JP7065290B2 - Lighting equipment, lighting fixtures, and lighting systems - Google Patents

Description

The present disclosure relates to a lighting device, a luminaire, and a lighting system, and more particularly to a lighting device, a luminaire, and a lighting system that switches the lighting state of a light source according to the on / off of an external power source.

As a conventional example, the lighting device, the lighting fixture, and the lighting system described in Patent Document 1 will be exemplified. The conventional lighting system has a plurality of luminaires and a wall switch for turning on / off the power supply from the commercial power source to each luminaire. Each of the plurality of lighting devices has a light source and a lighting device for lighting the light source. The lighting device has a lighting circuit unit for lighting the light source and an output control unit for controlling the lighting circuit unit and controlling the output of the light source. The lighting device further includes a power supply detection unit that detects the state of the power supply voltage supplied to the lighting device and determines the on / off state of the wall switch, and a dimming control unit that outputs a dimming command value to the output control unit. Have.

In the conventional lighting system, when the power detection unit detects the on / off state of the wall switch and the dimming control unit detects a predetermined power on / off operation (short-time power off operation), the dimming control unit Shifts from the normal lighting mode to the dimming ratio setting mode. In the dimming ratio setting mode, the dimming control unit automatically repeats all dimming ratios at predetermined time intervals, 75% dimming, 50% dimming, 25% dimming, all lighting, and so on. The dimming command value is output to the output control unit so as to switch. In this dimming ratio setting mode, the dimming ratio when the dimming control unit next detects a predetermined power on / off operation (power off operation) is stored in the non-volatile memory. The next time the power is turned on by the wall switch, the dimming control unit reads out the dimming ratio stored in the non-volatile memory and outputs the dimming command value according to the read dimming ratio to the output control unit. Then, the lighting circuit unit lights the light source at the dimming ratio stored in the non-volatile memory.

Japanese Unexamined Patent Publication No. 2010-20972

By the way, when the lighting device is changed to the dimming ratio by turning the wall switch on / off as in the above conventional example, the wall switch is turned on / off due to variations in the constants of the circuit elements constituting the lighting device. Lighting equipment (lighting device) that fails to detect the operation may appear. In this case, an erroneous dimming ratio is stored in the non-volatile memory of the lighting fixture (lighting device) that fails to detect the on / off operation of the wall switch. Therefore, in order to align the operating states of a plurality of lighting fixtures (lighting devices), it is necessary for the user to operate the wall switch to erase (reset) the dimming ratio stored in the non-volatile memory.

An object of the present disclosure is to provide a lighting device, a lighting fixture, and a lighting system capable of reducing the time and effort of a user to operate a wall switch.

The lighting device according to one aspect of the present disclosure is electrically connected to an external power source via a wall switch, and lights a light source by electric power supplied from the external power source via the wall switch. The lighting device includes a power supply circuit that converts electric power input from the external power source and outputs it to the light source, and a detection unit that detects an on / off operation of the wall switch. The lighting device includes a control circuit that controls the power supply circuit according to the on / off operation detected by the detection unit and switches the lighting state of the light source to one of a plurality of lighting states. The control circuit stores a plurality of patterns of the on / off operation, selects one pattern matching the pattern of the on / off operation detected by the detection unit from the plurality of patterns, and selects the light source from the plurality of patterns. The power supply circuit is controlled so as to switch the lighting state of the light source to the lighting state of the light source corresponding to the selected pattern . The control circuit includes a lighting state of the light source before selecting the one pattern from the plurality of patterns, and a lighting state of the light source corresponding to the one pattern selected from the plurality of patterns. If they match, the lighting state of the light source before selecting the one pattern is maintained.

The luminaire according to one aspect of the present disclosure includes the lighting device, a light source to be lit by the lighting device, the lighting device, and a support for supporting the light source.

The lighting system according to one aspect of the present disclosure has a plurality of the luminaires and has a wall switch for opening and closing a power supply path from an external power source to the plurality of luminaires.

The lighting device, the lighting fixture, and the lighting system of the present disclosure have an effect that the time and effort for the user to operate the wall switch can be reduced.

FIG. 1 is a system configuration diagram of a lighting system according to an embodiment of the present disclosure. FIG. 2 is an exploded perspective view of the lighting fixture according to the embodiment of the present disclosure. FIG. 3 is a cross-sectional view of the same lighting fixture. FIG. 4 is a circuit diagram of a lighting device according to the embodiment of the present disclosure. FIG. 5 is a front view of the lighting device of the same as above. FIG. 6 is an explanatory diagram of the initial illuminance correction function in the lighting device of the same. FIG. 7A is a time chart for explaining the detection operation of the first operation pattern in the lighting device of the same. FIG. 7B is a time chart for explaining the detection operation of the second operation pattern in the lighting device of the same.

Each figure described in the following embodiment is a schematic diagram, and the ratio of the size and the thickness of each component does not necessarily reflect the actual dimensional ratio. The configuration described in the following embodiments is only an example of the present disclosure. The present disclosure is not limited to the following embodiments, and various changes can be made depending on the design and the like as long as the effects of the present disclosure can be achieved.

As shown in FIG. 1, the lighting system 8 according to the embodiment of the present disclosure includes a plurality of lighting fixtures 1 according to the embodiment of the present disclosure and a wall switch 80. The wall switch 80 is a small indoor switch (see Japanese Industrial Standards JIS C8304) such as a tumbler switch and a wide handle type switch. The wall switch 80 opens and closes a power supply path from the external power source 9 to a plurality of (six units in the illustrated example) lighting fixtures 1. The external power supply 9 is, for example, a commercial power system, and supplies an AC voltage having an effective value of 100 V and a power supply frequency of 60 Hz or 50 Hz.

As shown in FIG. 1, three of the six lighting fixtures 1 are electrically connected in series to the external power supply 9 and the wall switch 80. Then, the remaining three lighting fixtures 1 out of the six lighting fixtures 1 are electrically connected in series to the external power supply 9 and the wall switch 80, and are electrically connected to the other three lighting fixtures 1. It is connected in parallel. Therefore, each of the six luminaires 1 is turned on by being supplied with electric power (AC power) from the external power source 9 when the wall switch 80 is in the on state, and is turned off when the wall switch 80 is in the off state. .. However, the connection relationship of the plurality of lighting fixtures 1 to the external power supply 9 and the wall switch 80 is not limited to the above connection relationship.

The plurality of lighting fixtures 1 all have a common configuration. The luminaire 1 is a direct-mounted luminaire that is attached to the ceiling, but may be an embedded luminaire embedded in the ceiling or a luminaire that is attached to a place other than the ceiling such as a wall. Further, in the following description, unless otherwise specified, the vertical, horizontal, and front-back directions of the luminaire 1 are defined in the directions shown in FIG.

The lighting fixture 1 has a light source unit 2 and a fixture main body 10 as shown in FIGS. 2 and 3. The instrument body 10 is fixed to the suspension bolt 200 by the nut 300 and directly attached to the ceiling 100. The light source unit 2 is detachably attached to the fixture body 10.

The instrument main body 10 is formed into a long, flat box shape in which the upper surface (the surface facing the ceiling 100) is opened by bending the sheet metal. Further, the fixture main body 10 is provided with a rectangular recess 11 for accommodating the light source unit 2 on the opposite side (lower side) of the ceiling 100 over the entire length in the longitudinal direction (front-back direction). Further, on both sides of the recess 11 in the left-right direction (width direction) of the instrument main body 10, inclined portions 12 extending from the open end edge of the recess 11 and sloping upward toward the outside are provided.

Further, the bottom plate 111 of the recess 11 is provided with a hole 111A for passing the power supply line 90 at substantially the center in the front-rear direction (longitudinal direction). Further, the bottom plate 111 is provided with holes 111B for passing the suspension bolts 200 at positions near both ends in the front-rear direction. A terminal block 25 is attached to the lower surface of the bottom plate 111. The terminal block 25 is electrically connected to the power line 90. Further, three electric wires 250 including a ground wire are drawn out from the terminal block 25. Further, a plug connector 251 is electrically connected to the tips of these three electric wires 250.

As shown in FIGS. 2 and 3, the light source unit 2 includes a plurality of (for example, two) LED modules 22, a mounting member 21, a cover 23, and a lighting device 3. Further, the lighting device 3 has a power supply unit 4 and a functional module 5.

The LED module 22 has a mounting board 221 formed in the shape of a rectangular plate long in the front-rear direction (see FIG. 3). A plurality of LEDs (Light Emitting Diodes) 222 are mounted on the lower surface of the mounting board 221 along the front-rear direction (longitudinal direction) and arranged in two rows. Further, a connector for electrically connecting to and from the power supply unit 4 is mounted on the front end portion of one of the LED modules 22. The output line 43 of the power supply unit 4 is electrically connected to this connector.

Further, a power supply connector 224 is mounted on each LED module 22 at an end facing the adjacent LED module 22 (see FIG. 3). Then, by electrically connecting the connectors 224 of both LED modules 22 to each other, the lighting power is relayed from one LED module 22 to the other LED module 22.

The mounting member 21 is formed in a U shape by bending the sheet metal, and has a long and rectangular bottom plate 211 and a bottom plate 211 in the vertical direction (bottom plate) from both ends in the left-right direction (width direction). It is composed of a pair of side plates 212 extending in a direction orthogonal to 211). As shown in FIG. 3, at the tip end (upper end) of each side plate 212, an inclined portion 212A inclined in a direction away from each other (outward) is provided over the entire length.

A hole for passing the output line 43 of the power supply unit 4 is provided at the front end portion of the bottom plate 211. Further, in the central portion of the bottom plate 211 in the front-rear direction, a rectangular recess formed by projecting a part of the bottom plate 211 upward is provided. This recess is provided in order to secure an insulating distance between the connector 224 and the bottom plate 211 of the mounting member 21 in a state where both LED modules 22 are mounted on the mounting member 21. The LED module 22 described above is fixed to the mounting member 21 by, for example, a claw formed by cutting up a part of the bottom plate 211 of the mounting member 21.

Further, the mounting member 21 has a pair of hook metal fittings 214 extending to one end side in the width direction at positions near both ends in the longitudinal direction, and a pair of hook springs 215 arranged on the other end side in the width direction. (See FIG. 2). The tips of the pair of hook metal fittings 214 are hooked on each of the pair of insertion holes 112A provided in one side plate 112 of the instrument main body 10. Further, the pair of hook springs 215 are hooked on the hook portion 1120 provided on the other side plate 112 of the instrument main body 10.

The cover 23 is formed in a long box shape in which the upper surface (the surface on the mounting member 21 side) is opened by a light diffusing material (for example, milky white acrylic resin). Further, the cover 23 has a convex lens-shaped curved surface portion 231 so that the amount of protrusion toward the lower side increases from both end sides to the center side in the left-right direction (width direction) (see FIG. 3).

As shown in FIG. 3, at both ends of the cover 23 in the left-right direction, as shown in FIG. 3, an extension portion 232 that overlaps with the opening end edge of the recess 11 of the fixture body 10 in the vertical direction with the light source unit 2 attached to the fixture body 10. Are provided respectively. Further, in the left-right direction of the cover 23, inside each extending portion 232, a protruding wall portion 233 projecting to the upper side (mounting member 21 side) is provided over the entire length, and the tip of each protruding wall portion 233 is provided. Each of the protrusions 233A protruding inward is provided. Further, near the root of each protruding wall portion 233, a support piece 233B protruding inward is projected.

The power supply unit 4 is configured by mounting electronic components on the first printed wiring board 40. The first printed wiring board 40 is housed in the first case 42. The circuit diagram of the power supply unit 4 is shown in FIG. The power supply unit 4 includes a power supply input unit 400, a filter circuit 401, a rectifier unit 402, a booster circuit 403, a step-down circuit 404, a power supply output unit 405, and a main control circuit 406. The power supply unit 4 further includes a control power supply circuit 407, a dimming control circuit 408, a light-off control circuit 409, a signal input unit 410, and a voltage detection circuit 411.

The power input unit 400 is composed of a receptacle connector, and a plug connector 251 (see FIG. 2) electrically connected to the electric wire 250 drawn from the terminal block 25 is plugged in and connected. The filter circuit 401 includes a common mode choke coil 4010 and an across-the-line capacitor 4011. The rectifying unit 402 is a diode bridge. The rectifying unit 402 full-wave rectifies the AC voltage input from the external power supply 9 via the filter circuit 401 and the power supply input unit 400, and outputs the AC voltage from the DC output terminal.

The booster circuit 403 is a booster chopper circuit (power factor improving circuit) having a choke coil L1, a switching element Q1, a rectifier element D1, and a smoothing capacitor C1. The booster circuit 403 converts the pulsating voltage output from the rectifying unit 402 into a DC voltage higher than the peak value of the pulsating voltage (for example, a DC voltage of 400 volts).

Further, the step-down circuit 404 is a step-down chopper circuit (back converter) having a switching element Q2, an inductor L2, a rectifier element D2, a resistor R1, and a smoothing capacitor C2. The step-down circuit 404 steps down the DC voltage output from the step-up circuit 403 to a DC voltage suitable for the LED module 22 which is a load. The power supply output unit 405 is composed of a receptacle connector and is electrically connected to the output terminals (both ends of the smoothing capacitor C2) of the step-down circuit 404. The step-up circuit 403 and the step-down circuit 404 form a power supply circuit.

The voltage detection circuit 411 detects the on / off operation of the wall switch 80. The voltage detection circuit 411 is electrically parallel to a plurality of resistors R2 and R3 electrically connected in series between the output ends of the step-down circuit 404 (between both ends of the smoothing capacitor C2) and a resistor R3 on the low potential side. It has a connected Zener diode ZD1. The voltage detection circuit 411 outputs a detection voltage (a voltage proportional to the output voltage of the step-down circuit 404) obtained by dividing the output voltage of the step-down circuit 404 by a plurality of resistors R2 and R3.

The main control circuit 406 switches the switching element Q1 of the step-up circuit 403 and the switching element Q2 of the step-down circuit 404, respectively, keeps the output voltage of the step-up circuit 403 constant, and matches the output current of the step-down circuit 404 with the target value. Let me. The control power supply circuit 407 is configured to generate a control voltage (for example, a DC voltage of about 15V to 3V) from the output voltage of the booster circuit 403. The main control circuit 406 operates at the control voltage supplied from the control power supply circuit 407.

The signal input unit 410 is composed of a receptacle connector, and the plug connector 504 of the functional module 5 is plugged in and connected (see FIG. 5). As will be described later, the control signal output from the functional module 5 is input to the dimming control circuit 408 and the extinguishing control circuit 409 via the signal input unit 410.

The extinguishing control circuit 409 generates an extinguishing signal for extinguishing the lighting LED module 22 according to the control signal, and outputs the extinguishing signal to the main control circuit 406. When the main control circuit 406 receives the extinguishing signal, the switching of the switching element Q2 is stopped, the step-down circuit 404 is stopped, and the LED module 22 is extinguished.

Further, the dimming control circuit 408 generates a dimming signal indicating the light output (dimming level) of the LED module 22 according to the control signal and outputs the dimming signal to the main control circuit 406. The dimming level is the ratio (%) of the average power supplied to the LED module 22 per unit time to the rated power when the optical output of the LED module 22 when the rated power is supplied is 100%. It is represented by. For example, when the average power supplied to the LED module 22 per unit time is half the rated power, the dimming level is 50%. In other words, the dimming control circuit 408 halves the average power per unit time supplied from the step-down circuit 404 to the LED module 22 if the dimming level indicated by the control signal is 50%. Generates a dimming signal to instruct. The main control circuit 406 preferably adjusts the on-duty ratio of the switching element Q2 according to the dimming signal received from the dimming control circuit 408. More specifically, the dimming control circuit 408 detects the output current of the step-down circuit 404 from the voltage across the resistor R1 so that the average value of the output current matches the target value corresponding to the dimming level. It is preferable to generate a dimming signal.

As shown in FIG. 5, the first printed wiring board 40 is configured by printing a wiring conductor (copper foil) on the back surface of a long rectangular flat plate-shaped insulating substrate. So-called lead components such as a connector, a smoothing capacitor, and a common mode choke coil 4010 are mounted on the surface of the first printed wiring board 40. Then, surface mount components such as a rectifying unit 402, a main control circuit 406, a dimming control circuit 408, and a light-off control circuit 409 are mounted on the back surface of the first printed wiring board 40. Here, the power input unit 400 is mounted on the surface of the longitudinal end portion (hereinafter, referred to as the first end portion) of the first printed wiring board 40. On the other hand, the power output unit 405 and the signal input unit 410 are mounted on the surface of the other end portion (hereinafter, referred to as the second end portion) in the longitudinal direction of the first printed wiring board 40. Then, the filter circuit 401, the rectifying unit 402, the step-up circuit 403, the step-down circuit 404, and the power supply output unit 405 are sequentially mounted on the first printed wiring board 40 from the first end to the second end. Further, the main control circuit 406, the control power supply circuit 407, the dimming control circuit 408, and the extinguishing control circuit 409 are mounted on the first printed wiring board 40 in order from the rectifying unit 402 toward the second end. Since the rectifying unit 402 is mounted on the back surface of the first printed wiring board 40, it is not shown in FIG. 5, but it is mounted at a position slightly closer to the second end from the common mode choke coil 4010. ing.

As shown in FIGS. 3 and 5, the first case 42 includes a bottom plate, a pair of first side plates 421A and 421B rising from the edge along the lateral direction of the bottom plate, and an edge along the longitudinal direction of the bottom plate. It has a pair of second side plates 422A and 422B that rise from. That is, the first case 42 is formed in a long box shape in which the front of the bottom plate is open. Further, the first case 42 includes a fixing plate 423 that projects outward from the tip of one of the second side plates 422A. The fixing plate 423 is formed in a gutter shape as shown in FIG.

The first printed wiring board 40 is housed in the first case 42 with the back surface facing the bottom plate and the second end facing the first side plate 421A, and is cut and raised from the pair of second side plates 422A and 422B. It is fixed to the first case 42 by four claws 4220 (see FIG. 5). The insertion port of the power input unit 400 projects out of the first case 42 through a rectangular window hole provided in the first side plate 421B on the first end side.

As shown in FIG. 2, the power supply unit 4 is attached to the attachment member 21 of the light source unit 2 so that the bottom plate of the first case 42 faces up. Specifically, the first case 42 is fixed to the mounting member 21 by screwing the second side plate 422B and the fixing plate 423 to each side plate 212 of the mounting member 21. Further, in the state of being attached to the attachment member 21, the opening of the first case 42 is closed by the bottom plate 211 of the attachment member 21.

The functional module 5 has a circuit unit in which electronic components are mounted on a printed wiring board, and a second case 51 for accommodating the circuit unit. As shown in FIG. 4, the circuit unit includes a control circuit 500, a signal output unit 502, and a signal cable 503.

The control circuit 500 has a microcontroller. The control circuit 500 realizes various functions described later by executing a program on a CPU (Central Processing Unit) of a microcontroller.

The signal output unit 502 is electrically connected to the signal input unit 410 of the power supply unit 4 via the signal cable 503. The signal cable 503 has four electric wires 503A to 503D. The electric wire 503A electrically connects the ground of the power supply unit 4 and the ground terminal of the control circuit 500. The electric wire 503B electrically connects the output terminal of the control power supply circuit 407 and the power supply input terminal of the control circuit 500. The electric wire 503C electrically connects the dimming control circuit 408 and the extinguishing control circuit 409 to the output terminal (microcontroller output port) of the control circuit 500. The electric wire 503D electrically connects the output terminal of the voltage detection circuit 411 (the connection point of the two resistors R2 and R3) and the input terminal of the control circuit 500 (the input port of the microcontroller). The control circuit 500 operates by supplying a control power supply voltage from the control power supply circuit 407 of the power supply unit 4 via the two electric wires 503A and 503B.

The functional module 5 houses the circuit unit inside the second case 51. The functional module 5 is attached to the first case 42 so as to connect the second case 51 to the longitudinal end of the first case 42 (the end on the first side plate 421A side) (see FIG. 5).

The control circuit 500 of the function module 5 realizes the initial illuminance correction function. The initial illuminance correction function is the accumulation of light sources so that the light output is kept almost constant (for example, 80% of the rated light output) from the start of use of the LED module 22 to the end of its life. It is a function to adjust the dimming level according to the lighting time.

The control circuit 500 measures the time during which the control power supply voltage is supplied from the control power supply circuit 407 of the power supply unit 4 (the time during which the microcontroller is operating) and stores it in the built-in memory (nonvolatile semiconductor memory). .. The control circuit 500 regards the cumulative value of the time stored in the memory as the cumulative lighting time of the LED module 22. Here, the built-in memory of the microcontroller constituting the control circuit 500 stores the illuminance correction characteristic shown by the solid line in FIG. This illuminance correction characteristic represents the relationship between the cumulative lighting time (horizontal axis t) and the dimming level (vertical axis%). In this illuminance correction characteristic, the initial value of the dimming level when the cumulative lighting time t = 0 is set to a value lower than 100% (for example, 80%), and the dimming level gradually increases in proportion to the cumulative lighting time. Is set to increase to. The illuminance correction characteristic is set so that the dimming level is set to 100% when the cumulative lighting time t reaches the preset life time t1. The control circuit 500 determines the dimming level corresponding to the cumulative lighting time t from the illuminance correction characteristic every predetermined time (for example, every few minutes to several hours), and generates a control signal instructing the determined dimming level. Then, it is output from the signal output unit 502 to the power supply unit 4.

Further, the control circuit 500 of the function module 5 realizes a one-to-switch function. The one-to-switch function is a function of changing the lighting state (for example, dimming level) of the LED module 22 according to the on / off operation of the wall switch 80, as described in the prior art.

The control circuit 500 takes in the detection voltage of the voltage detection circuit 411 of the power supply unit 4 (a voltage proportional to the output voltage of the step-down circuit 404) into the input port through the two electric wires 503A and 503D. The control circuit 500 determines that the wall switch 80 is in the on state if the detected voltage is higher than the threshold voltage, and determines that the wall switch 80 is in the off state if the detected voltage is equal to or lower than the threshold voltage. .. The control circuit 500 detects the time and the number of times that the wall switch 80 switches from the on state to the off state and further from the off state to the on state, so that the on / off operation of the wall switch 80 is any of a plurality of operation patterns. Judgment (detection) whether or not it corresponds to the operation pattern of.

The memory of the control circuit 500 stores the determination criteria of the first operation pattern and the second operation pattern. The criterion for determining the first operation pattern is that the number of times of switching from the off state to the on state is three, and the duration T1 of each of the off state and the on state is (1-β) seconds <T1 <(. The condition of 1 + α) seconds is satisfied (see FIG. 7A). However, α is preferably about 1 second and β is preferably about 0.5 seconds. On the other hand, the criterion for determining the second operation pattern is that the number of times of switching from the off state to the on state is two, and the duration T2 of each of the off state and the on state is (3-γ) seconds <T2. <The condition of (3 + δ) seconds is satisfied (see FIG. 7B). However, γ and δ are preferably about 1 second.

When the control circuit 500 detects the on / off operation of the wall switch 80 corresponding to the first operation pattern, the dimming level is set to 100 regardless of the dimming level (for example, 80%) determined from the initial illuminance correction. Switch to%. Then, the control circuit 500 generates a control signal indicating a 100% dimming level and outputs the control signal from the signal output unit 502 to the power supply unit 4. The power supply unit 4 controls the step-down circuit 404 according to the control signal received from the control circuit 500, and lights the LED module 22 at a dimming level of 100%.

On the other hand, when the control circuit 500 detects the on / off operation of the wall switch 80 corresponding to the second operation pattern, the control circuit 500 switches the dimming level to the dimming level determined from the initial illuminance correction. Then, the control circuit 500 generates a control signal indicating the dimming level (for example, 80%) determined from the initial illuminance correction, and outputs the control signal from the signal output unit 502 to the power supply unit 4. The power supply unit 4 controls the step-down circuit 404 according to the control signal received from the control circuit 500, and dimming and lighting the LED module 22 at the dimming level determined from the initial illuminance correction.

Here, in the lighting system 8 shown in FIG. 1, even though the wall switch 80 performs an on / off operation corresponding to the first operation pattern, the lighting of one of the plurality of lighting fixtures 1 is performed. It is assumed that the dimming level of the instrument 1 has not changed. Then, when the wall switch 80 performs the on / off operation corresponding to the first operation pattern again, the normal lighting fixture 1 (the lighting fixture 1 whose dimming level has already changed to 100%) is the first. The dimming level does not change even if the on / off operation of the operation pattern is detected. On the other hand, in the failed lighting fixture 1 (lighting fixture 1 in which the dimming level did not change in the previous on / off operation), the dimming level changes when the on / off operation corresponding to the first operation pattern is detected. .. As a result, the plurality of (six) lighting fixtures 1 are all in the same lighting state, that is, the LED module 22 is rated to be lit at a dimming level of 100%.

Further, in the lighting system 8 shown in FIG. 1, one of the plurality of lighting fixtures 1 is used even though the wall switch 80 is used to perform an on / off operation corresponding to the second operation pattern. It is assumed that the dimming level of 1 does not change. Then, when the on / off operation corresponding to the second operation pattern is performed again with the wall switch 80, the normal lighting fixture 1 (the lighting fixture 1 whose dimming level has already changed to 80%) is the second. The dimming level does not change even if the on / off operation of the operation pattern is detected. On the other hand, in the failed lighting fixture 1 (lighting fixture 1 in which the dimming level did not change in the previous on / off operation), the dimming level changes when the on / off operation corresponding to the second operation pattern is detected. .. As a result, the plurality (6 units) of the lighting fixtures 1 are all in the same lighting state, that is, the LED module 22 is in a dimming lighting state in which the initial illuminance is corrected (a dimming lighting state at a dimming level of 80%). .. The control circuit 500 is a step-down circuit 404 so as to reproduce the state stored in the memory (the state before switching to the off state) when the wall switch 80 is operated from the on state to the off state and then to the on state. To control.

Therefore, in the control circuit 500 of the lighting device 3, when the lighting state of the LED module 22 is different from the lighting state that should have already been changed, when the on / off operation of the wall switch 80 is detected, the lighting state is already present. The step-down circuit 404 is controlled so as to switch to the lighting state that should be changed. Here, the "lighting state that should have already been changed" means a lighting state that should have already been changed if the on / off operation of the wall switch 80 is correctly detected. In the above-mentioned example, the lighting state that is switched when the wall switch 80 performs the on / off operation corresponding to the second operation pattern, that is, the state in which the LED module 22 is lit at the dimming level of 80% is ". It means "lighting state that should have already been changed". Therefore, in the above-mentioned example, "a lighting state different from the lighting state that should have already been changed" means a state in which the LED module 22 is rated and lit at a dimming level of 100%.

Further, the control circuit 500 preferably stores a plurality of patterns of on / off operation of the wall switch 80. The control circuit 500 selects one pattern (first operation pattern or second operation pattern) that matches the detected on / off operation pattern from a plurality of patterns, and the LED module according to the selected pattern. It is preferable to switch the lighting state of 22. Therefore, the lighting device 3 can reduce the time and effort of the user to operate the wall switch 80 when switching to the lighting state that should have already been changed.

The number of on / off operation patterns stored in the memory of the control circuit 500 is not limited to two, and may be three or more. Further, the lighting state of the LED module 22 corresponding to each on / off operation pattern is not limited to the rated lighting state (lighting state of 100% dimming level) and the dimming lighting state by initial illuminance correction. Further, the power supply circuit (boost circuit 403 and step-down circuit 404) and the control circuit 500 are housed in separate cases (first case 42 and second case 51), but the power supply circuit and the control circuit 500 are contained in one case. It does not matter if it is contained.

Next, a modification of the lighting device 3 according to the embodiment will be described. The lighting device 3 of the modified example has the same configuration as the lighting device 3 according to the embodiment.

In the lighting device 3 of the modified example, the control circuit 500 may ignore the detection result of the new on / off operation of the wall switch 80 within a certain period of time from the time when the on / off operation of the wall switch 80 is detected. preferable. When the control circuit 500 detects a new on / off operation of the wall switch 80 after a certain period of time has elapsed, it is preferable to switch the lighting state of the LED module 22 according to the on / off operation.

In the lighting system 8 composed of the lighting fixture 1 having the lighting device 3 of the modified example, the lighting fixture 1 of one of the plurality of lighting fixtures 1 is operated even though the wall switch 80 is used to turn on / off. Suppose the dimming level did not change. Then, when the wall switch 80 is turned on / off again within a certain period of time, the detection result of the on / off operation is performed in the normal lighting fixture 1 (the lighting fixture 1 whose dimming level has already changed to 100%). Is ignored. On the other hand, in the failed lighting fixture 1 (lighting fixture 1 in which the dimming level did not change in the previous on / off operation), the dimming level changes when the on / off operation is detected. As a result, the plurality of (six) lighting fixtures 1 are all in the same lighting state. In the control circuit 500, the fixed time for ignoring the detection result of the on / off operation is preferably about several hundred milliseconds to several seconds.

Here, in the lighting device 3, the on / off operation of the wall switch 80 may be detected by detecting the input voltage of the booster circuit 403. However, in the lighting device 3 of the embodiment and the modified example, the power supply input unit 400 to which the AC voltage is input from the external power supply 9 is arranged on the first end side of the first printed wiring board 40, and the control circuit 500 is the first. It is arranged outside the second end of the printed wiring board 40. Therefore, when the voltage detection circuit detects the input voltage of the booster circuit 403, the wiring length for electrically connecting the voltage detection circuit and the control circuit 500 becomes long, which causes a problem that the wiring work becomes difficult. Will end up.

On the other hand, in the lighting device 3 of the embodiment and the modified example, the on / off operation of the wall switch 80 is detected by detecting the output voltage of the step-down circuit 404 with the voltage detection circuit 411. Therefore, in the lighting device 3, the wiring length from the voltage detection circuit 411 to the control circuit 500 can be shortened.

As described above, the lighting device (3) according to the first aspect is electrically connected to the external power source (9) via the wall switch (80), and is connected to the external power source (9) via the wall switch (80). The light source (LED module 22) is turned on by the electric power supplied to the light source (LED module 22). The lighting device (3) according to the first aspect includes a power supply circuit (boost circuit 403 and step-down circuit 404) that converts the power input from the external power supply (9) into power and outputs the power to the light source. The lighting device (3) according to the first aspect includes a detection unit (control circuit 500 and voltage detection circuit 411) that detects an on / off operation of the wall switch (80). The lighting device (3) according to the first aspect controls the power supply circuit according to the on / off operation detected by the detection unit, and controls to switch the lighting state of the light source to one of a plurality of lighting states. The circuit (500) is provided. When the lighting state of the light source when the detection unit detects an on / off operation is a lighting state different from the lighting state that should have already been changed, the control circuit (500) has a lighting state that should have already been changed. Control the power supply circuit to switch to.

The lighting device (3) according to the first aspect can reduce the time and effort of the user to operate the wall switch (80) when switching the lighting state of the light source to the lighting state that should have already been changed. ..

The lighting device (3) according to the second aspect can be realized in combination with the first aspect. In the lighting device (3) according to the second aspect, in the control circuit (500), when the detection unit detects an on / off operation while power is being supplied from the external power supply (9), the detection unit detects it. It is preferable to memorize the lighting state of the light source switched according to the on / off operation. It is preferable that the control circuit (500) controls the power supply circuit so as to switch the lighting state of the light source to the lighting state of the stored light source when the power supply from the external power source (9) is started.

The lighting device (3) according to the second aspect can reproduce the lighting state of the light source before the lighting is turned off when the light source is switched from the lighting state to the lighting state.

The lighting device (3) according to the third aspect can be realized by the combination with the first or the second aspect. In the lighting device (3) according to the third aspect, it is preferable that the control circuit (500) stores a plurality of patterns of on / off operations. It is preferable that the control circuit (500) selects one pattern that matches the pattern of the on / off operation detected by the detection unit from a plurality of patterns, and switches the lighting state of the light source according to the selected pattern.

In the lighting device (3) according to the third aspect, since the pattern of the on / off operation when switching from one lighting state to another lighting state is individually determined, the wall switch (80) by the user can be used. It is possible to reduce the labor of operation.

The lighting device (3) according to the fourth aspect can be realized in combination with the third aspect. In the lighting device (3) according to the fourth aspect, the plurality of patterns of the on / off operation are the on time when the wall switch (80) is on, the off time when the wall switch (80) is off, and the off time. It preferably consists of a combination of the number of times the wall switch (80) is turned on and off within a predetermined period.

The lighting device (3) according to the fourth aspect can reliably switch the light source to a desired lighting state by identifying a plurality of patterns.

The lighting device (3) according to the fifth aspect can be realized by the combination with the first or the second aspect. In the lighting device (3) according to the fifth aspect, the control circuit (500) ignores the detection result of the on / off operation of the detection unit within a certain period of time from the time when the detection unit detects the on / off operation. It is preferable to do so. It is preferable that the control circuit (500) switches the lighting state of the light source according to the on / off operation detected by the detection unit after a certain period of time.

The lighting device (3) according to the fifth aspect does not require the user to memorize a plurality of patterns of the on / off operation, so that the usability can be improved.

The lighting device (3) according to the sixth aspect can be realized by combining with one of the first to fifth aspects. In the lighting device (3) according to the sixth aspect, it is preferable that the detection unit detects the on / off operation of the wall switch (80) by the output voltage of the power supply circuit.

The lighting device (3) according to the sixth aspect has a control circuit (500) and a detection unit (voltage detection) as compared with the case where the detection unit detects the on / off operation of the wall switch (80) by the input voltage of the power supply circuit. The wiring length of the circuit 411) can be shortened.

The lighting device (3) according to the seventh aspect can be realized by combining with one of the first to sixth aspects. The lighting device (3) according to the seventh aspect preferably includes a case (first case 42, second case 51) for accommodating a power supply circuit, a detection unit, and a control circuit (500). It is preferable that the input terminal (power input unit 400) of the power supply circuit is arranged at one end of the case (first case 42). It is preferable that the detection unit is arranged at the other end of the case (first case 42) located on the opposite side of the power supply circuit with respect to one end of the case (first case 42) in which the input terminal is arranged.

The lighting device (3) according to the seventh aspect has a control circuit (500) and a detection unit (voltage detection) as compared with the case where the detection unit detects the on / off operation of the wall switch (80) by the input voltage of the power supply circuit. The wiring length of the circuit 411) can be shortened.

The lighting fixture (1) according to the eighth aspect includes a lighting device (3) according to any one of the first to seventh aspects, a light source to be lit by the lighting device (3), a lighting device (3), and a lighting device (3). It is provided with a support (apparatus body 10) that supports the light source.

The lighting fixture (1) according to the eighth aspect can reduce the time and effort of the user to operate the wall switch (80) when switching the lighting state of the light source to the lighting state that should have already been changed. ..

The lighting system (8) according to the ninth aspect has a plurality of lighting fixtures (1) according to the eighth aspect. The lighting system (8) according to a ninth aspect has a wall switch (80) that opens and closes a power supply path from an external power source (9) to a plurality of lighting fixtures (1).

The lighting system (8) according to the ninth aspect can reduce the time and effort of the user to operate the wall switch (80) when switching the lighting state of the light source to the lighting state that should have already been changed. ..

1 Lighting equipment 3 Lighting equipment 8 Lighting system 9 External power supply 10 Equipment body (support)
22 LED module (light source)
42 First case (case)
51 Second case (case)
80 Wall switch 400 Power input section (input terminal)
403 Booster circuit (power supply circuit)
404 Step-down circuit (power supply circuit)
411 Voltage detection circuit (detection unit)
500 Control circuit (control circuit, detector)

Claims (8)

A lighting device that is electrically connected to an external power source via a wall switch and lights a light source by electric power supplied from the external power source via the wall switch.
A power supply circuit that converts the power input from the external power supply into power and outputs it to the light source.
A detector that detects the on / off operation of the wall switch,
A control circuit that controls the power supply circuit according to the on / off operation detected by the detection unit and switches the lighting state of the light source to one of a plurality of lighting states.
Equipped with
The control circuit stores a plurality of patterns of the on / off operation, selects one pattern matching the pattern of the on / off operation detected by the detection unit from the plurality of patterns, and selects the light source from the plurality of patterns. The power supply circuit is controlled so as to switch the lighting state of the light source to the lighting state of the light source corresponding to the selected pattern .
The control circuit includes a lighting state of the light source before selecting the one pattern from the plurality of patterns, and a lighting state of the light source corresponding to the one pattern selected from the plurality of patterns. If they match, the lighting state of the light source before selecting the one pattern is maintained.
Lighting device. In the control circuit, when the detection unit detects the on / off operation while power is supplied from the external power source, the light source is switched according to the on / off operation detected by the detection unit. Memorize the lighting state,
The control circuit controls the power supply circuit so as to switch the lighting state of the light source to the lighting state of the stored light source when the power supply from the external power source is started.
The lighting device according to claim 1. The plurality of patterns of the on / off operation is a combination of the on time when the wall switch is on, the off time when the wall switch is off, and the number of times the wall switch is turned on and off within a predetermined period. Consists of
The lighting device according to claim 1 or 2 . The control circuit ignores the detection result of the on / off operation of the detection unit within a certain time from the time when the detection unit detects the on / off operation, and the detection unit detects the on / off operation after the certain time. The lighting state of the light source is switched according to the on / off operation.
The lighting device according to any one of claims 1 to 3 . The detection unit detects the on / off operation of the wall switch by the output voltage of the power supply circuit.
The lighting device according to any one of claims 1 to 4 . A case for accommodating the power supply circuit, the detection unit, and the control circuit is provided.
The input terminal of the power supply circuit is arranged at one end of the case, and the detection unit is located at the other end of the case located on the opposite side of the power supply circuit from one end of the case where the input terminal is arranged. Is placed,
The lighting device according to any one of claims 1 to 5 . The lighting device according to any one of claims 1 to 6 and the lighting device.
The light source that can be turned on by the lighting device and
A support that supports the lighting device and the light source, and
To prepare
lighting equipment. Having a plurality of lighting fixtures according to claim 7 ,
It has a wall switch that opens and closes a power supply path from an external power source to the plurality of lighting fixtures.
Lighting system .

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