JP5971583B2 - Load controller - Google Patents

Description

  The present invention relates to a load controller.

  Conventionally, there has been a switch in which a lighting switch capable of dimming control is switched on / off, and a dimmer for controlling the dimming level of the lighting load arranged in a series of mounting frames (for example, a patent) Reference 1). In this device, a switching operation is performed using a changeover switch, and a dimming level switching operation is performed using a dimmer.

JP 2009-301811 A

  In the dimmer and the changeover switch described in Patent Document 1, the operation unit operated to switch the lighting load on / off and the operation unit operated to switch the dimming level are different. It was provided at the place. That is, since the operation units for performing different load control are provided in different places, the number of operation units is increased, and there is a problem that the apparatus for controlling the load is enlarged as a whole. .

  The present invention has been made in view of the above problems, and an object thereof is to provide a load controller that is reduced in size by reducing the number of operation units.

The load controller according to one aspect of the present invention includes a first detection unit that detects a push operation of the operation unit, a second detection unit that detects a tap operation of the operation unit, and the first detection unit detects a push operation. A load control unit that performs load control different from the case where the second detection unit detects a tap operation, and a third detection unit that detects acceleration applied to the operation unit. An area where the first detection unit detects a push operation and an area where the second detection unit detects a tap operation overlap at least partially, and when the second detection unit detects an operation of the operation unit, The load control unit discriminates whether the operation detected by the second detection unit is a tap operation or a push operation based on the detection result of the third detection unit. The tap operation means an operation of tapping the operation unit with a finger, and the push operation means an operation of pushing the operation unit for a predetermined stroke or more.

The load controller according to one aspect of the present invention includes a first detection unit that detects a push operation of the operation unit, a second detection unit that detects a tap operation of the operation unit, and the first detection unit detects a push operation. And a load control unit that performs load control different from each other when the second detection unit detects a tap operation, the operation unit is rotatably supported, and the first detection unit is a push operation The second detection unit is a part different from a part that is pushed by the operation part, and is a center of rotation in the operation part. The tap operation is detected at the site.

  In this load controller, the load of the load control unit is a lighting fixture capable of dimming control. When the first detection unit detects a push operation, the load control unit switches on / off the load, and when the second detection unit detects a tap operation, the load control unit sets the load to a predetermined value. It is also preferable to light at a dimming level.

  In the load controller, when the second detection unit detects a long press operation for a predetermined time or longer, the load control unit sweeps the dimming level of the load, and the dimming level at the time when the long press operation is finished. It is also preferable to light up the load.

  According to the present invention, since the load control unit performs different load control depending on whether the operation unit is pushed or tapped, the operation unit for performing different load control is provided separately. Compared to the case, the number of operation units can be reduced, and the load controller can be downsized.

FIG. 3 is an exploded perspective view of the load controller according to the first embodiment. It is an exploded perspective view same as the above. It is a front view same as the above. It is sectional drawing same as the above. It is a block diagram same as the above. It is an operation | movement sequence diagram same as the above. (A) is a front view of the touch substrate with which the load controller of Embodiment 2 is provided, (b) is a side sectional view with a part omitted. It is a front view same as the above. It is a block diagram same as the above. It is an operation | movement sequence diagram same as the above. (A) is a front view of the touch substrate with which the load controller of Embodiment 3 is provided, (b) is a side sectional view in which a part is omitted. It is a front view same as the above. It is an operation | movement sequence diagram same as the above.

  Hereinafter, an embodiment in which a load controller according to the present invention is applied to control of a lighting fixture capable of dimming control will be described with reference to the drawings.

(Embodiment 1)
The load controller 1 of Embodiment 1 is demonstrated with reference to FIGS. In the following description, unless otherwise specified, the vertical and horizontal directions are defined in the direction shown in FIG. 3, and the upper side in FIG. 4 is described as the front side, and the lower side in FIG.

  FIG. 5 is a block diagram of the load controller 1 according to the first embodiment. The load controller 1 is used to control the operation of the LED lighting apparatus 100 capable of dimming control. The load controller 1 includes a signal processing unit 10, a tact switch 11, a touch sensor 12, an acceleration sensor 13, an output circuit 14, a light emitting diode (LED) 15, a piezoelectric buzzer 16, and drive circuits 17 and 18. And a power supply circuit 19.

  As shown in FIGS. 1 and 4, the tact switch 11 is mounted at a substantially center of a rectangular main board 22 (for example, made of a printed wiring board) disposed on the back side of the operation unit 20. When the operator pushes the operation unit 20, the push button 11a of the tact switch 11 is pushed on the back surface of the operation unit 20, and the built-in contact is switched on / off. Thereafter, when the operation unit 20 is not pushed by the operator, the push button 11a receives the spring force and returns to the original position, whereby the operation unit 20 returns to the initial position. Here, the push operation means an operation of pushing the operation unit 20 over a predetermined stroke, and the tact switch 11 constitutes a first detection unit.

  The touch sensor 12 is composed of a capacitance type sensor. In the present embodiment, a plurality of (for example, six) touch sensors 12 are mounted on the surface of the touch substrate 21 as shown in FIG. The touch substrate 21 is made of a synthetic resin molded product having a rectangular plate shape having substantially the same vertical and horizontal lengths, and is disposed on the back side of the operation unit 20 so as to be parallel to the surface of the operation unit 20. Three touch sensors 12 are attached to the upper and lower portions of the surface of the touch substrate 21 side by side in the left-right direction. Since the operation unit 20 is made of synthetic resin, when the operation unit 20 is touched with a finger to perform a tap operation, the capacitance value of the touch sensor 12 on the back side of the part touched by the finger changes. Here, the tap operation means an operation of tapping the operation unit 20 with a finger, and the touch sensor 12 constitutes a second detection unit.

  The acceleration sensor 13 is mounted on the touch substrate 21 and detects acceleration applied to the operation unit 20 at least in the front-rear direction (that is, the vertical direction in FIG. 1B). Here, the acceleration sensor 13 constitutes a third detection unit. The detection signals of the touch sensor 12 and the acceleration sensor 13 mounted on the touch substrate 21 are input to a circuit mounted on the main substrate 22 described later via a harness (not shown).

  The signal processing unit 10 performs overall control of the load controller 1. When a tap operation or a push operation of the operation unit 20 is detected based on inputs from the tact switch 11, the touch sensor 12, and the acceleration sensor 13, a tap is performed. Different load control is performed according to the operation or push operation.

  The output circuit 14 changes the voltage level of the output signal S1 in accordance with a control command from the signal processing unit 10. The output signal S1 of the output circuit 14 is input to the LED lighting device 100, and the LED lighting device 100 controls the dimming level of a light emitting diode (not shown) as a light source according to the voltage level of the output signal S1.

  The light emitting diodes 15 are made of, for example, RGB full color light emitting diodes, and a plurality of (for example, five) light emitting diodes 15 are mounted on the main substrate 22. The five light emitting diodes 15 are arranged on the left and right sides of the tact switch 11 at a substantially constant interval, and are located approximately in the middle of the touch sensors 12 arranged in two rows. As shown in FIG. 4, the main board 22 is provided with a light shielding wall 23 surrounding each light emitting diode 15. Light emitted from each light-emitting diode 15 is incident on a through-hole 21a provided at the front, and the light-shielding wall 23 enters the through-hole 21a other than the corresponding through-hole 21a. Light leakage is reduced so that it does not enter.

  The drive circuit 17 controls turning on / off of each light emitting diode 15 in accordance with an input signal from the signal processing unit 10 and controls the light emission color of the light emitting diode 15 formed of a full color LED.

  Further, the drive circuit 18 sounds the piezoelectric buzzer 16 according to the input signal from the signal processing unit 10.

  The power supply circuit 19 includes an AC / DC converter 19a and a constant voltage unit 19b. The AC / DC converter 19a converts AC power supplied from a commercial AC power source into DC. The constant voltage unit 19b is composed of, for example, an LDO (Low DropOut) regulator, and steps down the output voltage of the AC / DC conversion unit 19a to a predetermined voltage and supplies it to the signal processing unit 10.

  Next, the mechanical configuration of the load controller 1 will be described with reference to FIGS. 1 and 2 are exploded perspective views of the load controller 1, and FIG. 3 is a front view of the load controller 1, respectively. In the present embodiment, two load controllers 1 are attached to the plate member 30. The plate member 30 is made of a synthetic resin molded product, and integrally includes a main portion 30a formed in a vertically long rectangular plate shape, and a side portion 30b protruding rearward from a slightly inner side of the peripheral portion of the main portion 30a. In the center of the front surface of the main portion 30a, two rectangular openings 30c penetrating the main portion 30a in the front-rear direction are provided side by side.

  Two main boards 22 are fixed to the back side of the main part 30a by a method such as screwing. Each main board 22 is attached to a position facing the upper or lower opening 30c. A circuit excluding the touch sensor 12 and the acceleration sensor 13 among the circuits shown in FIG. 5 is mounted on the main board 22. A tact switch 11 is mounted substantially at the center of the main substrate 22, and five light emitting diodes 15 are mounted in a line at regular intervals on the left and right sides of the tact switch 11.

  On the front surface of the main part 30a, two operation parts 20 are mounted side by side so as to be arranged on the front side of the opening part 30c.

  The operation unit 20 is formed of a translucent synthetic resin, and has a main part 20a having a square shape in plan view and a front surface serving as an operation surface, and a side wall 20b protruding rearward from the peripheral part of the main part 20a. Is integrated. The operation unit 20 is provided with a rectangular plate-shaped mounting piece 20c that protrudes toward the left side from the rear part of the left side wall 20b. On the front surface of the plate member 30, a groove 30d extending in the vertical direction is formed on the left side of each opening 30c. The mounting piece 20c is overlapped on the front side of the groove 30d, and the mounting piece 20c is grooved 30d using a screw or the like. The operation unit 20 is cantilevered by the plate member 30. Further, on the back surface of the main portion 20a, a protrusion 20d protruding rearward is provided at a portion facing the push button 11a of the tact switch 11 mounted on the main board 22. The operation unit 20 is integrally provided with a retaining projection 20e that protrudes to the right from the rear of the right side wall 20b. Then, as shown in FIG. 4, the projection 20 e comes into contact with the peripheral portion of the hole 31 a of the plate frame 31 described later, so that the front surface of the operation unit 20 does not protrude forward from the front surface of the plate frame 31. The forward movement of the operation unit 20 is restricted.

  A touch substrate 21 is attached to a region surrounded by the main portion 20a and the side wall 20b. The touch substrate 21 is formed in a rectangular plate shape as shown in FIGS. 1 and 2, and three touch sensors 12 are mounted on each of the upper side portion and the lower side portion of the touch substrate 21. In the touch substrate 21, through holes 21 a for allowing light emitted from the light emitting diodes 15 to pass forward are formed in portions corresponding to the light emitting diodes 15 mounted on the main substrate 22. The light emission of each light emitting diode 15 is irradiated forward through the through hole 21a, passes through the operation unit 20 formed of a translucent material, and is irradiated to the outside from the front surface of the main portion 20a. Further, the touch substrate 21 is formed with an elongated through hole 21b through which the protrusion 20d is inserted at a portion facing the protrusion 20d of the operation unit 20. In a state where the touch substrate 21 is attached to the back side of the main portion 20a, the protrusion 20d protrudes rearward from the through hole 21b, and when the operation portion 20 is pushed, the protruding portion of the protrusion 20d causes the tact switch 11 to The push button 11a is pushed.

  A square frame-like plate frame 31 is attached to the front side of the plate member 30. The plate frame 31 is attached to the front surface of the plate member 30 by, for example, hooking a claw (not shown) provided on the back surface into a groove (not shown) of the plate member 30. A vertically long hole 31a is opened at the center of the plate frame 31, and the main portion 20a of each operation portion 20 attached to the plate member 30 is exposed forward from the hole 31a.

  The configuration of each part is as described above, and the main board 22 is attached to the back side of the plate member 30 by a method such as screwing so that the front surface is exposed from the opening 30c. On the front side of the plate member 30, the operating portion 20 is cantilevered by fixing the mounting piece 20c to the groove 30d. The main portion 20a of the operation unit 20 is disposed so as to cover the opening 30c, and the touch substrate 21 attached to the back side of the main portion 20a is disposed on the front side of the main substrate 22. In the assembled state, as shown in FIG. 4, the protrusion 20 d provided on the back surface of the main portion 20 a faces the push button 11 a of the tact switch 11. Since the operation portion 20 is cantilevered by the plate member 30 via the attachment piece 20c, when the main portion 20a is pushed, the main portion 20a rotates around the attachment piece 20c, and the push button 11a is rotated by the protrusion 20d. Will be pushed. Thereafter, when the main portion 20a is no longer pressed, the push button 11a is returned to the initial position by the return force of the spring provided in the tact switch 11, so that the operation portion 20 is returned to the initial position by pressing the protrusion 20d on the push button 11a. Will do. The through hole 21a of the touch substrate 21 is located in front of the light emitting diode 15 mounted on the main substrate 22, and the light emitted from the light emitting diode 15 is incident on the main portion 20a through the through hole 21a and is transmitted through the main portion 20a. Then, the light is irradiated to the outside from the front surface of the main portion 20a.

  Here, the signal processing unit 10 performs different load control when the tap operation is performed and when the push operation is performed. The determination of the tap operation and the push operation is performed by the following method. ing.

  When the push operation of the main part 20a is performed by the operator, the operation part 20 is pushed more than a predetermined stroke, so that the tact switch 11 is pushed by the projection 20d on the back side of the main part 20a, thereby causing the tact switch 11 is switched on, for example. Thereafter, when the operation unit 20 is no longer pressed, the push button 11a of the tact switch 11 receives the restoring force of the built-in spring and returns to the initial position, and the tact switch 11 is switched off, for example. Thus, since the tact switch 11 is turned on only while the main part 20a is pushed in, the signal processing unit 10 determines whether or not a push operation has been performed based on the on / off state of the tact switch 11. Can be detected.

  Further, when the operator performs a tap operation on the operation unit 20, the capacitance value of the touch sensor 12 arranged on the back side of the operation unit 20 changes. A plurality of touch sensors 12 are connected to the signal processing unit 10, and each touch sensor 12 is supported by comparing the level of the capacitance of each touch sensor 12 with a predetermined reference value. It can be determined whether or not a finger (human body) is touching a portion of the main part 20a to be performed.

  Here, since the area where the tap operation is performed in the main part 20a and the area where the push operation is performed overlap, even when the operation part 20 is pushed, the operator's finger touches the surface of the operation part 20, The capacitance value of the touch sensor 12 changes. Accordingly, since the tap operation and the push operation cannot be discriminated only by the output of the touch sensor 12, in this embodiment, the signal processing unit 10 performs the tap operation and the push operation based on the output of the touch sensor 12 and the output of the acceleration sensor 13. The operation is discriminated and detected.

  That is, when the operation unit 20 is tapped, the peak value of the acceleration detected by the acceleration sensor 13 is lower and the time for detecting the acceleration is shorter than when the operation unit 20 is pushed. In the signal processing unit 10, a threshold value of acceleration used for discriminating between the tap operation and the push operation is set in advance, and when the capacitance value of any touch sensor 12 exceeds a predetermined reference value, The acceleration detected by the acceleration sensor 13 is compared with a predetermined threshold value. Here, if the detected acceleration is equal to or greater than the threshold value, the signal processing unit 10 determines that the operation is a push operation, does not perform load control in the case of a tap operation, and pushes when the tact switch 11 is switched on / off. Perform load control according to the operation. On the other hand, if the detected acceleration is less than the threshold value, the signal processing unit 10 performs a tap operation when a predetermined determination time (a predetermined time shorter than the time required to push the operation unit 20) elapses. The load is controlled according to the tap operation. In the case of a tap operation, the operation unit 20 is not pushed in for a predetermined stroke or more, so that the tact switch 11 is not turned on.

  Here, the tact switch 11 forms a first detection unit that detects a push operation of the operation unit 20, and the touch sensor 12 forms a second detection unit that detects a tap operation of the operation unit 20. In the present embodiment, two sets of load controllers 1 are attached to the plate member 30, and the operation unit 20, the touch substrate 21, and the main substrate 22 constitute one set of load controllers 1.

  Next, the operation of this embodiment will be described. When the signal processing unit 10 detects the tap operation or push operation as described above, it performs load control according to the tap operation or push operation, and the operation sequence is shown in FIG.

  In the operation sequence of FIG. 6, when the push operation of the operation unit 20 is detected, the signal processing unit 10 alternately switches the operation state of the LED lighting apparatus 100 between the fully lit state and the unlit state. Moreover, if the tap operation of the operation part 20 is detected, the signal processing part 10 will switch the operation state of the LED lighting fixture 100 alternately with the light control state and light extinction state which light at a predetermined light control level.

  First, in a state where the LED lighting apparatus 100 is turned off (ST1 in FIG. 6), the signal processing unit 10 controls the drive circuit 17 to turn on each light emitting diode 15 in green and perform position display.

  Further, when the LED lighting apparatus 100 is lit at a predetermined dimming level (for example, 15% dimming level when the entire lighting state is set to 100% dimming level) (ST2 in FIG. 6), the signal The processing unit 10 controls the drive circuit 17 to light up each light-emitting diode 15 with a light bulb color, thereby notifying that it is being lit in a dimming lighting state.

  When the operator performs a push operation with the LED lighting device 100 turned off or dimmed (P1 and P2 in FIG. 6), the signal processing unit 10 includes the tact switch 11, the touch sensor 12, and the acceleration sensor 13. A push operation is detected based on the input signal. When the signal processing unit 10 detects the push operations P1 and P2, the signal processing unit 10 causes the output circuit 14 to output a full lighting signal to the LED lighting fixture 100, and turns on the LED lighting fixture 100 in a full lighting state. Further, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, “pi”) from the piezoelectric buzzer 16 and controls the drive circuit 17 to light each light emitting diode 15 in red. To notify that it has been switched to the fully lit state.

  When the operator performs a push operation (P3 in FIG. 6) while the LED lighting apparatus 100 is fully lit (ST3 in FIG. 6), the signal processing unit 10 includes the tact switch 11, the touch sensor 12, and the acceleration sensor 13. The push operation is detected based on the input signal. When the signal processing unit 10 detects the push operation P3, the signal processing unit 10 outputs a turn-off signal from the output circuit 14 to the LED lighting device 100, and turns off the LED lighting device 100. In addition, the signal processing unit 10 controls the drive circuit 18 to generate a notification sound (for example, a sound of “Peep”) from the piezoelectric buzzer 16 to notify that it has been switched to the off state. Further, the signal processing unit 10 controls the drive circuit 17 to light up each light emitting diode 15 in green, notifying that the light emitting diode 15 has been switched off, and performing position display.

  When the operator performs a tap operation with the LED lighting apparatus 100 turned off or fully lit (P4 and P5 in FIG. 6), the signal processing unit 10 is based on the inputs of the touch sensor 12 and the acceleration sensor 13. Detect tap operation. When the signal processing unit 10 detects the tap operations P4 and P5, the signal processing unit 10 outputs a dimming signal from the output circuit 14 to the LED lighting fixture 100, and the LED lighting fixture 100 is set at a predetermined dimming level (for example, a dimming level of 15%). Turn on the dimmer. Further, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, a sound of “pi”) from the piezoelectric buzzer 16 and also controls the drive circuit 17 to turn on each light emitting diode 15 with a light bulb color. To notify that it has switched to the dimming lighting state.

  In addition, when the operator performs a tap operation (P6 in FIG. 6) in a state where the LED lighting apparatus 100 is dimmed (ST2 in FIG. 6), the signal processing unit 10 includes the touch sensor 12 and the acceleration sensor 13. Detect tap operation based on input. When detecting the tap operation P <b> 6, the signal processing unit 10 outputs a turn-off signal from the output circuit 14 to the LED lighting device 100 to turn off the LED lighting device 100. In addition, the signal processing unit 10 controls the drive circuit 18 to generate a notification sound (for example, a sound of “Peep”) from the piezoelectric buzzer 16 to notify that it has been switched to the off state. Further, the signal processing unit 10 controls the drive circuit 17 to light up each light emitting diode 15 in green, notifying that the light emitting diode 15 has been switched off, and performing position display.

  As described above, the load controller 1 of the present embodiment includes the first detection unit (consisting of the tact switch 11), the second detection unit (consisting of the touch sensor 12), and the load control unit (consisting of the signal processing unit 10). ). The first detection unit detects a push operation of the operation unit 20 by the operator. The second detection unit detects a tap operation of the operation unit 20 by the operator. The load control unit performs different load control when the first detection unit detects a push operation and when the second detection unit detects a tap operation.

  Thereby, since different load control can be realized depending on whether the same operation unit 20 is tapped or pushed, the operation unit is different from the case where operation units for performing different load control are provided separately. The number of 20 can be reduced. Therefore, the load controller 1 can be miniaturized and the design can be improved. In this embodiment, different load control is performed by controlling the same load to different control states, but load control of different loads may be performed by a tap operation or a flick operation.

  In the present embodiment, at least a part of the operation unit 20 includes a region where the first detection unit (tact switch 11) detects the push operation and a region where the second detection unit (touch sensor 12) detects the tap operation. overlapping. Therefore, an acceleration sensor 13 that detects an acceleration sensor applied to the operation unit 20 is provided as a third detection unit. When the second detection unit detects an operation of the operation unit 20, the load control unit (signal processing unit 10) Based on the detection result of the detection unit, it is discriminated whether the operation detected by the second detection unit is a tap operation or a push operation.

  As a result, touching the operation unit 20 to perform a push operation is less likely to be erroneously detected as a tap operation.

(Embodiment 2)
The load controller 1 of Embodiment 2 is demonstrated with reference to FIGS. In addition, the same code | symbol is attached | subjected to the component which is common in Embodiment 1, and the description is abbreviate | omitted.

  In the first embodiment, since the area where the push operation is performed and the area where the tap operation is performed overlap in the operation unit 20, the acceleration sensor 13 is necessary to discriminate the push operation from the tap operation. In the present embodiment, the push operation area and the tap operation area in the operation unit 20 are separate areas, and the acceleration sensor 13 is not required.

  In the first embodiment, one end side of the operation unit 20 is cantilevered and the other end side of the operation unit 20 is pushed. Therefore, only one tact switch 11 is provided. On the other hand, in the present embodiment, the operation unit 20 is rotatably supported at the intermediate portion in the left-right direction, and the right side and the left side of the operation unit 20 can be pushed, so the push on the right side Two tact switches 11 are provided to detect the operation and the push operation on the left side.

  FIG. 9 is a block diagram of the present embodiment, which is the same as the circuit described in the first embodiment except that the acceleration sensor 13 is not provided and two tact switches 11 are connected. Common constituent elements are denoted by the same reference numerals, and description thereof is omitted.

  Next, the mechanical configuration of the load controller 1 will be described with reference to FIGS.

  The operation unit 20 is formed of a translucent synthetic resin, and has a main part 20a having a square shape in plan view and a front surface serving as an operation surface, and a side wall 20b protruding rearward from the peripheral part of the main part 20a. Is integrated. The operation unit 20 is attached to the plate member 30 so as to be rotatable about an intermediate portion in the left-right direction.

  The main substrate 22 is attached to the plate member 30 on the back side of the main portion 20a so as to be parallel to the front surface of the main portion 20a in the neutral position. One RGB full-color light emitting diode 15 is mounted at the center position of the main board 22. Further, tact switches 11 are mounted on the main board 22 at both end positions in the left-right direction. On the back side of the main portion 20a, protrusions 24 are provided at portions facing the push buttons 11a of the tact switches 11, and the protrusions 20d are inserted into through holes (not shown) of the touch substrate 21, and the touch substrate 21 protrudes rearward from the rear surface.

  As shown in FIGS. 7A and 7B, the touch substrate 21 is formed in a rectangular plate shape with a synthetic resin, and a plurality of (for example, four) touch sensors 12 are vertically arranged in the middle portion in the left-right direction. Implemented side by side. That is, the touch sensor 12 is mounted in a region excluding regions (right end portion and left end portion) that are pushed in the main portion 20a, that is, a central portion in the left-right direction that is the rotation center of the main portion 20a. Further, the touch substrate 21 is provided with a through hole 21 a at a portion facing the light emitting diode 15 mounted on the main substrate 22. Light emitted from the light emitting diode 15 is incident on the main portion 20a through the through hole 21a, passes through the translucent main portion 20a, and is irradiated forward from the front surface of the main portion 20a.

  In the present embodiment, when the left end portion or the right end portion is pushed in the main portion 20a of the operation portion 20, the operation portion 20 rotates so that the pressed side moves to the rear side. In accordance with the rotation of the operation unit 20, the push button 11a of the tact switch 11 is pushed by the protrusion 24 on the pushed side, and the tact switch 11 is switched from off to on, for example. Based on the input from the tact switch 11, the signal processing unit 10 detects that either the left end portion or the right end portion of the operation unit 20 has been pushed. Thereafter, when the operation unit 20 is not pushed by the operator, the tact switch 11 is turned off. Further, when the return force of the spring built in the tact switch 11 is received and the push button 11a returns to the original position, the operation unit 20 returns to the initial position.

  Further, when the center portion in the left-right direction is tapped on the main portion 20a of the operation unit 20, the capacitance value of the touch sensor 12 on the back side of the region tapped on the main portion 20a is changed to a human body (for example, an operator). Changes with the approach of a finger. Therefore, the signal processing unit 10 compares the input from the touch sensor 12 with a predetermined reference value to determine whether each touch sensor 12 has detected a finger (human body), that is, the tap operation is performed. Determine whether it was done.

  As described above, the signal processing unit 10 detects whether or not a push operation has been performed from the input of the tact switch 11, and detects whether or not a tap operation has been performed from the input of the touch sensor 12.

  Next, the operation of this embodiment will be described. When the signal processing unit 10 detects the tap operation or the push operation as described above, it performs load control according to the tap operation or the push operation, and the operation sequence is shown in FIG.

  In the operation sequence of FIG. 10, when a push operation that pushes the right side of the operation unit 20 is detected, the signal processing unit 10 turns on the LED lighting device 100 and detects a push operation that pushes the left side of the operation unit 20. Then, the signal processing unit 10 turns off the LED lighting device 100. When the tap operation of the operation unit 20 is detected, the signal processing unit 10 causes the LED lighting apparatus 100 to be dimmed and lit at a predetermined dimming level (for example, a dimming level of 15%).

  First, in a state where the LED lighting apparatus 100 is turned off (ST1 in FIG. 10), the signal processing unit 10 controls the drive circuit 17 to turn on the light emitting diode 15 in green and perform position display.

  Further, in a state where the LED lighting device 100 is dimmed and lit at a predetermined dimming level (ST2 in FIG. 10), the signal processing unit 10 controls the drive circuit 17 to light the light emitting diode 15 with a light bulb color. Then, it is notified that the lighting is being performed in the dimming lighting state.

  When the operator pushes the right side of the operation unit 20 with the LED lighting apparatus 100 turned off or dimmed (P11, P12 in FIG. 10), the signal processing unit 10 is a tact switch disposed on the right side. 11 is detected based on the input signal 11. When the signal processing unit 10 detects the push operations P11 and P12 in which the right side is pressed, the signal processing unit 10 outputs a full lighting signal from the output circuit 14 to the LED lighting device 100, and turns on the LED lighting device 100 in the full lighting state. In addition, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, “pi”) from the piezoelectric buzzer 16, and controls the drive circuit 17 to light the light emitting diode 15 in red. To notify that it has been switched to the fully lit state.

  When the operator pushes the left side of the operation unit 20 in a state where the LED lighting apparatus 100 is dimmed or fully lit (ST2 and ST3 in FIG. 10), the signal processing unit 10 has a tact arranged on the left side. Based on the input signal of the switch 11, a push operation in which the left side is pushed is detected. When the signal processing unit 10 detects push operations P13 and P14 in which the left side is pressed, the signal processing unit 10 outputs a turn-off signal from the output circuit 14 to the LED lighting device 100, and turns off the LED lighting device 100. In addition, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, a sound “peep”) from the piezoelectric buzzer 16 to notify that the switch has been switched to the extinguished state. In addition, the signal processing unit 10 controls the drive circuit 17 to light the light emitting diode 15 in green, notifying that the light emitting diode 15 has been switched off, and displaying the position.

  Further, when the operator performs a tap operation with the LED lighting apparatus 100 turned off or fully lit (ST 1 and ST 3 in FIG. 10), the signal processing unit 10 performs the tap operation based on the input of the touch sensor 12. To detect. When the signal processing unit 10 detects the tap operations P15 and P16, the signal processing unit 10 causes the output circuit 14 to output a dimming signal to the LED lighting fixture 100, and the LED lighting fixture 100 is set to a predetermined dimming level (for example, a dimming level of 15%). Turn on the dimmer. Further, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, a sound of “pi”) from the piezoelectric buzzer 16 and controls the drive circuit 17 to light the light emitting diode 15 in a light bulb color. Informs that it has switched to the dimming lighting state.

  As described above, the load controller 1 of the present embodiment includes the first detection unit (consisting of the tact switch 11), the second detection unit (consisting of the touch sensor 12), and the load control unit (consisting of the signal processing unit 10). ). The first detection unit detects a push operation of the operation unit 20 by the operator. The second detection unit detects a tap operation of the operation unit 20 by the operator. The load control unit performs different load control when the first detection unit detects a push operation and when the second detection unit detects a tap operation.

  Thereby, since different load control can be realized depending on whether the same operation unit 20 is tapped or pushed, the operation unit is different from the case where operation units for performing different load control are provided separately. The number of 20 can be reduced. Therefore, the load controller 1 can be miniaturized and the design can be improved. In this embodiment, different load control is performed by controlling the same load to different control states, but load control of different loads may be performed by a tap operation or a flick operation.

  In the present embodiment, the operation unit 20 is rotatably supported, and the first detection unit is configured by a tact switch 11 that is driven by being pushed by the operation unit 20 that is rotated in response to a push operation. . The second detection unit (comprising the touch sensor 12) detects a tap operation at a portion that is rotatably supported by the operation unit 20.

  As described above, in the operation unit 20, the area for detecting the push operation and the area for detecting the tap operation are separate areas, so that the acceleration sensor 13 for discriminating the push operation from the tap operation becomes unnecessary. Incorrect detection of push operation and tap operation is less likely to occur.

(Embodiment 3)
The load controller 1 of Embodiment 3 is demonstrated with reference to FIGS. In addition, the same code | symbol is attached | subjected to the component which is common in Embodiment 1, 2, and the description is abbreviate | omitted.

  In the second embodiment, the operation unit 20 is rotatably supported at an intermediate portion in the left-right direction, whereas in the present embodiment, the operation unit 20 is rotatable about one side (for example, the left side) in the left-right direction. It is supported by.

  That is, the main portion 20a is rotated by pressing the opposite side (for example, the right side portion) of the main portion 20a in the left-right direction, and as shown in FIG. The tact switch 11 is mounted at a position facing the right side of the main portion 20a. A protrusion 24 for pressing the push button 11 a of the tact switch 11 is provided on the back surface of the main portion 20 a at a position facing the tact switch 11.

  The touch sensor 12 is mounted on the surface of the touch substrate 21 on one side in the left-right direction (that is, the left side where the operation unit 20 is rotatably supported). One touch sensor 12 is mounted on each of an upper side and a lower side of the touch substrate 21, and a through hole 21 a is formed in an intermediate portion of the two touch sensors 12 in the touch substrate 21. The main board 22 is mounted with RGB full-color light emitting diodes 15 at positions facing the through holes 21a. The main portion 20a is provided with a through hole (not shown) at a position facing the attachment position of the touch sensor 12, and a rectangular plate-like cover 25 is attached so as to close the through hole. Since the cover 25 slightly protrudes to the front side of the front surface of the main portion 20a, an area where a touch operation can be detected can be easily determined. Further, since the cover 25 is made of a light transmissive material, the light emitted from the light emitting diode 15 is irradiated forward through the through hole 21a of the touch substrate 21 and the cover 25.

  In the present embodiment, when the right side of the main portion 20a is pushed, the operation unit 20 moves so that the pushed side moves to the rear side with a shaft portion (not shown) provided on the left side as a center. Rotate to. And according to rotation of the operation part 20, the push button 11a of the tact switch 11 is pushed by the protrusion 24 on the back side of the main part 20a, and the tact switch 11 is switched from OFF to ON, for example. At this time, the signal processing unit 10 detects that the operation unit 20 has been pushed based on the input from the tact switch 11. Thereafter, when the operation unit 20 is not pushed by the operator, the tact switch 11 is turned off. Further, when the return force of the spring built in the tact switch 11 is received and the push button 11a returns to the original position, the operation unit 20 returns to the initial position.

  When the surface of the cover 25 is tapped on the main portion 20a, the capacitance value of the touch sensor 12 on the back side of the cover 25 changes due to the approach of a human body (for example, an operator's finger). Therefore, the signal processing unit 10 compares the input from the touch sensor 12 with a predetermined reference value to determine whether each touch sensor 12 has detected a finger (human body), that is, the tap operation is performed. It can be determined whether or not it has been performed.

  As described above, the signal processing unit 10 detects whether or not a push operation has been performed from the input of the tact switch 11, and detects whether or not a tap operation has been performed from the input of the touch sensor 12.

  Next, the operation of this embodiment will be described. When the signal processing unit 10 detects the tap operation or the push operation as described above, it performs load control according to the tap operation or the push operation, and the operation sequence is shown in FIG.

  In the operation sequence of FIG. 13, when a push operation is detected, the signal processing unit 10 switches on / off the LED lighting apparatus 100, and when a tap operation is detected, the signal processing unit 10 sets the LED lighting apparatus 100 to a predetermined value. The dimming is turned on at the dimming level.

  First, in a state where the LED lighting apparatus 100 is turned off (ST1 in FIG. 13), the signal processing unit 10 controls the drive circuit 17 to turn on the light emitting diode 15 in green and perform position display.

  Further, in a state where the LED lighting apparatus 100 is dimmed and lit at a predetermined dimming level (ST2 in FIG. 13), the signal processing unit 10 controls the drive circuit 17 to light the light emitting diode 15 in a light bulb color. Then, it is notified that the lighting is being performed in the dimming lighting state.

  When the operator performs a push operation of the operation unit 20 with the LED lighting apparatus 100 turned off (P21 in FIG. 13), the signal processing unit 10 performs the push operation based on the input signal of the tact switch 11. Detect what happened. When the signal processing unit 10 detects the push operation P <b> 21, the signal processing unit 10 outputs a full lighting signal from the output circuit 14 to the LED lighting fixture 100, and turns on the LED lighting fixture 100 in a full lighting state. In addition, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, “pi”) from the piezoelectric buzzer 16, and controls the drive circuit 17 to light the light emitting diode 15 in red. To notify that it has been switched to the fully lit state.

  When the operator performs a push operation of the operation unit 20 in a state where the LED lighting apparatus 100 is dimmed or fully lit (ST2 and ST3 in FIG. 13), the signal processing unit 10 receives an input signal of the tact switch 11. Based on this, it is detected that a push operation has been performed. When the signal processing unit 10 detects the push operations P24 and P25, the signal processing unit 10 outputs a turn-off signal from the output circuit 14 to the LED lighting device 100, and turns off the LED lighting device 100. In addition, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, a sound “peep”) from the piezoelectric buzzer 16 to notify that the switch has been switched to the extinguished state. In addition, the signal processing unit 10 controls the drive circuit 17 to light the light emitting diode 15 in green, notifying that the light emitting diode 15 has been switched off, and displaying the position.

  When the operator performs a tap operation with the LED lighting apparatus 100 turned off or fully lit (ST 1 and ST 3 in FIG. 13), the signal processing unit 10 performs the tap operation based on the input of the touch sensor 12. To detect. When the signal processing unit 10 detects the tap operations P22 and P23, the signal processing unit 10 outputs a dimming signal from the output circuit 14 to the LED lighting fixture 100, and the LED lighting fixture 100 is set to a predetermined dimming level (for example, a dimming level of 15%). Turn on the dimmer. Further, the signal processing unit 10 controls the drive circuit 18 to sound a notification sound (for example, a sound of “pi”) from the piezoelectric buzzer 16 and controls the drive circuit 17 to light the light emitting diode 15 in a light bulb color. Informs that it has switched to the dimming lighting state.

  As described above, the load controller 1 of the present embodiment includes the first detection unit (consisting of the tact switch 11), the second detection unit (consisting of the touch sensor 12), and the load control unit (consisting of the signal processing unit 10). ). The first detection unit detects a push operation of the operation unit 20 by the operator. The second detection unit detects a tap operation of the operation unit 20 by the operator. The load control unit performs different load control when the first detection unit detects a push operation and when the second detection unit detects a tap operation.

  Thereby, since different load control can be realized depending on whether the same operation unit 20 is tapped or pushed, the operation unit is different from the case where operation units for performing different load control are provided separately. The number of 20 can be reduced, and the load controller 1 can be downsized. In this embodiment, different load control is performed by controlling the same load to different control states, but load control of different loads may be performed by a tap operation or a flick operation.

  In the present embodiment, the operation unit 20 is rotatably supported, and the first detection unit is configured by a tact switch 11 that is driven by being pushed by the operation unit 20 that is rotated in response to a push operation. . The second detection unit (comprising the touch sensor 12) detects a tap operation at a portion that is rotatably supported by the operation unit 20.

  Thereby, in the operation part 20, since the area | region which detects push operation, and the area | region which detects tap operation are made into a separate area | region, the acceleration sensor 13 etc. for discriminating push operation and tap operation become unnecessary, False detection of push operation and tap operation is less likely to occur.

  In the present embodiment, the load of the load control unit is a lighting fixture (for example, the LED lighting fixture 100) capable of dimming control. When the first detection unit detects a push operation, the load control unit (signal processing unit 10) The load is switched on and off. When the second detection unit detects a tap operation, the load control unit lights the load at a predetermined dimming level.

  As a result, the load is turned on and off by the push operation, and the light is turned on at a predetermined dimming level by the tap operation.To switch to the desired control state, either the push operation or the tap operation is performed. There is an advantage that it is easy to understand whether it is good.

  Further, in the present embodiment, when the second detection unit detects a long press operation for a predetermined time or longer, that is, when the state where the capacitance value of the touch sensor 12 is equal to or higher than the predetermined reference value continues for a predetermined time or longer, The processing unit 10 may sweep the dimming level of the LED lighting apparatus 100 by controlling the output circuit 14. When the long press is finished and the capacitance value of the touch sensor 12 becomes less than the reference value, the signal processing unit 10 controls the output signal from the output circuit 14 so as to maintain the dimming level at that time. To do. As a result, since the dimming level of the LED lighting apparatus 100 is controlled to the dimming level at the time when the long press of the operation unit 20 is finished, the LED lighting apparatus 100 can be turned on at a desired dimming level. .

  In the first and second embodiments described above, when the second detection unit detects a long press operation for a predetermined time or longer, the signal processing unit 10 controls the output circuit 14 to adjust the dimming level of the LED lighting apparatus 100. When the long press is finished and the capacitance value of the touch sensor 12 becomes less than the reference value, the signal processing unit 10 outputs the output signal from the output circuit 14 so as to maintain the dimming level at that time. May be controlled.

  Moreover, the form of load control demonstrated in Embodiment 1-3 is an example, and is not limited to said control content, It can change suitably according to the apparatus and use environment of a control object.

  In each of the above embodiments, the embodiment in which the present invention is applied to a controller that controls the operating state of a lighting fixture has been described. However, a load other than the lighting fixture (for example, equipment such as a ventilator) may be controlled. . Alternatively, a remote controller that transmits and controls a wireless signal to the load may be used.

1 Load Controller 10 Signal Processing Unit (Load Control Unit)
11 tact switch (first detector)
11a Push button 12 Touch sensor (second detection unit)
20 Operation unit 20c Mounting piece 21 Touch substrate 22 Main substrate 30 Plate member 100 LED lighting device (load)

Claims (4)

A first detector for detecting a push operation of the operation unit,
A second detector for detecting a tapping operation before Symbol operation unit,
A load control unit that performs different load control when the first detection unit detects a push operation and when the second detection unit detects a tap operation ;
A third detection unit for detecting acceleration applied to the operation unit,
In the operation unit, the region where the first detection unit detects a push operation and the region where the second detection unit detects a tap operation overlap at least partially,
When the second detection unit detects an operation of the operation unit, the load control unit determines whether the operation detected by the second detection unit is a tap operation or a push operation based on the detection result of the third detection unit. A load controller that discriminates between them . A first detection unit that detects a push operation of the operation unit;
A second detection unit for detecting a tap operation of the operation unit;
A load control unit that performs different load control when the first detection unit detects a push operation and when the second detection unit detects a tap operation;
The operation unit is rotatably supported,
The first detection unit includes a switch that is driven by being pushed by the operation unit rotated according to a push operation.
The second detection unit is a load controller that detects a tap operation at a part that is different from a part that is pushed by the operation part and that serves as a rotation center in the operation part . The load of the load control unit is a lighting fixture capable of dimming control,
When the first detection unit detects a push operation, the load control unit switches on and off the load,
The load controller according to claim 1 or 2, wherein when the second detection unit detects a tap operation, the load control unit turns on the load at a predetermined dimming level . When the second detection unit detects a long press operation for a predetermined time or longer, the load control unit sweeps the dimming level of the load and turns on the load at the dimming level when the long press operation is finished. The load controller according to claim 3 .

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