of the human sensor-equipped automatic switch according to the first embodiment. FIG. 5 is an exploded perspective view for explaining the automatic switch with a human sensor according to the first embodiment. FIG. 6 is an explanatory front view showing a main part of the automatic switch with human sensor according to the first embodiment. FIG. 7 is an explanatory front view showing another main part of the human sensor-equipped automatic switch according to the first embodiment. FIG. 8 is an explanatory side view showing another main part of the human sensor-equipped automatic switch according to the first embodiment. FIG. 9 is a rear view of the human sensor-equipped automatic switch according to the first embodiment. FIG. 10 is a cross-sectional view taken along the line AA of the human sensor-equipped automatic switch of FIG. FIG. 11 is an enlarged view of a portion surrounded by a broken line of the human sensor-equipped automatic switch of FIG. 12 is a BB cross-sectional view of the human sensor-equipped automatic switch of FIG. FIG. 13 is an enlarged view of a portion surrounded by a broken line of the human sensor-equipped automatic switch of FIG. FIG. 14 is a rear view illustrating the main part of the human-sensor-equipped automatic switch according to the first embodiment. FIG. 15 is an explanatory perspective view of the operation unit in the first embodiment. FIG. 16 is a block diagram illustrating an automatic switch system with a human sensor according to a second embodiment. FIG. 17 is a perspective explanatory view of a sensor slave unit in the second embodiment.

(Embodiment 1)
An automatic switch system 30 with a human sensor according to this embodiment will be described with reference to FIGS. 1 and 2. The human sensor-equipped automatic switch 10 according to this embodiment will be described with reference to FIGS. 1, 3 to 14. The operation unit 20 in this embodiment will be described with reference to FIGS. 1 and 15. In addition, in the figure, the same number is attached | subjected with respect to the same member, and the overlapping description is abbreviate | omitted.

The human sensor-equipped automatic switch system 30 according to the present embodiment includes a human sensor-equipped automatic switch 10 and an operating unit 20 as shown in FIG. Hereinafter, the human sensor-equipped automatic switch system 30 according to the present embodiment is also referred to as a system 30. The human sensor-equipped automatic switch 10 is also referred to as a switch master unit 10.

The switch master unit 10 includes a heat ray sensor unit 1, which is one of human sensor units, a first input determination unit 2, a signal reception unit 3, a control unit 4, and a switch 5. The heat ray sensor unit 1 detects the presence or absence of a human body using a heat ray emitted from a human body, and outputs a sensor signal. The first input determination unit 2 determines whether or not the first operation switch 2a operated manually is present. The signal receiving unit 3 receives a transmission signal from the operation unit 20. The control unit 4 controls the lighting load 52 to be turned on / off based on the sensor signal from the heat ray sensor unit 1, the determination signal from the first input determination unit 2, and the transmission signal received by the signal reception unit 3. Is output. The switch 5 turns on and off the supply of power to the lighting load 52 based on a control signal from the control unit 4.

The operating unit 20 includes a second input determination unit 22 and a signal transmission unit 23. The second input determination unit 22 determines whether or not the second operation switch 22a operated manually is present. The signal transmission unit 23 transmits a transmission signal to the switch parent device 10 based on the operation signal from the second input determination unit 22.

The control unit 4 of the switch parent 10 controls the switch 5 so that the lighting load 52 is turned on in accordance with a transmission signal from the operation unit 20 and is turned off after a predetermined lighting holding time has elapsed. When the sensor signal from the heat ray sensor unit 1 is input while the illumination load 52 is in the lighting state, the control unit 4 switches the switch 5 so that the light is turned off after a predetermined lighting holding time after the sensor signal is input. To control.

As a result, the system 30 can further improve usability.

Hereinafter, a more specific configuration of the system 30 will be described.

In the system 30, the switch master 10 shown in FIGS. 3 to 14 is attached to the attachment frame 17 and installed on a construction surface (not shown) such as a wall surface of a building. The switch master 10 includes a container body 11 that is embedded in a construction material that constitutes a construction surface.

The container 11 has a rectangular parallelepiped shape. The body 11 is composed of a bottomed rectangular tube-shaped body body 11a and a bottomed rectangular tube-shaped cover body 11b. The body 11 is a box with a hollow inside by fitting the body 11a and the cover 11b. The container 11 is configured so that the heat ray sensor unit 1, the first input determination unit 2, the control unit 4, the switch 5 and the light emitting diode 6a can be housed therein. Note that the switch parent 10 has a size of a single-unit module corresponding to three of one module of the embedded wiring device in the size of the body 11. The body 11 has a dimension in the short direction of the container 11 having a rectangular shape in front view, which is slightly smaller than the dimension in the short direction of the first window hole 17aa in the mounting frame 17 for the embedded wiring device. .

The body body 11a includes an engagement protrusion 11ac for fitting with the cover body 11b. The engaging protrusions 11ac are provided in pairs along the short direction of the upper and lower sides of the body body 11a (up and down on the paper surface of FIG. 5). The body body 11a is formed of an electrically insulating resin material. For the body 11a, for example, ABS (acrylonitrile butadiene styrene copolymer) resin, urea resin, or the like can be used as an electrically insulating resin material. The body body 11a can be formed, for example, by injection molding in which an electrically insulating resin material that has been heated and melted is injected and injected into a mold and then cooled and solidified.

The switch parent unit 10 is electrically connected to the operation unit 20, the commercial power source 51, and the lighting load 52 by an electric wire (not shown). As shown in FIG. 5, the switch parent device 10 includes a terminal 11c to which an electric wire is connected. The body body 11a houses the terminal 11c. The terminal 11c includes a lock spring 11ca that applies a spring force to the electric wire, and a terminal plate 11cb that accommodates the lock spring 11ca. When the electric wire is inserted, the terminal 11c is configured to be electrically connected to the electric wire and be fixed by the terminal plate 11cb and the lock spring 11ca. The lock spring 11ca can be formed by bending a plate material made of a metal material.

As the metal material of the lock spring 11ca, for example, copper or copper alloy can be used. Similarly, the terminal plate 11cb can be formed by bending a plate material made of a metal material. As a metal material of the terminal board 11cb, for example, copper, copper alloy, or the like can be used. The terminal 11c constitutes a quick connection terminal in which electrical connection and mechanical connection with the electric wire are performed by inserting the core wire in the electric wire from which the insulation coating has been removed.

Further, the body body 11a includes a button 11cc for releasing the electric wire from the quick connection terminal. In the switch parent 10, the button 11 cc deforms the lock spring 11 ca by pressing and pressing the button 11 cc with a jig (not shown) from the back of the body 11 shown in FIG. 9. In the switch parent 10, the terminal 11 c is configured so that the electric wire can be pulled out from the container 11 by deformation of the lock spring 11 ca. The terminal 11c constitutes a first power supply terminal 11c1, a second power supply terminal 11c2, a first load terminal 11c4, a second load terminal 11c3, a first connection terminal 11c5, and a second connection terminal 11c6, which will be described later.

The cover body 11b includes a pair of projecting pieces 11bc and 11bc projecting toward the body body 11a along the short side direction of the cover body 11b (up and down of the paper surface in FIG. 5). The protruding piece 11bc is configured to be elastically deformable with respect to the cylindrical portion of the bottomed rectangular cylindrical cover body 11b. The cover body 11b can be formed by integrally molding the cylindrical portion and the protruding piece 11bc. The protruding piece 11bc has a C-shaped outer shape, and has an engagement hole 11bf at a portion protruding from the tubular portion and exposed to the outside. The cover body 11b is configured so that the engagement hole 11bf of the protruding piece 11bc and the engagement protrusion 11ac of the body body 11a can be fitted together.

The cover body 11b is provided with mounting claws 11bd protruding from the side wall 11bb on the side wall 11bb in the short side direction. The cover body 11b can fit the instrument mounting hole 17ab of the mounting frame 17 and the mounting claw 11bd. The cover body 11b is provided with cut grooves 11bg and 11bg along the thickness direction on both side portions of the side wall 11bb where the pair of mounting claws 11bd and 11bd protrude. The cover body 11b is provided with a bending piece 11be having flexibility in the thickness direction at a portion between the pair of mounting claws 11bd and 11bd. The cover body 11b is configured such that the bending piece 11be can be bent into the inside of the container body 11. The cover body 11b is formed of an electrically insulating resin material. The cover body 11b can be formed using, for example, an ABS resin or a urea resin as an electrically insulating resin material. The cover body 11b can be formed by, for example, injection molding in which an electrically insulating resin material heated and melted is injected and injected into a mold and cooled and solidified.

The mounting frame 17 is formed in a frame shape by a pair of opposing side pieces 17a and 17a and a pair of opposing frame pieces 17b and 17b. The side piece 17a includes an instrument mounting hole 17ab to which the vessel 11 can be mounted. The attachment frame 17 can hold | maintain the body 11 to the attachment frame 17 by fitting the attachment nail | claw 11bd of the cover body 11b to the instrument attachment hole 17ab. When the container body 11 is attached to the attachment frame 17, for example, the attachment claws 11 bd of one side wall 11 bb of the cover body 11 b are inserted into one instrument attachment hole 17 ab of the attachment frame 17. Next, the container body 11 inserts the cover body 11b into the first window hole 17aa of the mounting frame 17 so that the mounting claws 11bd of the other side wall 11bb are bent to the inside of the cover body 11b. After the body 11 is inserted so as to be embedded in the mounting frame 17, the mounting claw 11 bd of the other side wall 11 bb of the cover body 11 b is inserted into the other instrument mounting hole 17 ab of the mounting frame 17. The body 11 is held by the mounting frame 17 by inserting the mounting claws 11bd into the instrument mounting holes 17ab. Further, in the switch parent device 10, when the device body 11 is removed from the mounting frame 17, the bending piece 11 be is pushed into the cover body 11 b. The switch master 10 can remove the body 11 from the mounting frame 17 by the mounting claws 11bd coming out of the device mounting hole 17ab by the bending of the bending piece 11be.

The mounting frame 17 has a long hole 17ac in the frame piece 17b as shown in FIGS. A fixing screw (not shown) is inserted through the long hole 17ac. The mounting frame 17 is fixed to the construction surface side by, for example, screwing a fixing screw inserted into the long hole 17ac into a screw portion of an embedding box (not shown) embedded in the construction surface. The Further, as shown in FIGS. 3 and 5, the mounting frame 17 includes a screw hole 17ad for a plate screw in the frame piece 17b. Although not shown, the attachment frame 17 can be screwed on the surface side of the attachment frame 17 using a rectangular frame plate frame (not shown) and a plate screw (not shown). . The mounting frame 17 can have various shapes as long as the container body 11 can be mounted. The attachment frame 17 can be comprised with a resin body or a metal body, for example.

The switch master 10 houses a circuit portion 16 capable of controlling the lighting load 52 to be turned on and off in the body 11. The circuit unit 16 includes a first circuit board 16a and a second circuit board 16c. The first circuit board 16a has a rectangular flat plate shape. The first circuit board 16a can be formed of a printed wiring board. The circuit unit 16 has a first circuit board 16a and a second circuit board 16c arranged to face each other via a flat insulating plate 16b. The circuit unit 16 electrically connects the first circuit board 16a and the second circuit board 16c with a conductor or the like (not shown). The second circuit board 16c has a rectangular flat plate shape. The second circuit board 16c can be formed of a printed wiring board or the like.

The circuit unit 16 may be configured to include, for example, the heat ray sensor unit 1, the first input determination unit 2, the signal receiving unit 3, the control unit 4, and the light emitting diode 6a on the first circuit board 16a. The first circuit board 16a is mounted with an electronic component 16aa constituting the signal receiving unit 3. The first circuit board 16a is mounted with an electronic component 16aa constituting the control unit 4. The first circuit board 16a has a plurality of (here, three) light emitting diodes 6a mounted thereon. The first circuit board 16a is mounted with a switch body 2aa having an operation element 2ac that is pushed and driven by the manual operation unit 2a1. The first circuit board 16a is mounted with a photodiode constituting the brightness sensor 1s. Furthermore, the first circuit board 16a may be mounted with various electronic components 16aa such as a fuse, a temperature fuse for suppressing abnormal heat generation, and a relay for preventing leakage. The first circuit board 16a is formed with wiring of a predetermined shape (not shown) so that it can be electrically connected to various electronic components 16aa.

Moreover, the circuit unit 16 can be configured to include, for example, the DC stabilized power supply 4c and the switch 5 on the second circuit board 16c. The DC stabilized power supply 4c is suitably provided for lighting the illumination load 52.

The second circuit board 16c, as the switch 5, is mounted with an open / close element 5a constituting a main switch element and an open / close drive unit 5b for controlling the drive of the open / close element 5a. The switching element 5a can be configured using a bidirectional three-terminal thyristor. The open / close drive unit 5b is configured to be capable of on / off control of the open / close element 5a by a control signal. The switch 5 may be constituted by a mechanical switch having a movable contact and a fixed contact in addition to an electronic switch having a main switch element as a semiconductor switch element. The second circuit board 16c is mounted with an electronic component 16aa constituting the DC stabilized power supply 4c. On the second circuit board 16c, a wiring having a predetermined shape (not shown) is formed.

The heat ray sensor unit 1 can be configured using an infrared sensor 1a. The infrared sensor 1a is mounted on the first circuit board 16a. For example, the infrared sensor 1a detects heat rays emitted from a human body. The heat rays are infrared rays that are electromagnetic waves in the infrared region. The infrared sensor 1a may be configured to include a pyroelectric element. The heat ray sensor unit 1 may be configured to detect infrared rays at any time, or may be configured to detect infrared rays at predetermined time intervals. In other words, the heat ray sensor unit 1 constitutes a human sensor provided with a sensor capable of detecting the presence or absence of a human body. For example, the heat ray sensor unit 1 may be configured integrally with a brightness sensor 1s such as a photodiode so that ambient brightness can be detected by the brightness sensor 1s. The human sensor unit not only includes an infrared sensor that detects a heat ray like the heat ray sensor unit 1 in the present embodiment, but also by an ultrasonic wave, a sound, a vibration, or the like such as an ultrasonic sensor or a sound sensor. You may provide the sensor which detects the presence or absence of a human body.

The heat ray sensor unit 1 includes a protruding portion 1k that protrudes from the front of the first operation switch 2a in order to ensure a predetermined viewing angle. The heat ray sensor unit 1 includes a cylindrical optical member 1r. Although not shown, the optical member 1r has a mirror for expanding the detection area of the infrared sensor 1a. The heat ray sensor unit 1 covers the infrared sensor 1a and the optical member 1r with a sensor cover 1aa. The sensor cover 1aa has a semi-cylindrical outer shape. In the heat ray sensor unit 1, the infrared sensor 1a detects a heat ray emitted from a human body via the sensor cover 1aa. The sensor cover 1aa has a Fresnel lens that collects infrared rays. The sensor cover 1aa can be formed using, for example, polyethylene resin. The switch master 10 sandwiches the sensor cover 1aa between the cover body 11b of the container body 11 and the first circuit board 16a, and houses the sensor cover 1aa inside the container body 11.

The heat ray sensor unit 1 includes a pair of shutters 1b and 1b between a cover body 11b of the body 11 and the sensor cover 1aa. Each shutter 1b is integrally provided with a base 1ba having an arcuate outer shape and a handle part 1bb erected from one end of the base 1ba. Each shutter 1b is configured to be movable along the surface of the sensor cover 1aa. Each shutter 1b can cover a part of the sensor cover 1aa. Each shutter 1b can move the base 1ba by operating the handle part 1bb. The shutter 1b can be formed using, for example, a polycarbonate resin. The heat ray sensor unit 1 can adjust the detection region where the heat ray sensor unit 1 detects a human body by moving the base 1ba of each shutter 1b. The switch parent 10 can adjust the detection area of the heat ray sensor unit 1 to adjust the detection area of the human body.

The first input determination unit 2 is configured to receive an output signal from the first operation switch 2a. The first operation switch 2a is configured such that the manual operation unit 2a1 is manually pressed and the switch operation of the switch body 2aa can be performed. That is, the manual operation unit 2a1 constitutes a part of the first operation switch 2a that is manually pressed. The first input determination unit 2 only needs to be able to determine whether or not the first operation switch 2a has been operated.

The manual operation unit 2a1 is configured using a makeup lid 2g, a handle 2f, and a cover body 11b. The decorative lid part 2g includes a translucent member 2g1 provided on the one surface 2ab side to be pressed and a base plate 2g2 provided on the cover body 11b side. The manual operation portion 2a1 includes a handle portion 2a2 provided so as to overlap the protruding portion 1k of the heat ray sensor portion 1. The handle portion 2a2 is provided with a hook recess 2a3 so that the user can easily remove the makeup lid portion 2g by hooking a finger.

The handle portion 2f holds the makeup lid portion 2g so as to be removable. The switch parent 10 has an opening 2f1 formed in the handle 2f so that the first surface 11bp of the container 11 is exposed to the outside by removing the decorative lid 2g from the handle 2f. Further, the handle portion 2f has a through hole 2f3 that penetrates in the thickness direction of the handle portion 2f.

The translucent member 2g1 has a rectangular plate-like outer shape. The translucent member 2g1 can be formed of a translucent resin material. For the translucent member 2g1, for example, a polycarbonate resin can be used as the translucent resin material. As shown in FIGS. 10 to 14, the decorative lid portion 2g has a light diffusion layer 2g5 on the handle portion 2f side of the translucent member 2g1. The light diffusion layer 2g5 is formed by screen-printing a resin containing a white pigment on the translucent member 2g1. As the white pigment, for example, silicon dioxide or barium titanate can be used. The light diffusion layer 2g5 can be formed by applying the light transmissive member 2g1 by screen printing. In the decorative lid portion 2g, not only the light diffusing layer 2g5 is formed by screen printing, but also a sheet constituting the light diffusing layer 2g5 formed in advance may be attached to the translucent member 2g1. In the decorative lid portion 2g, the translucent member 2g1 is attached to and held on the base plate 2g2 by a double-sided tape or the like. The base plate 2g2 has a through hole 2gc provided corresponding to the through hole 2f3 of the handle portion 2f.

As shown in FIGS. 5, 11, and 14, the manual operation unit 2a1 includes nail parts 2g3 at the four corners of the makeup lid 2g. The manual operation portion 2a1 includes a locking hole 2f2 at the position of the handle portion 2f corresponding to the claw portion 2g3 of the base plate 2g2. The decorative lid portion 2g is configured to be detachable so that the claw portion 2g3 of the base plate 2g2 can be hooked and stopped in the locking hole 2f2 of the handle portion 2f.

The cover body 11b includes a third window hole 11bh and a fourth window hole 11bi having a circular shape in plan view on the upper side of the cover body 11b (on the left side in FIG. 5). The cover body 11b includes three first cylindrical protrusions 11bs having a rectangular shape in plan view along the short side direction of the cover body 11b at the center of the cover body 11b. The switch parent 10 emits the light of the light emitting diode 6a from the fifth window hole 11bj of the first cylindrical protrusion 11bs. The light of the light emitting diode 6a emitted from the first cylindrical protrusion 11bs is emitted to the outside of the switch parent device 10 through the decorative lid portion 2g. The cover body 11b includes a projecting portion 11bk that protrudes outward from the first surface 11bp side of the cover body 11b on the lower side of the cover body 11b (on the right side in FIG. 5). The cover body 11b includes an opening 11bm in the projecting portion 11bk.

Further, since the cover body 11b is rotatably attached to the handle portion 2f of the manual operation portion 2a1, a shaft portion 11bn protruding on one side wall side (the lower side of the paper surface of FIG. 5) of the first surface 11bp of the cover body 11b. It has. The shaft portion 11bn is formed in a cylindrical shape along the longitudinal direction of the cover body 11b. As shown in FIGS. 5, 12, and 14, the shaft portion 11 bn of the cover body 11 b is pressed against the handle portion 2 f side of the manual operation portion 2 a 1 by the metal leaf spring 2 d. In other words, the manual operation portion 2a1 is held by the body 11 with the handle portion 2f and the leaf spring 2d holding the shaft portion 11bn of the cover body 11b. Further, the cover body 11b has a peripheral portion so that, when seen in a plan view, an end portion is held at the center portion of the first surface 11bp of the cover body 11b and the other end side (upper side of the paper surface of FIG. Is provided with a bent portion 11br. The bending portion 11br is configured to be bent inside the vessel body 11 by the pressing force from the handle portion 2f.

The first operation switch 2a is a piano handle in which one end portion of the handle portion 2f in the manual operation portion 2a1 is supported by the body 11, and the other end portion can be pushed and rotated. That is, the first operation switch 2a constitutes a piano handle type switch. The piano handle type switch is configured such that a piano handle attached to the front side of the switch main body 2aa is rotated by pressing the other side of the piano handle as a fulcrum. The piano handle constitutes a part of a switch capable of pressing the operation element 2ac of the switch body 2aa. The piano handle type switch can be operated by a piano touch on the piano handle.

As shown in FIG. 12, the manual operation portion 2a1 is configured such that the T-shaped bending portion 11br and the operation element 2ac can come into contact with each other. The manual operation unit 2a1 is supported by the body 11 so that the back side of the manual operation unit 2a1 can come into contact with the bending portion 11br of the cover body 11b. When the user pushes the manual operation unit 2a1, the switch base unit 10 pushes the manual operation unit 2a1 toward the cover body 11b. In the switch parent device 10, the manual operation portion 2 a 1 pushes the operation element 2 ac inside the device body 11 through the bending portion 11 br by a push operation to the manual operation portion 2 a 1. In the switch parent device 10, the first operation switch 2a is turned on when the operation element 2ac is pressed. The switch master 10 can be configured such that when the pressing force disappears from the manual operation unit 2a1, the manual operation unit 2a1 receives the reaction force of the operation element 2ac and returns to the original position. In the switch parent device 10, when the manual operation unit 2a1 returns to the original position, the first operation switch 2a is turned off. For example, a tactile switch can be used as the first operation switch 2a.

As shown in FIG. 3, the switch master 10 is provided with a protrusion 2g4 on the surface of the decorative lid 2g. In the switch parent device 10, the protrusion 2g4 of the decorative lid 2g can be used as a mark when the user operates the manual operation unit 2a1.

The switch parent 10 can efficiently radiate the light from the light emitting diode 6a to the outside by inserting at least a part of the first cylindrical protrusion 11bs into the through hole 2f3 of the handle portion 2f. In addition, the switch master 10 can suppress external light from being introduced into the interior of the body 11 and absorbed. Therefore, when the light emitting diode 6a is turned off, the switch parent device 10 can suppress that the portion where the light from the light emitting diode 6a in the decorative lid portion 2g emits light becomes dark due to external light.

Further, in the switch parent device 10, as shown in FIG. 10, the handle portion 2 f includes a second cylindrical protrusion 2 fs that protrudes toward the container body 11 and surrounds the first cylindrical protrusion 11 bs. In the switch parent device 10, light from the first cylindrical protrusion 11bs leaks between the manual operation part 2a1 and the cover body 11b by the second cylindrical protrusion 2fs regardless of the operation of the manual operation part 2a1. Can be suppressed. Thereby, the switch parent 10 can irradiate the light from the light emitting diode 6a to the makeup lid part 2g side more efficiently. Further, in the switch parent device 10, the device body 11 includes a third cylindrical protrusion 11 bt projecting inside so as to surround the light emitting diode 6 a. Thereby, the switch master 10 can suppress the diffusion of light from the light emitting diode 6 a inside the container 11, and can efficiently emit the light of the light emitting diode 6 a to the outside of the container 11.

In the switch parent device 10, the control unit 4 has a built-in timer unit (not shown) for measuring the lighting holding time during which the lighting load 52 is lit. When the sensor signal is input again from the heat ray sensor unit 1 while the lighting holding time is being measured, the control unit 4 causes the lighting load 52 to be turned off after a predetermined lighting holding time from the time when the sensor signal is input again. It is configured. Therefore, the timer unit is constituted by a retriggerable timer so that a predetermined lighting holding time can be measured from the time when the sensor signal is re-input.

As a basic operation, the control unit 4 is based on a change in the heat ray incident on the heat ray sensor unit 1 in a state where the brightness detected by the brightness sensor 1s is darker than a preset brightness threshold. When a sensor signal indicating detection is input, the illumination load 52 is turned on. Note that the brightness threshold value may be stored in a memory (not shown) of the control unit 4, for example. The control unit 4 controls the switch 5 so as to maintain the lighting state of the lighting load 52 for a predetermined lighting holding time counted by the timer unit.

In the control unit 4, the output of the heat ray sensor unit 1 which is a sensor signal is input. The control unit 4 receives the output of the first input determination unit 2. The control unit 4 receives the output of the signal receiving unit 3. The control unit 4 can detect the presence / absence of a human body in a preset detection area based on the sensor signal from the heat ray sensor unit 1 and can output a control signal for controlling the switch 5. The control unit 4 can be configured using, for example, a microcomputer including a CPU (Central Processing Unit).

The control unit 4 has an automatic lighting / off mode in which the lighting load 52 is automatically turned on in response to a sensor signal from the heat ray sensor unit 1 and the lighting load 52 is turned off after a predetermined lighting holding time has elapsed. Yes. The control unit 4 has a continuous lighting mode in which the illumination load 52 is continuously lit regardless of the presence or absence of a sensor signal from the heat ray sensor unit 1. The control unit 4 has a forced turn-off mode for forcibly turning off the illumination load 52 regardless of the presence or absence of a sensor signal from the heat ray sensor unit 1.

The control unit 4 switches between the continuous lighting mode, the automatic lighting off mode, and the forced lighting mode by pressing the manual operation unit 2a1. The control unit 4 is electrically connected to each light emitting diode 6a. The control unit 4 controls lighting of the plurality of light emitting diodes 6a individually corresponding to each mode. The light emitting diode 6a constitutes a mode display unit 6 capable of displaying each mode of the switch parent device 10 according to, for example, a light emission color or a lighting state. That is, the control unit 4 can display each switched mode on the mode display unit 6 provided in the manual operation unit 2a1. In the switch parent device 10 shown in FIG. 4, the continuous lighting mode is displayed as “continuous on”. In the switch parent device 10 shown in FIG. 4, the automatic light on / off mode is displayed as “automatic”. Furthermore, in the switch parent device 10 shown in FIG. 4, the forced turn-off mode is displayed as “OFF”.

The switch parent 10 switches between the continuous lighting mode, the automatic lighting on / off mode, and the forced lighting off mode every time the first operation switch 2a is operated. The mode display unit 6 displays “continuous on” in the continuous lighting mode. The mode display unit 6 displays “automatic” in the automatic on / off mode. The mode display unit 6 displays “OFF” in the forced extinction mode. The switch parent device 10 repeats the transition of each mode in the order of “OFF”, “AUTO”, and “CONTINUOUS ON” in accordance with the operation of the first operation switch 2a.

More specifically, when the switch master 10 is in the forced extinction mode, for example, among the three light emitting diodes 6a, the light emitting diode 6a provided on one side in the short direction (left side of the paper in FIG. 4) is turned on. To do. For example, the switch parent device 10 may illuminate the light-emitting diode 6a provided on one side in the short direction of the three light-emitting diodes 6a in red. In the automatic switch on / off mode, for example, the light emitting diode 6a provided in the center portion in the short direction is turned on. For example, the switch parent 10 may illuminate the light emitting diode 6a provided at the center in the short direction among the three light emitting diodes 6a in green.

The switch master 10 may blink the light emitting diode 6a provided in the center portion in green for a predetermined lighting holding time. The switch parent 10 may shorten the blinking interval of the light emitting diode 6a provided at the center as the remaining time of the predetermined lighting holding time decreases. In the case of the continuous lighting mode, for example, the light emitting diode 6a provided on the other side in the short side direction (the right side of the paper in FIG. 3) is lit. For example, the switch parent 10 may illuminate the light emitting diode 6a on the other side in the lateral direction out of the three light emitting diodes 6a in blue. That is, the light emitting diode 6a can display the continuous lighting mode, the automatic lighting off mode, and the forced lighting mode on the mode display unit 6 by distinguishing between lighting and blinking of red light emission, green light emission, and blue light emission, for example.

The switch master 10 includes a decorative cover 1d below the manual operation unit 2a1. The decorative cover 1d includes an opening window 1db at a position facing the opening 11bm of the cover body 11b. In the decorative cover 1d, the projecting portion 11bk is inserted so that the opening 11bm corresponds to the opening window portion 1db. The decorative cover 1d includes a protrusion 1dk that protrudes from one surface 2ab of the manual operation portion 2a1. The protrusion 1dk has an arc shape so as to protect the protrusion 11bk.

The switch master 10 includes a setting operation unit 7 that can set the detection sensitivity of the heat ray sensor unit 1. The setting operation unit 7 may have a function other than the function capable of setting the detection sensitivity of the heat ray sensor unit 1. The setting operation unit 7 may include an operation unit capable of setting a lighting holding time in the automatic lighting / unlighting mode. The setting operation unit 7 exposes a part of the setting operation unit 7 to the first surface 11 bp of the container 11. The setting operation unit 7 exposed on the first surface 11bp of the vessel body 11 is covered with the manual operation unit 2a1. The setting operation unit 7 includes a first setting unit 7a and a second setting unit 7b.

In the first setting unit 7a, a volume or the like constituting the first setting unit 7a is mounted on the first circuit board 16a. The first setting unit 7a includes, for example, a first knob 7a1 so that the operation shaft of the volume can be rotated. The first setting portion 7 a projects the first knob 7 a 1 of the first setting portion 7 a toward the first surface 11 bp side of the container body 11 through the third window hole 11 bh of the container body 11. The first setting unit 7a is configured to be able to set a lighting holding time during which the lighting load 52 is lit in the automatic lighting / unlighting mode. The switch parent device 10 can appropriately set the lighting holding time in a range from 30 seconds to 30 minutes, for example.

As for the 2nd setting part 7b, the rotary volume etc. which comprise the 2nd setting part 7b are mounted in the 1st circuit board 16a. The second setting unit 7b includes, for example, a second knob 7b1 so that the operation shaft of the rotary volume can be rotated. The second setting portion 7 b protrudes the second knob 7 b 1 of the second setting portion 7 b toward the first surface 11 bp side of the vessel body 11 through the fourth window hole 11 bi of the vessel body 11. For example, the second setting unit 7b can set the brightness sensitivity level of the brightness sensor 1s in a range from “dark” to “bright”. The “darkness” of the brightness sensitivity level can be set to 5 lux or less, for example. The “brightness” of the brightness sensitivity level can be set to, for example, 100 lux or more.

For example, when the second setting unit 7b is set to “OFF”, the switch master unit 10 can stop the function of the brightness sensor 1s. When the second setting unit 7b is set to “OFF”, the switch parent 10 can prevent the lighting load 52 in the house from being turned on when the surroundings of the switch parent 10 are bright. The switch parent 10 can prevent the lighting load 52 in the house from being turned on when the surroundings are bright, and can save energy.

For example, by adjusting the brightness threshold value in the second setting unit 7b, the switch parent unit 10 is set with a detection sensitivity at which the heat ray sensor unit 1 detects the presence or absence of a person. The same effect can be obtained. That is, in the switch parent device 10, the second setting unit 7 b configures the setting operation unit 7 that sets the detection sensitivity of the heat ray sensor unit 1. Note that the switch parent 10 may include a setting operation unit 7 that directly adjusts and sets the detection sensitivity of the heat ray sensor unit 1. For example, the switch master 10 directly adjusts the detection sensitivity of the heat ray sensor unit 1 by adjusting the amplification degree when the change amount of the heat ray detected by the heat ray sensor unit 1 is amplified based on the setting operation unit 7. Can be adjusted.

In the system 30, the operating unit 20 shown in FIG. 15 is attached to the mounting frame 17 and installed on a construction surface (not shown) such as a wall surface of a building. The operating unit 20 includes a box 21 that is embedded in a construction material that constitutes a construction surface. The operation child device 20 can be configured to include, for example, a box 21 that can house the second input determination unit 22, the signal transmission unit 23, and the child device control unit 24 therein. The box body 21 has the same structure as the mounting claws 11bd of the body 11 of the switch master 10, and can be configured to be attached to the mounting frame 17. The operation child device 20 includes a cover portion 22 g that covers the front surface of the box body 21. The cover 22g can be used as a piano handle of the second operation switch 22a constituting a piano handle type switch.

Next, the operation of the switch parent 10 in the system 30 will be described in detail with reference to FIG.

When the switch main unit 10 is in the automatic on / off mode, when the transmission signal from the operation unit 20 is input to the control unit 4 at time t1 via the signal receiving unit 3, the control unit 4 causes the switch 5 to switch. The lighting load 52 is turned on by controlling. In the switch master 10, the control unit 4 gradually decreases the counter value of the timer unit until a predetermined time elapses after receiving the transmission signal from the operating unit 20. In the switch parent device 10, after the time t <b> 2 when the counter value of the timer unit becomes “0”, the control unit 4 controls the switch 5 to turn off the illumination load 52. In other words, the switch parent device 10 lights the illumination load 52 until the lighting holding time from the preset time t1 to time t2 elapses. Hereinafter, the lighting holding time from time t1 to time t2 is also referred to as a first lighting holding time.

In addition, although not shown in figure, in the automatic lighting / extinguishing mode, the switch master 10 has passed a preset first lighting holding time based on the sensor signal from the heat ray sensor unit 1 as in the case of the transmission signal. The lighting load 52 can also be turned on until it is done.

Next, in the switch master unit 10, in the automatic lighting / off mode, when the transmission signal from the operation unit 20 is input to the control unit 4 at the time t <b> 3 through the signal receiving unit 3, similarly to the time t <b> 1. The control unit 4 controls the switch 5 to turn on the illumination load 52. When the switch parent device 10 is in the automatic light on / off mode, when the heat ray sensor unit 1 detects a change in the heat ray at time t4, the heat ray sensor unit 1 outputs a sensor signal. When the sensor signal is input from the heat ray sensor unit 1 during the lighting holding time, the switch master 10 is connected to the lighting load until a preset lighting holding time from time t4 to time t6 when the sensor signal is input elapses. 52 is turned on. Hereinafter, the lighting holding time from time t4 to time t6 is also referred to as a second lighting holding time.

The switch parent 10 controls the switch 5 after the second lighting holding time to turn on the lighting load 52. In FIG. 2, based on the input of the sensor signal, the control unit 4 sets a second lighting holding time for turning on the lighting load 52 from time t4 to time t6. In the switch parent device 10, the first lighting holding time and the second lighting holding time are set to the same time interval. However, the first lighting holding time and the second lighting holding time may be set to different time intervals. The switch parent 10 resets the lighting holding time with the sensor signal as a trigger.

The switch parent 10 receives a time t6 after a time t5 when the value of the counter of the timer unit becomes “0” from a time t3 when the control unit 4 turns on the lighting load 52 by a transmission signal from the operation unit 20. Thus, the control unit 4 controls the switch 5 to turn off the illumination load 52. That is, it can be said that the switch parent device 10 extends the lighting holding time from the time t3 to the time t5 from the time t3 to the time t6.

In addition, although not shown in figure, in the automatic lighting / extinguishing mode, the switch parent device 10 has passed a preset second lighting holding time based on the sensor signal from the heat ray sensor unit 1 as in the case of the transmission signal. The lighting load 52 can also be turned on until it is done.

In the system 30, in the automatic light on / off mode, the operation load 20 provided outside the detection area of the heat ray sensor unit 1 is used to set the illumination load 52 regardless of whether or not the heat ray sensor unit 1 is detected by the switch parent 10. It is possible to maintain lighting during the lighting holding time. Further, the system 30 keeps the lighting load 52 lit during the lighting holding time which is set again by detecting a person in the detection area of the heat ray sensor unit 1 while the lighting load 52 is lit by the operation unit 20. Is possible.

In the system 30, the illumination load 52 can be turned on even if there is no person in the detection area of the heat ray sensor unit 1 in the switch parent unit 10. Therefore, for example, when the switch parent device 10 is installed at the entrance, the system 30 turns on the lighting load 52 by the operation device 20 and suppresses that the corridor on the way to the entrance remains dark. It becomes possible to do. In the system 30, even when the switch parent device 10 is installed near the entrance, the lighting load 52 can be turned on by the operation device 20 provided at the other end of the hallway. Further, in the system 30, the lighting load 52 is in a lighting state even if a telephone call or the like leaves the switch parent unit 10 after the operation unit 20 is operated and the lighting load 52 is turned on so that a person goes out. It will not remain. Therefore, the system 30 can further save energy.

In the system 30, for example, a person away from the switch parent device 10 operates the operation child device 20 to supply and stop power to the lighting load 52. In the switch parent device 10, the internal signal receiving unit 3 receives a transmission signal from the operation unit 20, and the control unit 4 supplies and stops power to the illumination load 52 based on the transmission signal from the operation unit 20. And switch. For example, when power is supplied to the lighting load 52 in the automatic lighting / off mode, the switch master 10 can continue to supply power to the lighting load 52 by a sensor signal from the heat ray sensor unit 1. When the control unit 4 keeps the lighting load 52 in a lighting state for a predetermined lighting holding time by a transmission signal from the operation unit 20, a predetermined lighting holding time is input by inputting a sensor signal from the heat ray sensor unit 1. Again. The control unit 4 can turn off the illumination load 52 after a predetermined lighting time has elapsed from the input of the sensor signal from the heat ray sensor unit 1.

The switch master 10 may be configured to include a second switch for turning on / off the supply of power to a load device such as a ventilation fan in addition to the switch 5 for turning on / off the supply of power to the lighting load 52. . Thereby, the switch parent 10 can also control a load device separate from the illumination load 52.

(Embodiment 2)
The automatic switch system with human sensor 30 of the present embodiment shown in FIG. 16 has the same configuration as that of the first embodiment of FIG. 1, and is mainly different in that a sensor slave unit 40 is provided in addition to the operation slave unit 20. To do. In addition, about the component similar to Embodiment 1, description is abbreviate | omitted suitably using the same code | symbol.

The system 30 further includes a sensor slave unit 40 as shown in FIG. The sensor slave unit 40 includes a second hot wire sensor unit 45 and a detection signal transmission unit 43. The 2nd heat ray sensor part 45 detects the presence or absence of a human body. The detection signal transmission unit 43 transmits a detection signal to the switch parent device 10 based on the second sensor signal from the second heat ray sensor unit 45.

The control unit 4 controls the switch 5 so that the illumination load 52 is turned on in accordance with the detection signal from the sensor slave unit 40 and is turned off after a predetermined lighting holding time has elapsed. When the sensor signal or the detection signal is input during the lighting holding time, the control unit 4 controls the switch 5 so as to be turned off after a predetermined lighting holding time after the sensor signal or the detection signal is input. .

As a result, the system 30 can be made more usable.

More specifically, the system 30 electrically connects the operation unit 20 and the sensor unit 40 to the switch base unit 10. The sensor slave unit 40 includes a second heat ray sensor unit 45, a signal control unit 44, and a detection signal transmission unit 43. The signal control unit 44 controls the detection signal transmission unit 43 based on the second sensor signal from the second heat ray sensor unit 45. The detection signal transmission unit 43 transmits a detection signal to the switch parent device 10 under the control of the signal control unit 44. The sensor slave unit 40 may transmit the detection signal to the switch parent unit 10 by wire or may transmit the detection signal to the switch parent unit 10 wirelessly.

In the system 30, it is preferable to provide the sensor slave unit 40 at a position outside the detection area in the heat ray sensor unit 1 of the switch master unit 10. When the sensor slave unit 40 detects a person in the detection area of the second heat ray sensor unit 45, the signal control unit 44 controls the detection signal transmission unit 43 to output a detection signal. In the switch parent device 10, the signal receiving unit 3 receives the detection signal from the sensor slave unit 40, and the control unit 4 electrically connected to the signal receiving unit 3 is based on the detection signal from the sensor slave unit 40. 52 is in a lighting state.

For example, when the supply of power to the illumination load 52 is stopped in the automatic lighting / extinguishing mode, the switch parent device 10 can supply the illumination load 52 with the detection signal from the sensor slave unit 40. That is, the control unit 4 of the switch parent 10 turns on the illumination load 52 by the detection signal from the sensor slave 40 in the automatic light on / off mode. The controller 4 is turned off after a predetermined lighting holding time has elapsed since the illumination load 52 was turned on by the detection signal from the sensor slave unit 40.

In addition, when the control unit 4 keeps the illumination load 52 in the lighting state for a predetermined lighting holding time by the detection signal from the sensor slave unit 40, the predetermined lighting is performed by the input of the sensor signal from the heat ray sensor unit 1. Re-measure the holding time again. The control unit 4 can turn off the illumination load 52 after a predetermined lighting time has elapsed from the input of the sensor signal from the heat ray sensor unit 1. Note that the switch master 10 is configured such that the signal receiver 3 can discriminate between a transmission signal from the operation slave 20 and a detection signal from the sensor slave 40 based on a difference in signal voltage.

In the system 30, the sensor slave unit 40 shown in FIG. 17 is attached to the mounting frame 17 and installed on a construction surface (not shown) such as a wall surface of a building. The sensor slave unit 40 includes a box portion 46 that is embedded in a construction material constituting the construction surface.

The sensor slave unit 40 can be configured to include, for example, a box unit 46 that can house the second heat ray sensor unit 45, the detection signal transmission unit 43, and the signal control unit 44 therein. The box portion 46 has a structure similar to that of the attachment claw 11 bd of the body 11 of the switch master 10 and can be configured to be attached to the attachment frame 17. The sensor slave unit 40 includes a first covering portion 47 a that covers the front surface of the box portion 46. In the sensor slave unit 40, the second heat ray sensor unit 45 has the same configuration as the heat ray sensor unit 1 of the switch parent unit 10. The second heat ray sensor unit 45 includes a shielding plate 45 b corresponding to the shutter 1 b of the heat ray sensor unit 1. In the sensor slave unit 40, the size of the box portion 46 is set to the size of a single module corresponding to two of one module of the embedded wiring device. Therefore, on the upper side of the sensor sub-unit 40, a second covering portion 47b that closes the first window hole 17aa in a state where the sensor sub-unit 40 is attached to the attachment frame 17 is provided. Note that the system 30 may appropriately use the components of the first embodiment.

DESCRIPTION OF SYMBOLS 1 Heat ray sensor part 2 1st input discrimination | determination part 2a 1st operation switch 3 Signal receiving part 4 Control part 5 Switch 10 Automatic switch with a human sensor 20 Operation child device 22 2nd input discrimination | determination part 22a 2nd operation switch 23 Signal transmission Section 30 Automatic switch system with human sensor 40 Sensor slave unit 43 Detection signal transmission section 45 Second hot wire sensor section 52 Illumination load

Claims (2)

1. An automatic switch system with a human sensor having an automatic switch with a human sensor and a control unit,
   The human sensor-equipped automatic switch is a human sensor unit capable of detecting the presence or absence of a human body,
   A first input determining unit for determining whether or not the first operation switch operated manually is operated;
   A signal receiving unit for receiving a transmission signal from the operating unit;
   Control for outputting a control signal for controlling lighting on / off of the lighting load based on the sensor signal from the human sensor unit, the determination signal from the first input determination unit, and the transmission signal received by the signal reception unit And
   A switch for turning on and off the supply of power to the lighting load based on the control signal from the control unit,
   The operation unit is
   A second input determining unit for determining whether or not the second operation switch operated manually is operated;
   A signal transmission unit that transmits the transmission signal to the human sensor-equipped automatic switch based on an operation signal from the second input determination unit;
   The controller is
   The switch is controlled to turn on the lighting load in accordance with the transmission signal from the operation unit and to turn off the light after a predetermined lighting holding time, and during the lighting holding time, When the sensor signal from the human sensor unit is input, the switch is controlled so that the switch is turned off after a predetermined lighting holding time after the sensor signal is input. Automatic switch system.
2. It further comprises a sensor slave unit,
   The sensor unit is
   A second human sensor for detecting the presence or absence of a human body;
   A detection signal transmission unit that transmits a detection signal to the automatic switch with human sensor based on the second sensor signal from the second human sensor unit,
   The control unit controls the switch so that the lighting load is turned on according to the detection signal from the sensor slave unit, and is turned off after a predetermined lighting holding time has elapsed, and the lighting holding is performed. When the sensor signal or the detection signal is input during the time, the switch is controlled so that the switch is turned off after a predetermined lighting holding time after the sensor signal or the detection signal is input. The automatic switch system with a human sensor according to claim 1.

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