JP2014107251A - Lighting device and lighting fixture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting device, in which a light source module being detachably mounted and which lights the light source module when mounted, capable of determining attachment or detachment of the light source module using a power supply with a stable voltage value.SOLUTION: A DC generation section 150 generates a control voltage (a DC power supply Vdc) of a stable voltage value on the basis of generation control from a control circuit 60. The control circuit 60 monitors a detection voltage (a lamp connection detection signal) based on a control voltage output by a lamp connection detection circuit 30 to determine the attachment or detachment of a light source module 200. In other words, the lighting device 100 can determine the attachment or detachment of the light source module 200, using a control voltage with a stable voltage value.

Description

  The present invention relates to a lighting device and a lighting fixture. The present invention particularly relates to a lighting device and a lighting fixture for lighting an LED as a light source.

  Before the start of oscillation of the inverter circuit, power is supplied from the main power source to the inverter control circuit via the current limiting element, and after the start of oscillation of the inverter circuit, power is supplied to the inverter control circuit by the oscillation output of the inverter circuit. There is a technique in which an electric lamp lighting device is configured to intermittently supply current from a main power supply to an inverter control circuit via a current limiting element by opening and closing a switching element during standby of the inverter circuit. (For example, refer to Patent Document 1.)

Japanese Patent Application Laid-Open No. 07-57887

  However, it is necessary to open and close the switching element during standby of the inverter circuit, and there is a problem that the control power supply voltage during standby becomes unstable. Moreover, since the control for driving (opening / closing) the switching element is performed, there is a problem that standby power is increased.

  For example, in a lighting device to which a light source is detachably attached, the main object of the present invention is to obtain a power supply having a stable voltage value when a lighting circuit that lights the light source is on standby. The main object is to determine whether a light source is attached or detached using a power supply with a stable voltage value.

The lighting device according to the present invention includes:
In a lighting device in which a light source is detachably attached and turns on the light source when attached,
An AC voltage is supplied from an AC power source and is subjected to generation control, thereby generating a DC voltage having a voltage value based on the generation control from the AC voltage as a control voltage, and supplying the generated control voltage;
A lighting unit for lighting the light source at the time of mounting, wherein the control voltage is supplied by the supply unit, and the light source is turned on from the control voltage by receiving a lighting control for lighting the light source at the time of mounting. A lighting unit that generates a lighting voltage higher than the required voltage value;
A light source mounting detection unit that outputs a detection voltage of a voltage value different between when the light source is mounted and when the light source is removed by supplying the control voltage supplied by the supply unit;
A control unit that performs the generation control and the lighting control on the supply unit and the lighting unit, and intermittently performs the generation control on the supply unit, thereby intermittently controlling the control voltage. And when the control voltage is intermittently generated with respect to the supply unit, a control unit that stops the lighting control for the lighting unit,
The light source wearing detector is
By intermittently supplying the control voltage from the supply unit, intermittently outputting the detection voltage based on the control voltage supplied intermittently,
The controller is
The detection voltage output intermittently by the light source mounting detection unit is monitored, and it is determined whether or not the light source is mounted based on a voltage value of the detected detection voltage.

  According to the present invention, the supply unit generates a control voltage having a stable voltage value based on generation control. And a control part determines attachment or detachment of a light source by monitoring the detection voltage based on the control voltage which a light source mounting | wearing detection part outputs. That is, the lighting device according to the present invention can determine whether the light source is attached or detached using a control voltage with a stable voltage value.

FIG. 5 shows the first embodiment and shows a structure of a lighting fixture. FIG. 5 is a diagram showing the first embodiment, and is a sequence diagram showing an operation of the lighting device before detection of mounting of the light source module. FIG. 5 shows the first embodiment and is a timing chart showing the operation of the lighting device. FIG. 5 is a diagram showing the first embodiment, and is a sequence diagram showing an operation of the lighting device after detection of mounting of the light source module. FIG. 5 shows a second embodiment and shows a structure of a lighting fixture. FIG. 5 is a diagram showing the second embodiment, and is a sequence diagram showing the operation of the lighting device before detecting the mounting of the light source module. FIG. 9 shows the second embodiment and is a timing chart showing the operation of the lighting device.

Embodiment 1 FIG.
(Outline of lighting equipment)
FIG. 1 is a diagram illustrating a configuration of a lighting fixture 800.
The lighting fixture 800 includes a lighting device 100 and a light source module 200.
A light source module 200 (light source) is connected (mounted) to the lighting device 100, and AC power is supplied from an AC power source AC. And the lighting device 100 converts the supplied alternating current power into the electric power according to the light source module 200 connected. Here, in the lighting device 100, the light source module 200 is detachably attached, and the light source module 200 at the time of connection is turned on.

  The light source module 200 includes a plurality of light emitting diodes LD connected in series and a connection resistor Rs connected in parallel to the light emitting diodes LD connected in series. That is, the lighting device 100 lights up the light emitting diode LD. In FIG. 1, the light source module 200 includes six light emitting diodes LD, but the number of light emitting diodes LD is not limited.

(Configuration of lighting device 100 as a whole)
The lighting device 100 includes a DC generator 150 (supply unit), a lighting circuit 20 (lighting unit), a first converter circuit 40 (second voltage conversion unit), a second converter circuit 50 (first voltage conversion unit), and a lamp connection. A detection circuit 30 (light source mounting detection unit), a control circuit 60 (control unit), and a lamp connection detection voltage generation circuit 22 (transmission unit) are provided. The direct current generator 150 includes a rectifier circuit DB and a PFC (power factor correction) circuit 10.

(Description of rectifier circuit DB)
The rectifier circuit DB is a diode bridge circuit, and full-wave rectifies the AC voltage supplied from the AC power supply AC and outputs a pulsating DC voltage (hereinafter also referred to as rectification). That is, the rectifier circuit DB converts the AC voltage into a pulsating DC voltage.

(Description of PFC circuit 10)
The PFC circuit 10 includes a resistor R1, a resistor R2, an inductor L1, a switching element Q1, a detection resistor R3, a PFC control circuit 11, a diode D1, and a capacitor C1. The switching element Q1 is a MOS-FET.
The PFC circuit 10 is connected to the rectifier circuit DB, and the pulsating flow converted by the rectifier circuit DB is divided by the resistors R1 and R2.
The PFC control circuit 11 receives the generation control from the control circuit 60, and further detects when the first control power Vcc1 (described later) is supplied by the divided voltage applied to the resistor R2 and the detection resistor R3. The detected voltage is monitored. Then, the PFC control circuit 11 performs switching control of the switching element Q1 based on the monitoring result. By switching control of the switching element Q1, the current is charged or discharged to the inductor L1, and the pulsating voltage converted by the rectifier circuit DB (the output voltage of the rectifier circuit DB) reaches a voltage value based on the generation control. Boosted. That is, the PFC circuit 10 boosts the pulsating current output from the rectifier circuit DB. In other words, the generation control is control in which the control circuit 60 boosts the pulsating voltage to the PFC circuit 10.
The boosted pulsating current is smoothed by charging the capacitor C1 through the diode D1, and the PFC circuit 10 outputs a DC power supply Vdc that is a smoothed voltage.
That is, the DC generator 150 (rectifier circuit DB and PFC circuit 10) is supplied with AC voltage from the AC power supply AC. The DC generator 150 receives generation control from the control circuit 60 to generate a DC power supply Vdc having a voltage value based on the generation control from the AC voltage, and outputs (supplies) the generated DC power supply Vdc.
Here, the DC power supply Vdc generated by the DC generator 150 receiving generation control is referred to as a “control voltage”. Furthermore, the DC power supply Vdc generated when the DC generation unit 150 receives generation control is also referred to as “a boosted DC power supply Vdc”.

On the other hand, the DC generator 150 (the rectifier circuit DB and the PFC circuit 10) is used when the generation control from the control circuit 60 is stopped or when the operation voltage used for the control voltage generation operation is not supplied. Stops generating the control voltage. Here, the operation voltage used for the control voltage generating operation is an operation voltage of the PFC control circuit 11 and is a voltage necessary for the PFC control circuit 11 to perform switching control of the switching element Q1.
When the generation of the control voltage is stopped, the PFC circuit 10 outputs the DC power supply Vdc that is obtained by smoothing the pulsating flow converted by the rectifier DB DB from the AC voltage supplied by the AC power supply AC. That is, when the switching element Q1 is not subjected to switching control, the pulsating current output by the rectifier circuit DB is not boosted.
That is, when the generation of the control voltage is stopped, the DC generator 150 generates a DC power supply Vdc (DC voltage) having a voltage value based on the AC voltage from the AC voltage supplied from the AC power supply AC, and generates the generated DC The power supply Vdc is output (supplied).
Here, the DC power supply Vdc having a voltage value based on the AC voltage generated when the DC generation unit 150 stops generating the control voltage is referred to as “power supply dependent voltage”. Furthermore, the DC power supply Vdc having a voltage value based on the AC voltage is also referred to as “DC power supply Vdc during non-boosting”.

(Description of lighting circuit 20)
The lighting circuit 20 includes a primary winding L2p of the coil L2, a switching element Q2, a diode D4, and a lighting control circuit 21. The switching element Q2 is a MOS-FET. The coil L2 is a transformer having a primary winding L2p and a secondary winding L2s described later, and the primary winding L2p and the secondary winding L2s are magnetically coupled.
The lighting circuit 20 shown in FIG. 1 constitutes a so-called buck converter circuit, but other configurations (a boost converter circuit and a flyback circuit) may be used.
The lighting circuit 20 is connected to the direct current generator 150. The lighting circuit 20 is supplied with the control voltage by the DC generator 150 when the DC generator 150 is generating the control voltage (the boosted DC power supply Vdc). The lighting circuit 20 (lighting control circuit 21) performs lighting (switching) operation of the switching element Q2 by receiving lighting control from the control circuit 60, and generates a lighting voltage from the control voltage.
Here, the lighting voltage is a voltage equal to or higher than a voltage value necessary for lighting the light emitting diode LD in the light source module 200 mounted on the lighting device 100. The lighting control is control for lighting the light emitting diode LD in the mounted light source module 200.
Then, the lighting circuit 20 lights the light emitting diode LD in the light source module 200 connected to the lighting circuit 20 by supplying the generated lighting voltage to the light source module 200 as the output voltage Vout. Note that lighting the light emitting diode LD in the light source module 200 is referred to as “lighting the light source module 200”.

(Description of the lamp connection detection circuit 30)
The lamp connection detection circuit 30 monitors the attachment / detachment of the light source module 200.
The lamp connection detection circuit 30 includes three resistors R31 to R33 connected in series.
When the output voltage Vout of the lighting circuit 20 is supplied to the lamp connection detection circuit 30, the lamp connection detection circuit 30 divides the output voltage Vout of the lighting circuit 20 by resistance. Alternatively, when the DC power supply Vdc output from the PFC circuit 10 is supplied by the lamp connection detection voltage generation circuit 22, the lamp connection detection circuit 30 converts the DC power supply Vdc output from the PFC circuit 10 into the resistance R21 and the resistance R22. Then, the resistance is further divided by resistors R31 to R33.
When the light source module 200 is connected to the lighting device 100, since the connection resistance Rs is connected in parallel to the resistance R31 and the resistance R32, when the light source module 200 is connected and when it is removed, The voltage at the connection point between the resistor R31 and the resistor R32 changes.
That is, the lamp connection detection circuit 30 outputs detection voltages having different voltage values when the light source module 200 is attached and when the light source module 200 is removed.
The lamp connection detection circuit 30 outputs a voltage (detection voltage) at a connection point between the resistors R31 and R32 as a lamp connection detection signal.

(Description of the control circuit 60)
The control circuit 60 is, for example, a microcomputer (CPU).
The control circuit 60 monitors the lamp connection detection signal and determines whether the light source module 200 is attached or detached based on the monitoring result. Then, the control circuit 60 performs generation control on the DC generator 150 (PFC control circuit 11) and performs lighting control on the lighting circuit 20 (lighting control circuit 21).

(Description of the first converter circuit 40)
The first converter circuit 40 includes a secondary winding L2s of a coil L2, a diode D2, and a capacitor C2.
The first converter circuit 40 extracts the first control power supply Vcc1 (second DC voltage) from the lighting voltage generated by the lighting circuit 20 by receiving the lighting control, and supplies the first control power source Vcc1 to the second converter circuit 50.
In other words, the first converter circuit 40 rectifies part of the lighting voltage generated by the lighting circuit 20 by the diode D2 rectifying the voltage generated in the secondary winding L2s by the lighting voltage generated by the lighting circuit 20. Thus, the first control power supply Vcc1 is generated.

(Description of second converter circuit 50)
The second converter circuit 50 is connected to the PFC circuit 10 and the first converter circuit 40.
The second converter circuit 50 is supplied with the control voltage as the supply voltage when the control voltage (the boosted DC power supply Vdc) is supplied by the DC generator 150. On the other hand, when the power source dependent voltage (DC power source Vdc at the time of non-boosting) is supplied by the DC generator 150, the power source dependent voltage is supplied as the supply voltage.
Then, the supply voltage supplied from the DC generator 150 is converted into the second control power supply Vcc2, and the converted second control power supply Vcc2 is supplied to the lighting control circuit 21 and the control circuit 60. Here, the second control power supply Vcc2 based on the supply voltage (DC power supply Vdc) supplied by the DC generator 150 is referred to as standby control power supply V21 (first DC voltage).
On the other hand, when the first converter circuit 40 is generating the first control power supply Vcc1, the second converter circuit 50 is supplied with the first control power supply Vcc1 from the first converter circuit 40. When the first converter circuit 40 is supplied with the first control power supply Vcc1, the second converter circuit 50 converts the supply voltage (DC power supply Vdc) supplied by the DC generator 150 into the standby control power supply V21. To stop. Further, the second converter circuit 50 supplies the second control power source Vcc2 based on the supplied first control power source Vcc1 to the lighting control circuit 21 and the control circuit 60. Here, the second control power supply Vcc2 based on the first control power supply Vcc1 is referred to as an operation control power supply V22 (third DC voltage).
That is, the second converter circuit 50 switches the standby control power supply V21 to the operation control power supply V22 and supplies the switched operation control power supply V22 to the lighting control circuit 21 and the control circuit 60.
The second converter circuit 50 switches the standby control power supply V21 to the operation control power supply V22 when the first control power supply Vcc1 supplied from the first converter circuit 40 exceeds a preset threshold. May be.
The voltage value of the standby control power supply V21 and the voltage value of the operation control power supply V22 may be the same or different. For example, the voltage value of the standby control power supply V21 may be lower than the voltage value of the operation control power supply V22.

(Description of the lamp connection detection voltage generation circuit 22)
The lamp connection detection voltage generation circuit 22 includes a resistor R21 and a resistor R22 connected in parallel between the drain terminal and the source terminal of the switching element Q2.
The lamp connection detection voltage generation circuit 22 transmits the DC power supply Vdc output from the PFC circuit 10 to the lamp connection detection circuit 30 regardless of whether the switching element Q2 is turned on or off (whether the lighting circuit 20 operates or not). Apply).

<Operation of lighting device 100 before detection of mounting of light source module 200>
Next, the operation of the lighting device 100 will be described.
First, the operation of the lighting device 100 before the detection of mounting of the light source module 200 (when the light source module 200 is removed from the lighting device 100) will be described with reference to FIGS.
FIG. 2 is a sequence diagram showing the operation of the lighting device 100 before the mounting of the light source module 200 is detected.
FIG. 3 is a timing chart showing the operation of the lighting device 100 ((a) is the connection state of the light source modules, (b) is the voltage of the AC power supply AC, (c) is the voltage of the DC power supply Vdc, and (d) is The voltage of the second control power supply Vcc2, (e) is the lighting control signal to the lighting control circuit, (f) is the oscillation operation of the switching element Q2, (g) is the voltage of the first control power supply Vcc1, and (h) is the PFC control. (I) is the oscillation operation of the switching element Q1, (j) is the timing at which the control circuit detects the connection state of the light source module, and (k) is the output voltage of the lighting device 100).

(Explanation from time t1 to time t2)
Time t1 (FIG. 3) is a time when the AC power supply AC is turned on.
At time t1, the light source module 200 is detached from the lighting device 100 (FIG. 3A). Further, the generation control by the control circuit 60 is stopped at time t1. Here, the state where the generation control by the control circuit 60 is stopped is a state where an operation start signal is not output from the control circuit 60 to the PFC control circuit 11 (or an operation stop signal is output). Yes (FIG. 3 (h)). The operation start signal (or operation stop signal) will be described later.
At time t1, the AC power supply AC is turned on (S201 in FIG. 2), and a predetermined voltage is supplied (FIG. 3 (b)). Here, the alternating voltage of FIG.3 (b) has shown the effective value.
And rectifier circuit DB converts an alternating voltage into a pulsating flow.
At time t1, the operation start signal is not output from the control circuit 60 to the PFC control circuit 11. Further, since the operating voltage is not supplied to the PFC control circuit 11, the switching element Q1 of the PFC circuit 10 is stopped (the generation of the control voltage is stopped). For this reason, the pulsating flow output by the rectifier circuit DB is not boosted.
The PFC circuit 10 smoothes the pulsating current output from the rectifier circuit DB, and generates the smoothed pulsating current as the DC power supply Vdc having the voltage value Va. That is, the PFC circuit 10 outputs the DC power supply Vdc having the voltage value Va (S202 in FIG. 2, FIG. 3C). The DC power supply Vdc having the voltage value Va is a non-boosting DC power supply Vdc (power supply dependent voltage), and the DC power supply Vdc having the voltage value Va is supplied to the second converter circuit 50.
Further, the DC power source Vdc having the voltage value Va is also supplied to the lighting circuit 20.

At this time, the first control power supply Vcc1 is not supplied from the first converter circuit 40.
The second converter circuit 50 converts the DC power supply Vdc (power supply dependent voltage) having the voltage value Va (supplied from the PFC circuit 10) generated by the DC generator 150 into the second control power supply Vcc2 (standby control) having the voltage value V2. The power is converted into the power supply V21 (FIG. 3D). In other words, the second converter circuit 50 generates the standby control power supply V21 from the DC power supply Vdc.
Then, the second converter circuit 50 supplies (outputs) the generated second control power supply Vcc2 (standby control power supply V21) to the lighting control circuit 21 and the control circuit 60 (S203 in FIG. 2).

The lighting control circuit 21 enters a standby state (a state in which the oscillation of the switching element Q2 can be controlled) when the second control power supply Vcc2 (standby control power supply V21) is supplied (S204 in FIG. 2).
Further, the control circuit 60 is activated when the second control power supply Vcc2 (standby control power supply V21) is supplied (S205 in FIG. 2). That is, the control circuit 60 is operated by the second control power supply Vcc2 (standby control power supply V21) supplied from the second converter circuit 50.
When activated, the control circuit 60 outputs a lighting control signal (hereinafter referred to as “pre-lighting signal”) for temporarily driving (oscillating) the switching element Q2 to the lighting control circuit 21 (S211a in FIG. 2, FIG. 3 (e)). The pre-lighting signal is output, for example, at a predetermined time tp (for example, 1 to 3 seconds).

Since the second control power supply Vcc2 has already been supplied to the lighting control circuit 21, the DC power supply Vdc (power supply dependent voltage) having the voltage value Va is supplied by the PFC circuit 10 (S202 in FIG. 2 described above). When the pre-lighting signal is input, the switching element Q2 starts oscillating (S212 in FIG. 2, FIG. 3 (f)).
At this time, the output voltage Vout of the voltage value Voff is generated in the lighting circuit 20 by the oscillation of the switching element Q2 (FIG. 3 (k)). However, since the voltage value is low at this voltage value Voff, the light source module 200 is lit. Not.
Here, since only the DC power supply Vdc having the voltage value Va is supplied to the lighting circuit 20, even if the switching element Q2 oscillates, only the output voltage Vout having the voltage value Voff is generated. Therefore, the pre-lighting signal may be the same voltage as the lighting signal described later.
The lighting control circuit 21 controls the oscillation of the switching element Q2 according to the voltage of the lighting control signal. When the pre-lighting signal is input, the pre-lighting signal may be a voltage lower than a lighting signal described later in order to reduce the output voltage Vout so that the light source module 200 is not lighted. For example, the voltage value of the pre-lighting signal may be a value that can generate the first control power supply Vcc1 from the first converter circuit 40.

Here, the output voltage Vout of the voltage value Voff is a turn-off maintaining voltage that is smaller than the voltage value necessary for the light source to turn on. The control for generating the output voltage Vout having the voltage value Voff, that is, the output of the pre-lighting signal is referred to as the extinguishing maintenance control. That is, the control circuit 60 causes the lighting circuit 20 to generate the output voltage Vout having the voltage value Voff by performing the extinction maintenance control on the lighting circuit 20.
On the other hand, the lighting circuit 20 is supplied with the DC power supply Vdc (power supply dependent voltage) having the voltage value Va from the PFC circuit 10 and receives the power-off maintaining control from the control circuit 60 when the power supply dependent voltage is supplied. From this, a sustaining voltage is generated.
In addition to the output voltage Vout of the lighting circuit 20, a voltage transmitted by the lamp connection detection voltage generation circuit 22 is applied to the light source module 200. Therefore, the voltage value Voff of the extinction maintaining voltage is smaller than the voltage value necessary for the light source to turn on even if the voltage value transmitted by the lamp connection detection voltage generation circuit 22 is added to the voltage value Voff. Is set to be
In addition, as shown in FIG.3 (e), the control circuit 60 performs a light extinction maintenance control intermittently with respect to the lighting control circuit 21 (it outputs a pre lighting signal). Therefore, the lighting circuit 20 intermittently generates a light extinction maintaining voltage.

When the oscillation of the switching element Q2 is started, a current flows through the primary winding L2p. Further, the secondary winding L2s is excited and an induced current starts to flow through the secondary winding L2s.
Thereby, the first converter circuit 40 generates the first control power supply Vcc1 having the voltage value V1 based on the output voltage Vout (extinguishing sustain voltage) having the voltage value Voff, and outputs (supplied) the generated first control power supply Vcc1. The process starts (S213 in FIG. 2, FIG. 3 (g)).
That is, in the period during which the turn-off maintaining voltage is generated by the lighting circuit 20, the first converter circuit 40 generates the first control power supply Vcc1 from the turn-off maintaining voltage generated by the lighting circuit 20 when the switching element Q2 oscillates. Take out. Then, the first converter circuit 40 supplies the extracted first control power supply Vcc1 to the PFC control circuit 11 as an operating voltage.

  Further, the first converter circuit 40 charges the capacitor C2 with at least a part of the electric charge based on the extracted first control power supply Vcc1. The capacitance of the capacitor C2 may be a value that can generate the first control power supply Vcc1.

The first control power supply Vcc1 output from the first converter circuit 40 is also supplied to the second converter circuit 50.
Therefore, the second converter circuit 50 is supplied with the first control power supply Vcc1 from the first converter circuit 40, whereby the second control power supply Vcc2 (standby control power supply V21) based on the DC power supply Vdc is changed to the first control power supply. The second control power supply Vcc2 (operation control power supply V22) based on Vcc1 may be switched and supplied.
Here, before the control circuit 60 determines the mounting of the light source module 200, the control circuit 60 generates the second control power source Vcc2 (standby control power source V21) based on the DC power source Vdc to the second converter circuit 50. Control to continue. In FIG. 1, connection for the control circuit 60 to control the second converter circuit 50 is not shown.

  At time t1, since the control circuit 60 does not output the lighting control signal to the PFC control circuit 11 (FIG. 2 (h)), the PFC control circuit 11 stops the oscillation of the switching element Q1 ( FIG. 2 (i)). In other words, the control circuit 60 outputs a lighting control signal (operation stop signal) having a voltage value of zero for stopping the switching element Q1 to the PFC control circuit 11. Therefore, as described above, the output voltage of the PFC circuit 10 is equal to the rectified voltage Va obtained by rectifying the AC power supply.

(Explanation from time t2 to time t3)
Time t2 is a time when the control circuit 60 outputs a lighting control signal to the PFC control circuit 11.
When the predetermined time tp elapses and the control circuit 60 stops outputting the pre-lighting signal, the control circuit 60 sends a lighting control signal (also referred to as an operation start signal) for driving (oscillating) the switching element Q1 to the PFC control circuit 11. At time t2, the data is output (S211b in FIG. 2, FIG. 3 (h)). This lighting control signal is output, for example, at a predetermined time ts (for example, 1 to 3 seconds).
Output of the lighting control signal (operation start signal) to the PFC control circuit 11 by the control circuit 60 is referred to as generation control.
The control circuit 60 stops outputting the pre-lighting signal to the lighting control circuit 21 at a predetermined time ts (FIG. 3 (e)). Then, the lighting control circuit 21 stops the oscillation of the switching element Q2 (FIG. 3 (f)). In other words, the control circuit 60 outputs to the lighting control circuit 21 a lighting control signal (light extinction signal) having a voltage value of zero for stopping the switching element Q2 at the predetermined time ts.
That is, the control circuit 60 intermittently performs generation control on the PFC control circuit 11 as shown in FIG.

Here, the first converter circuit 40 generates the first control power supply Vcc1 from the charge charged in the capacitor C2 during a period when the turn-off maintaining voltage is not generated by the lighting circuit 20 (for example, t2 to t3 in FIG. 3). To do. Then, the first converter circuit 40 supplies the generated first control power supply Vcc1 to the PFC control circuit 11 as an operation voltage. That is, the first converter circuit 40 continuously supplies the operating voltage to the PFC control circuit 11.
Since the first control power supply Vcc1 is supplied from the first converter circuit 40 to the PFC control circuit 11, when the lighting control signal is input, the PFC control circuit 11 starts oscillation of the switching element Q1 (FIG. 2, S214, FIG. 3 (i)). The voltage value of the first control power supply Vcc1 decreases as the capacitor C2 is discharged (FIG. 3 (g)).

When the oscillation of the switching element Q1 is started, the rectified voltage rectified by the rectifier circuit DB is boosted from the voltage value Va to the voltage value Vb, and the PFC circuit 10 outputs the DC power source Vdc having the voltage value Vb (FIG. 2, S214, FIG. 3 (c)). The DC power supply Vdc having the voltage value Vb is a boosted DC power supply Vdc (control voltage). That is, the PFC circuit 10 generates the control voltage by being supplied with the first control power supply Vcc1 as the operating voltage by the first converter circuit 40 and being subjected to generation control by the control circuit 60.
Then, the control circuit 60 intermittently generates the control voltage by intermittently generating and controlling the PFC control circuit 11. The control circuit 60 stops the lighting control for the lighting circuit 20 when the PFC control circuit 11 is intermittently generating the control voltage.

A DC power supply Vdc (control voltage) having a boosted voltage value Vb is supplied to the lighting circuit 20 by the PFC circuit 10.
Then, the lamp connection detection voltage generation circuit 22 uses the control voltage supplied to the lighting circuit 20 as the control voltage supplied to the lamp connection detection circuit 30 through the supply from the PFC circuit 10 to the lighting circuit 20. It is transmitted (supplied) to the detection circuit 30.
In other words, the lamp connection detection voltage generation circuit 22 extracts the control voltage supplied to the lighting circuit 20 and transmitted to the lighting circuit 20 from the lighting circuit 20 (the drain terminal of the switching element Q2 in FIG. 1) and connects the lamp. This is transmitted to the detection circuit 30.
Here, the DC power source Vdc having the voltage value Vb is divided by the resistor R21, the resistor R22, and the resistors R31 to R33, and for example, the divided voltage value Vb1 is applied to the lamp connection detection circuit 30. The voltage value Vb and the voltage value Vb1 are in a proportional relationship, and the divided voltage value Vb1 is a voltage based on the DC power source Vdc of the voltage value Vb.
In FIG. 1, the resistor R22 is connected to a connection point between the source terminal of the switching element Q2 and one end of the primary winding L2p. Therefore, the lamp connection detection voltage generation circuit 22 transmits the control voltage to the lamp connection detection circuit 30 via the primary winding L2p. However, since the primary winding L2p is a coil, the control voltage (voltage value) is a direct current. It does not contribute to the partial pressure of the DC power supply Vdc) of Vb.
Further, the resistor R22 may be connected to a connection point between the other end of the primary winding L2p and the resistor R31. That is, the lamp connection detection voltage generation circuit 22 may directly transmit the control voltage to the lamp connection detection circuit 30 without going through the primary winding L2p.
In other words, the lamp connection detection voltage generation circuit 22 converts the voltage value of the control voltage, and transmits the voltage converted voltage (voltage based on the control voltage) to the lamp connection detection circuit 30.
In the present embodiment, since the lamp connection detection voltage generation circuit 22 is constituted by a resistance element, the voltage value of the control voltage is converted as described above, but the lamp connection detection voltage generation circuit 22 The voltage value of the voltage may be transmitted to the lamp connection detection circuit 30 without conversion (maintaining the voltage value of the control voltage). Specifically, the lamp connection detection voltage generation circuit 22 may be a switching element that is turned on when the switching element Q2 of the lighting circuit 20 is off. The lamp connection detection voltage generation circuit 22 only needs to be connected so that the control voltage output from the PFC circuit 10 can be transmitted to the lamp connection detection circuit 30. That is, the parts constituting the lamp connection detection voltage generation circuit 22 are not limited.
In other words, the lamp connection detection voltage generation circuit 22 is supplied with a control voltage from the DC generation unit 150 and supplies (transmits) a voltage based on the supplied control voltage to the lamp connection detection circuit 30. The lamp connection detection circuit 30 outputs a detection voltage when supplied with a voltage based on the control voltage supplied (transmitted) by the lamp connection detection voltage generation circuit 22.

When the light source module 200 is removed and a voltage of the voltage value Vb1 is applied, a detection voltage of the voltage value Vr1 is generated at the connection point between the resistor R31 and the resistor R32 of the lamp connection detection circuit 30 (FIG. 2 S206).
Here, the lamp connection detection circuit 30 is supplied with the control voltage intermittently from the PFC circuit 10 via the lighting circuit 20 and the lamp connection detection voltage generation circuit 22, thereby supplying the control voltage intermittently. The detection voltage based on is intermittently output.

The control circuit 60 monitors (monitors) the detection voltage (lamp connection detection signal) output from the lamp connection detection circuit 30 during the predetermined time tp during which the PFC circuit 10 outputs the DC power supply Vdc having the voltage value Vb. (S207 in FIG. 2, FIG. 3 (j)). Then, the control circuit 60 detects this voltage value Vr1.
Here, the control circuit 60 monitors the detection voltage output intermittently by the lamp connection detection circuit 30, and determines whether or not the light source module 200 is mounted based on the voltage value of the detected detection voltage.

At this time, since the PFC circuit 10 is operating, a constant voltage (control voltage) is applied to the lamp connection detection voltage generation circuit 22. Therefore, even when the lighting circuit 20 is stopped (even when the switching element Q2 is off), the lamp connection detection circuit 30 supplies power to the lamp connection detection circuit 30. That is, power is supplied to the lamp connection detection circuit 30 by the lamp connection detection voltage generation circuit 22 regardless of whether the lighting circuit 20 operates or not.
On the other hand, when the PFC circuit 10 is not operating, a voltage obtained by rectifying the voltage of the AC power supply AC is supplied to the lamp connection detection circuit 30 by the lamp connection detection voltage generation circuit 22. In this case, the voltage supplied to the lamp connection detection circuit 30 changes as the voltage value of the AC power supply AC changes. Therefore, since the voltage value detected by the control circuit 60 also changes, the control circuit 60 may erroneously detect attachment / detachment of the light source module.
That is, by operating the PFC circuit 10 and supplying a constant voltage to the lamp connection detection circuit 30, the control circuit 60 can attach and detach the light source module 200 with high accuracy without being affected by the voltage fluctuation of the AC power supply AC. Can be detected.

  Then, the control circuit 60 detects that the light source module 200 is removed based on the voltage (lamp connection detection signal) output from the lamp connection detection circuit 30.

(Description from time t3 to time t6)
Time t3 is the time when the control circuit 60 outputs the pre-lighting signal again.
The control circuit 60 outputs a pre-lighting signal to the lighting control circuit 21 again when the predetermined time ts has elapsed.
On the other hand, the control circuit 60 stops outputting the lighting control signal to the PFC control circuit 11. In other words, the control circuit 60 outputs a lighting control signal (also referred to as an operation stop signal) having a voltage value of zero for stopping the switching element Q1 to the PFC control circuit 11 (FIG. 3 (h)).
Since the subsequent operation is the same as that at time t1, the description thereof is omitted. Time t5 is the same as time t1. Furthermore, time t4 is the same as time t2.
That is, the portion “A” in FIG. 2 is repeated.

(Explanation from time t6 to before time t7)
Time t6 is the time when the light source module 200 is mounted on the lighting device 100.
At time t6, the light source module 200 is connected to the lighting device 100 (S208 in FIG. 2, FIG. 3A).

(Description after time t7)
Time t7 is a time when the control circuit 60 outputs a lighting control signal to the PFC control circuit 11 after the light source module 200 is mounted.
At time t7, the control circuit 60 outputs a lighting control signal to the PFC control circuit 11 as described above (S211b in FIG. 2, FIG. 3 (h)). Then, the switching element Q1 oscillates (S214 in FIG. 2, FIG. 3 (i)), and the PFC circuit 10 outputs the DC power source Vdc having the voltage value Vb (S214 in FIG. 2, FIG. 3 (c)).
In the same manner as described above, the lamp connection detection voltage generation circuit 22 applies the voltage of the voltage value Vb1 to the lamp connection detection circuit 30.
Here, since the connection resistance Rs is connected in parallel to the resistance R31 and the resistance R32 by mounting the light source module 200, the voltage of the lamp connection detection signal (the voltage at the connection point between the resistance R31 and the resistance R32) is a voltage value. The voltage rises from Vr1 to the voltage value Vr2 (S209 in FIG. 2).
Then, the control circuit 60 detects this voltage value Vr2 at the timing of monitoring the lamp connection detection signal at time t7 (FIG. 3 (j)), and determines that the light source module 200 is connected to the lighting device 100 (FIG. 2 S210).
That is, the control circuit 60 determines that the light source is mounted as a result of monitoring the detection voltage output intermittently by the lamp connection detection circuit 30 when the control voltage is intermittently supplied.

<Operation of Lighting Device 100 after Detection of Mounting Light Source Module 200>
Next, the operation of the lighting device 100 after the mounting detection of the light source module 200 (when the light source module 200 is mounted from the lighting device 100) will be described using FIG. 3 and FIG.
FIG. 4 is a sequence diagram showing the operation of the lighting device 100 after the mounting detection of the light source module 200 is detected.

When the control circuit 60 determines that the light source module 200 is connected to the lighting device 100 (S210 in FIG. 4), the control circuit 60 performs lighting control on the lighting control circuit 21. Specifically, the control circuit 60 drives (oscillates) the switching element Q2 and outputs a lighting control signal (hereinafter referred to as “lighting signal”) for lighting the light source module 200 to the lighting control circuit 21 (FIG. 4). S211c, FIG. 3 (e)). The voltage value of the lighting signal may be higher than or equal to the voltage value of the pre-lighting signal.
Further, the control circuit 60 outputs a lighting control signal for driving (oscillating) the switching element Q1 to the PFC control circuit 11 (S211c in FIG. 4, FIG. 3 (h)). These lighting control signals are continuously output unless the light source module 200 is removed.
The oscillation of the switching element Q1 is continued (S214c in FIG. 4, FIG. 3 (i)), and the output of the DC power source Vdc having the voltage value Vb is continued from the PFC circuit 10 (S214c in FIG. 4, FIG. c)). The DC power source Vdc having the voltage value Vb is supplied to the lighting circuit 20.
Further, the oscillation of the switching element Q2 is continued by the lighting signal (S212c in FIG. 4, FIG. 3 (f)), and the lighting circuit 20 generates the output voltage Vout of the voltage value Vf from the DC power supply Vdc of the voltage value Vb ( FIG. 3 (k)). The light source module 200 is turned on by the output voltage Vout having the voltage value Vf (S215c in FIG. 4).

On the other hand, the first converter circuit 40 also continues to output the first control power supply Vcc1 (S213c in FIG. 4, FIG. 3G). In other words, the first converter circuit 40 generates the first control power supply Vcc1 having the voltage value V1b based on the output voltage Vout having the voltage value Vf.
Here, after the control circuit 60 determines the mounting of the light source module 200, the control circuit 60 continues to generate the second control power source Vcc2 (standby control power source V21) based on the DC power source Vdc to the second converter circuit 50. Stop the control.
Then, when the first control power Vcc1 is supplied from the first converter circuit 40, the second converter circuit 50 stops generating the second control power Vcc2 from the DC power Vdc. That is, when the first control power supply Vcc1 having the voltage value V1b is supplied from the first converter circuit 40, the second converter circuit 50 stops the conversion from the DC power supply Vdc to the standby control power supply V21.

The second converter circuit 50 supplies the first control power supply Vcc1 supplied by the first converter circuit 40 to the control circuit 60 and the lighting control circuit 21 as the second control power supply Vcc2 (operation control power supply V22) (FIG. 4 S216c, FIG. 3 (c)).
That is, the second converter circuit 50 switches the second control power supply Vcc2 (standby control power supply V21) based on the DC power supply Vdc to the second control power supply Vcc2 (operation control power supply V22) based on the first control power supply Vcc1, The switched operation control power supply V22 is supplied.
In the example shown in FIG. 3, the voltage value of the standby control power supply V21 and the voltage value of the operation control power supply V22 are the same, but as described above, the voltage value of the standby control power supply V21 and the operation control power supply V22 are the same. It may be different from the voltage value of V22.
The second converter circuit 50 converts (steps up or down) the voltage value of the first control power supply Vcc1 supplied by the first converter circuit 40, and supplies it as the second control power supply Vcc2 (operation control power supply V22). May be. Further, the second converter circuit 50 may maintain the voltage value of the first control power supply Vcc1 supplied by the first converter circuit 40 and supply it as the operation control power supply V22. For example, the voltage value of the operation control power supply V22 may be lower than the voltage value of the first control power supply Vcc1. That is, the second converter circuit 50 may step down the first control power supply Vcc1 to generate the operation control power supply V22.

(Explanation after lighting the light source module 200)
When the control power supply V22 for operation is supplied from the second converter circuit 50, the control circuit 60 operates by the control power supply V22 for operation supplied from the second converter circuit 50. That is, the control circuit 60 continues to operate by supplying the operation control power V22 switched from the standby control power V21.
Then, the control circuit 60 continues to monitor the lamp connection detection signal (FIG. 3 (j)).
The lamp connection detection circuit 30 is applied with the voltage value Vb1 by the lamp connection detection voltage generation circuit 22 and the output voltage Vout of the voltage value Vf by the lighting circuit 20.
Here, the voltage value output from the lamp connection detection circuit 30 when the voltage value Vb1 and the output voltage Vout of the voltage value Vf are applied and the light source module 200 is mounted is Vr3.
The control circuit 60 determines that the light source module 200 has been removed when the voltage value falls to a voltage value within a preset range from Vr3. Then, the control circuit 60 controls the lighting control circuit 21 to stop the oscillation of the switching element Q2, and controls the PFC control circuit 11 to stop the oscillation of the switching element Q1.
Then, the lighting device 100 repeats the operation of the portion “A” in FIG.

(Effect of Embodiment 1)
The lighting device 100 according to the present embodiment operates the PFC circuit 10 and supplies a light source module 200 during a period in which a voltage having a preset voltage value that does not depend on the voltage of the AC power supply AC is supplied to the lamp connection detection circuit 30. Detects attachment / detachment. Therefore, even when the AC power source AC having the voltage value A is connected to the lighting device 100, the voltage of the AC power source AC is used even when the AC power source AC having the voltage value B different from the voltage value A is connected to the lighting device 100. Regardless of the value, the same voltage value is supplied to the lamp connection detection circuit 30. And it is possible to detect attachment / detachment of the light source module 200 with high accuracy regardless of the voltage value of the AC power supply AC.
Further, even when the lighting circuit 20 is stopped (even when the switching element Q2 is off), the lighting device 100 includes the lamp connection detection voltage generation circuit 22 so that the voltage of the PFC circuit 10 is supplied to the lamp connection detection circuit 30. Since it is supplied, it is possible to accurately detect whether the light source module 200 is attached or detached.

Embodiment 2. FIG.
In the present embodiment, differences from the first embodiment will be mainly described.
In the first embodiment, the case where the PFC circuit 10 is operated after the control circuit 60 operates the lighting circuit 20 has been described. However, in the present embodiment, the lighting circuit 20 is started after the PFC circuit 10 is started. It is made to let you.

FIG. 5 is a diagram illustrating a configuration of the lighting fixture 800.
The PFC control circuit 11 of the lighting device 100 according to the first embodiment is operated by the first control power supply Vcc1. On the other hand, the PFC control circuit 11 of the lighting device 100 of the present embodiment shown in FIG. 5 is different in that it operates by the power of the second control power supply Vcc2, and the other circuit configuration is the same as that of the first embodiment. The description is omitted.

Next, the operation of the lighting device 100 will be described.
The operation of the lighting device 100 before the detection of mounting of the light source module 200 (when the light source module 200 is removed from the lighting device 100) will be described with reference to FIGS.
FIG. 6 is a sequence diagram showing the operation of the lighting device 100 before the mounting of the light source module 200 is detected.
FIG. 7 is a timing chart showing the operation of the lighting device 100 ((a) is the connection state of the light source module, (b) is the voltage of the AC power supply AC, (c) is the voltage of the DC power supply Vdc, and (d) is The voltage of the second control power supply Vcc2, (e) is the lighting control signal to the lighting control circuit, (f) is the oscillation operation of the switching element Q2, (g) is the voltage of the first control power supply Vcc1, and (h) is the PFC control. (I) is the oscillation operation of the switching element Q1, (j) is the timing at which the control circuit detects the connection state of the light source module, and (k) is the output voltage of the lighting device 100).

(Explanation from time t1 to time t2)
Time t1 (FIG. 7) is a time when the AC power supply AC is turned on.
At time t1, the light source module 200 is detached from the lighting device 100 (FIG. 7A).
At time t1, the AC power supply AC is turned on (S201 in FIG. 6), and the control circuit 60 is activated by the supply of the second control power supply Vcc2 (standby control power supply V21) (S205 in FIG. 2). The operations up to are the same as those in the first embodiment.
Here, the second converter circuit 50 supplies (outputs) the generated second control power supply Vcc2 (standby control power supply V21) to the lighting control circuit 21 and the control circuit 60 (S203 in FIG. 2).
Furthermore, in the second embodiment, the second converter circuit 50 supplies (outputs) the standby control power supply V21 to the PFC control circuit 11 as an operation voltage (S203 in FIG. 2).

  Even if the control circuit 60 is activated, unlike the first embodiment, it does not output a pre-lighting signal (FIG. 7 (e)). Therefore, the oscillation of the switching element Q2 is also stopped (FIG. 7 (f)). Further, the first control power supply Vcc1 is not output (FIG. 7 (g)).

(Explanation from time t2 to time t3)
Time t2 is a time when the control circuit 60 outputs a lighting control signal to the PFC control circuit 11.
When a predetermined time tp elapses after activation, the control circuit 60 outputs a lighting control signal (operation start signal) for driving (oscillating) the switching element Q1 to the PFC control circuit 11 at time t2 (see FIG. 6, S211b, FIG. 7 (h)). This lighting control signal is output, for example, at a predetermined time ts (for example, 1 to 3 seconds).
Since the PFC control circuit 11 is supplied with the second control power Vcc2 (standby control power V21) from the second converter circuit 50, when the lighting control signal is input, the PFC control circuit 11 causes the switching element Q1 to oscillate. Is started (S214 in FIG. 6, FIG. 7 (i)).

When the oscillation of the switching element Q1 is started, the rectified voltage rectified by the rectifier circuit DB is boosted from the voltage value Va to the voltage value Vb (S214 in FIG. 6, FIG. 7C).
That is, the PFC circuit 10 (PFC control circuit 11) generates the control voltage by the standby control power supply V21 being supplied as the operation voltage by the second converter circuit 50 and being subjected to generation control by the control circuit 60. .
The operation until the voltage is applied to the lamp connection detection circuit 30 via the lamp connection detection voltage generation circuit 22 and the control circuit 60 detects that the light source module 200 is removed is the same as in the first embodiment. It is.

(Description from time t3 to time t6)
Time t3 is a time at which the control circuit 60 stops outputting the lighting control signal.
When the control circuit 60 detects that the light source module 200 is removed, the control circuit 60 stops outputting the lighting control signal to the PFC control circuit 11. In other words, the control circuit 60 outputs an operation stop signal) to the PFC control circuit 11 (FIG. 7 (h)). Then, the oscillation of the switching element Q1 (operation of the PFC circuit 10) stops (FIG. 7 (i)).
Since the subsequent operation is the same as that at time t1, the description thereof is omitted. Time t5 is the same as time t1. Furthermore, time t4 is the same as time t2.
That is, the portion “A” in FIG. 7 is repeated.

(Explanation from time t6 to before time t7)
Time t6 is the time when the light source module 200 is mounted on the lighting device 100.
At time t6, the light source module 200 is connected to the lighting device 100 (S208 in FIG. 6, FIG. 7A).

(Description after time t7)
Time t7 is a time when the control circuit 60 outputs a lighting control signal to the PFC control circuit 11 after the light source module 200 is mounted.
At time t7, the control circuit 60 outputs a lighting control signal to the PFC control circuit 11 as described above (S211b in FIG. 6, FIG. 7 (h)).
Then, the control circuit 60 detects the voltage value Vr2 at the timing of monitoring the lamp connection detection signal at time t7 (FIG. 7 (j)), and determines that the light source module 200 is connected to the lighting device 100 (FIG. 6). The operation up to S210) is the same as in the first embodiment.
Since the subsequent operation is the same as that of the first embodiment, the description thereof is omitted.

(Effect of Embodiment 2)
In the lighting device 100 according to the second embodiment, since the control circuit 60 activates the PFC circuit 10 and then activates the lighting circuit 20, the control circuit 60 determines the connection state of the light source module 200 without activating the lighting circuit 20. Can be monitored.

  Further, since the PFC circuit 10 is activated without activating the lighting circuit 20, it is possible to eliminate power loss due to the operation of the lighting circuit 20.

  10 PFC circuit, 11 PFC control circuit, 20 lighting circuit, 21 lighting control circuit, 22 lamp connection detection voltage generation circuit, 30 lamp connection detection circuit, 40 first converter circuit, 50 second converter circuit, 60 control circuit, 100 lighting Device, 150 DC generator, 200 light source module, 800 lighting fixture, AC AC power supply, C1 capacitor, C2 capacitor, D1-D2, D4 diode, DB rectifier circuit, L1 inductor, L2 coil, L2p primary winding, L2s secondary Winding, LD light emitting diode, R1, R2 resistance, R3 detection resistance, R21, R22, R31 to R33 resistance, Rs connection resistance, Q1, Q2 switching element, Vcc1 first control power supply, Vcc2 second control power supply, Vdc DC power supply .

Claims (9)

In a lighting device in which a light source is detachably attached and turns on the light source when attached,
An AC voltage is supplied from an AC power source and is subjected to generation control, thereby generating a DC voltage having a voltage value based on the generation control from the AC voltage as a control voltage, and supplying the generated control voltage;
A lighting unit for lighting the light source at the time of mounting, wherein the control voltage is supplied by the supply unit, and the light source is turned on from the control voltage by receiving a lighting control for lighting the light source at the time of mounting. A lighting unit that generates a lighting voltage higher than the required voltage value;
A light source mounting detection unit that outputs a detection voltage of a voltage value different between when the light source is mounted and when the light source is removed by supplying the control voltage supplied by the supply unit;
A control unit that performs the generation control and the lighting control on the supply unit and the lighting unit, and intermittently performs the generation control on the supply unit, thereby intermittently controlling the control voltage. And when the control voltage is intermittently generated with respect to the supply unit, a control unit that stops the lighting control for the lighting unit,
The light source wearing detector is
By intermittently supplying the control voltage from the supply unit, intermittently outputting the detection voltage based on the control voltage supplied intermittently,
The controller is
The lighting device characterized by monitoring the detection voltage intermittently output by the light source mounting detection unit and determining whether or not the light source is mounted based on a voltage value of the detected detection voltage. The lighting device further includes:
The control voltage supplied to the lighting unit by the supply unit is supplied to the detection unit through supply from the supply unit to the lighting unit regardless of whether the lighting unit operates or not. The lighting device according to claim 1, further comprising a transmission unit that transmits the control voltage to the detection unit. The supply unit
When the generation control is stopped by the control unit, or when the operation voltage used for the generation operation of the control voltage is not supplied, the generation of the control voltage is stopped and the control voltage When generating is stopped, a DC voltage having a voltage value based on the AC voltage is generated as a power supply dependent voltage from the AC voltage supplied by the AC power supply, and the generated power supply dependent voltage is supplied.
The lighting device further includes:
When the control voltage is supplied by the supply unit, the control voltage is supplied as a supply voltage.When the power supply dependent voltage is supplied by the supply unit, the power supply dependent voltage is supplied as the supply voltage. A first voltage conversion unit that converts the supply voltage supplied by the supply unit into a first DC voltage and supplies the first DC voltage to the control unit;
The controller is
Operation of the first DC voltage supplied by the first voltage conversion unit, and monitoring result of the detection voltage output by the light source mounting detection unit intermittently when the control voltage is intermittently supplied When it is determined that the light source is mounted, the lighting control is performed on the lighting unit,
The lighting device further includes:
A second voltage converter that extracts the second DC voltage from the lighting voltage generated by the lighting unit by receiving the lighting control and supplies the second DC voltage to the first voltage converter;
The first voltage converter is
When the second DC voltage is supplied by the second voltage converter, the conversion from the supply voltage supplied by the supply to the first DC voltage is stopped, and the first DC voltage is stopped. Is switched to a third DC voltage based on the second DC voltage, and the switched third DC voltage is supplied to the control unit,
The controller is
3. The operation according to claim 1, wherein when the third DC voltage is supplied by the first voltage converter, the third DC voltage supplied by the first voltage converter is operated. Lighting device. The lighting part is
When the power supply dependent voltage is supplied, the power supply dependent voltage is supplied from the control section when the power supply dependent voltage is supplied. Generating the extinction maintaining voltage from the power supply dependent voltage by receiving,
The controller is
By performing the extinction maintenance control on the lighting unit, the extinction maintenance voltage is generated,
The second voltage converter is
The second DC voltage is extracted from the extinction maintaining voltage generated by the lighting unit, and the extracted second DC voltage is supplied to the supply unit as the operation voltage.
The supply unit
4. The control voltage is generated by the second voltage conversion unit supplying the second DC voltage as the operation voltage and receiving the generation control by the control unit. The lighting device described. The controller is
By intermittently performing the extinction maintenance control on the lighting part, the extinction maintenance voltage is generated intermittently,
The second voltage converter is
Having a capacitance element;
During the period when the extinguishing sustain voltage is generated by the lighting unit, the second DC voltage is extracted from the extinguishing sustain voltage, and the extracted second DC voltage is supplied to the supply unit as the operating voltage. And charging the capacitance element with at least a part of the electric charge based on the taken-out second DC voltage,
In a period in which the turn-off maintaining voltage is not generated by the lighting unit, the second DC voltage is generated from the charge charged in the capacitance element, and the generated second DC voltage is used as the operation voltage. The lighting device according to claim 4, wherein the operation voltage is continuously supplied to the supply unit by supplying the supply unit to the supply unit. The first voltage converter is
Supplying the first DC voltage as the operating voltage to the supply unit;
The supply unit
4. The control voltage is generated by supplying the first DC voltage as the operation voltage by the first voltage conversion unit and receiving the generation control by the control unit. The lighting device described. The first voltage converter is
The voltage value of the second DC voltage supplied by the second voltage conversion unit is converted or maintained and supplied as the third DC voltage. Lighting device. The lighting device is
The lighting device according to claim 1, wherein an LED is turned on as the light source.   A lighting apparatus comprising the lighting device according to claim 1.

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