JP5757127B2 - Light source lighting device and lighting device - Google Patents

Description

  The present invention relates to a light source lighting device and a lighting device for lighting, for example, an LED (light emitting diode) or an organic EL.

  When the LED unit connected to the lighting device is removed, the output voltage rises to detect that there is no load, the electric capacitor of the lighting device is discharged, and the output voltage decreases in a short time. Thus, there has been proposed a lighting device that prevents an overcurrent from flowing through the LED unit when the LED unit is connected again (see, for example, Patent Document 1).

  In addition, in a lighting device having an initial illumination correction function, an illumination device has been proposed that detects that a lamp has been removed and automatically resets the cumulative lighting time for initial illumination correction to an initial value (for example, Patent Documents). 2).

JP 2010-55824 A (see FIG. 2) JP 2000-315589 A (see FIG. 2)

  However, when it is determined that the LED unit has been removed by detecting that the output voltage has risen and no load is applied, the output voltage also increases when the LED of the LED unit fails to open. It was not possible to determine whether the LED unit was removed from the lighting device or whether the LED of the LED unit had an open failure.

  In addition, because of the function of detecting that the lamp has been removed, in the case of an apparatus having an initial illumination correction function, there is a problem that the accumulated time is reset even when the same lamp is removed.

  The present invention has been made to solve the above-described problems, and makes it possible to determine whether the lamp has been removed from the light source lighting device or whether the lamp has failed.

  The present invention provides a light source lighting device that determines whether the lamp has been removed from the light source lighting device or whether the lamp has failed.

Light source lighting apparatus for this invention, a plurality of LED are connected in series, the light source lighting device for lighting a lamp impedance is connected in parallel with the plurality of LED, the output terminal of said lamp is connected a constant current source circuit having, connected to said output terminal of the constant current source circuit, an output voltage detection circuit for detecting a voltage to be output to the output terminal, when the constant current source circuit is in a stopped state, the constant comprising a lamp sensing circuit for bypassing the current supply circuit is applied to the output terminal of the constant-current power supply circuit, a control circuit for controlling the pre Kijo current power supply circuit, wherein the control circuit includes determination and setting unit The setting unit is configured to set a first threshold value and a second threshold value lower than the first threshold value, and the determination unit determines that the voltage value of the output voltage detection circuit is the first threshold value. Exceeds the threshold The constant current power supply circuit is sometimes stopped, and when a predetermined period has elapsed since the constant current power supply circuit was stopped, the lamp is broken if the voltage value of the output voltage detection circuit is lower than the second threshold value. And determining that the lamp has been removed when the voltage value of the output voltage detection circuit is higher than the second threshold, and determining that the lamp has been removed, and then the voltage value of the output voltage detection circuit is when it becomes lower than the second threshold value, the lamp is determined to have been connected to the output terminal of the constant-current power supply circuit, Ru to initiate operation of the constant-current power supply circuit.

  According to the light source lighting device of the present invention, the output voltage of the light source lighting device is detected, and it is determined whether the lamp has been removed from the light source lighting device or the light source component constituting the lamp has failed due to the detected output voltage. can do.

1 is a perspective view showing a lighting fixture of Embodiment 1. FIG. It is sectional drawing which shows the cross section of the lighting fixture of FIG. FIG. 3 is a circuit diagram illustrating a circuit of the light source lighting device according to the first embodiment. It is a flowchart which shows operation | movement of the determination part of the light source lighting device of FIG. 4 is a waveform diagram showing an example of an output voltage of the light source lighting device of Embodiment 1. FIG. 6 is a flowchart illustrating an operation of a determination unit of the light source lighting device according to the second embodiment. FIG. 6 is a waveform diagram showing an example of an output voltage of the light source lighting device of the second embodiment. FIG. 6 is a waveform diagram showing an example of an output voltage of the light source lighting device of the second embodiment. 10 is a flowchart illustrating an operation of a determination unit of the light source lighting device according to the third embodiment. 6 is a waveform diagram illustrating an example of an output voltage of a light source lighting device according to Embodiment 3. FIG. 6 is a waveform diagram illustrating an example of an output voltage of a light source lighting device according to Embodiment 3. FIG. 10 is a flowchart illustrating an operation of a determination unit of the light source lighting device according to the fourth embodiment. 10 is a graph showing the relationship between the cumulative lighting time and the dimming rate in the fourth embodiment. 14 is a graph showing an example of a relationship between another accumulated lighting time and a dimming rate in the fourth embodiment.

Embodiment 1 FIG.
FIG. 1 is a perspective view showing the lighting fixture of Embodiment 1, and FIG. 2 is a cross-sectional view showing a cross section of the lighting fixture of FIG.

  The lighting fixture 100 includes a fixture main body 110, a light source lighting device 120 attached to the fixture main body 110, a socket 130 to which the lamp 200 is detachably mounted, and a wiring 140 that connects the socket 130 and the light source lighting device 120. .

  The lamp 200 includes a hollow straight tube cover 210, an LED module 220 housed in the straight tube cover 210, and a base provided at both ends of the straight tube cover 210 that is electrically connected to the LED module 220. Unit 230.

  The LED module 220 includes a rectangular substrate 221, 13 LEDs 222 mounted on the substrate 221 and connected in series, and a resistor 223 mounted on the substrate and connected in parallel to the 13 LEDs connected in series. And comprising. In addition, although the LED module 220 in this embodiment demonstrates the case provided with 13 LED222, the number of LED222 connected in series may be 12 or less, or 14 or more.

  FIG. 3 is a circuit diagram showing a circuit of the light source lighting device 120 of the lighting fixture of FIG.

  The light source lighting device 120 is supplied with an AC voltage AC and converted into a DC voltage, and a DC current output from the DC power circuit 121 is input to an LED module 220 connected via a socket 130. A constant current power supply circuit 122 that supplies a constant current, an output voltage detection circuit 123 that detects an output voltage output from the constant current power supply circuit 122, and a current that the constant current power supply circuit 122 supplies to the LED module 220 are detected. Output current detection circuit 124, a control circuit 125 that controls constant current power supply circuit 122 based on detection current and detection voltage detected by output current detection circuit 124 and output voltage detection circuit 123, and constant current power supply circuit 122. And the constant current power supply circuit 122 is bypassed when the constant current power supply circuit 122 is stopped. Comprising a lamp sensing circuit 126 supplying a current to module 220, a.

  The DC power supply circuit 121 is, for example, a step-up chopper circuit.

  The constant current power supply circuit 122 includes a MOS-FET 122a whose drain terminal is connected to the high potential side of the DC power supply circuit, a diode 122b whose cathode terminal is connected to the source terminal of the MOS-FET 122a, and the source of the MOS-FET 122a. An inductor 122c having one end connected to the terminal, a capacitor 122d connected to the other end of the inductor 122c, and a drive circuit 122e connected to the gate terminal of the MOS-FET 122a and turning on / off the MOS-FET 122a Prepare. The configuration of the constant current power supply circuit 122 of this embodiment is a so-called buck converter, but may be a boost converter, a flyback converter, a forward converter, or the like.

  The output voltage detection circuit 123 is connected between the output terminals of the constant current power supply circuit 122, and two resistors 123a and 123b are connected in series. From the connection point of these two resistors 123a and 123b, an output voltage detection signal proportional to the output voltage output from the constant current power supply circuit 122 (hereinafter, simply referred to as an output voltage detection signal is output from the constant current power supply circuit 122). Output voltage may be included). Although the output voltage detection circuit 123 in this embodiment will be described with respect to a case where two resistors 123a and 123b are connected in series, three or more resistors may be connected in series.

  The output current detection circuit 124 is connected between the low potential side of the constant current power supply circuit 122 and the LED module 220, and includes one resistor 124a. From the connection point between the resistor 124 a and the LED module 220, the constant current power supply circuit 122 outputs an output current detection signal corresponding to the output current supplied to the LED module 220.

  The control circuit 125 is, for example, a microcomputer. The control circuit 125 includes a determination unit 125a and a setting unit 125b. The setting unit 125b includes a first threshold (for example, a voltage value 3.32V corresponding to the voltage 110V at the output terminal of the constant current power supply circuit 122), and a second threshold (for example, a value lower than the first threshold). A voltage value 550 mV corresponding to a voltage 18 V at the output terminal of the constant current power supply circuit 122 and a current reference value (for example, a voltage value 700 mV corresponding to a current 350 mA flowing through the LED module 220) are set. The determination unit 125a compares the output voltage detection signal (the output voltage of the constant current power supply circuit 122) input to the control circuit 125 with the first threshold value and the second threshold value, and also outputs the input to the control circuit 125. The current detection signal and the current reference value are compared, and an oscillation control signal is output to the constant current power supply circuit 122 (drive circuit 122e) based on the comparison result.

  The lamp detection circuit 126 includes a resistor 126a connected in parallel between the drain and source of the MOS-FET 122a. The resistor 126a is configured to output the DC current output from the DC power supply circuit 121 via the inductor 122c when the constant current power supply circuit 122 is stopped (the MOS-FET 122a is kept off). 123 is a bypass circuit for passing a current through 123.

  Next, the circuit operation of the light source lighting device 120 and the operation of the control circuit 125 (determination unit 125a) will be described.

  4 is a flowchart showing the operation of the control circuit of the light source lighting device of FIG. 3, FIG. 5 is a waveform diagram showing an example of the output voltage of the light source lighting device, and FIG. FIG. 5B is a waveform diagram illustrating an example of a change in the output voltage of the light source lighting device when an optical component to be opened fails, and FIG. 5B is an example of a change in the output voltage of the light source lighting device when the lamp is removed. FIG. 5C is a waveform diagram illustrating an example of a change in the output voltage of the light source lighting device when the lamp is attached in a short time after the lamp is removed.

  First, when an AC voltage AC (for example, AC voltage 100V to 242V) is supplied to the light source lighting device 120, the DC power supply circuit 121 boosts and outputs a smoothed smoothed voltage (for example, DC voltage 410V). The smoothed voltage smoothed by the DC power supply circuit 121 is input to the constant current power supply circuit 122, but the constant current power supply circuit 122 is not operating and the MOS-FET 122a is in the off state.

  Therefore, a current flows through a loop of the inductor 4 → the output voltage detection circuit 123 and the resistor 223 of the LED module 220 → the output current detection circuit 124 through the lamp detection circuit 126 connected in parallel to the MOS-FET 122a. The control circuit 125 (determination unit 125a) determines whether an output voltage detection signal is input from the output voltage detection circuit 123 to the control circuit 125 (step 1).

  At this time, the output voltage detection signal output from the output voltage detection circuit 123 includes a lamp detection circuit 126, resistors 123a and 123b of the output voltage detection circuit 123, and an LED module connected in parallel to the output voltage detection circuit 123. Since the voltage is divided by the resistor 223 of 220, the signal has a voltage level lower than the second threshold value.

  Note that current also flows through the output current detection circuit 124 (resistor 124a), but the resistance value r5 (for example, 2Ω) of the resistor 124a constituting the output current detection circuit 124 is the resistance 126a, the resistor 123a, the resistor 123b, and the resistor 223. It is a value of 1/1000 or less with respect to the resistance values r1 to r4 (if the resistance values are different, the smallest resistance value among them, for example, 5.15 kΩ), and is almost equal to the voltage level of the output voltage detection signal 124. Since it has no effect, it will not be considered here.

  As described above, when the output voltage detection signal (voltage level lower than the second threshold) is input to the control circuit 125, the determination unit 125a determines that the lamp 200 is connected to the light source lighting device 120. Is determined, and an oscillation control signal is output to the drive circuit 122e (step 2).

  When the oscillation control signal is input, the drive circuit 122e starts on / off control (hereinafter referred to as switching control) of the MOS-FET 122a. When the MOS-FET 122a is subjected to switching control, a current flows through a loop of the inductor 122c → the LED 222 → the output current detection circuit 124, and the LED 222 is turned on.

  The determination unit 125a determines whether the output voltage detection signal input to the control circuit 125 has reached (or exceeded) the first threshold (step 3), and the output voltage detection signal is the first When determining that the threshold value has not been reached (exceeded), the determination unit 125a determines whether or not the voltage level of the output current detection signal output from the output current detection circuit 124 is equal to the current reference value (step 4). ) And outputs an oscillation control signal (a signal for increasing the output current or decreasing the output current) based on the determination result to the drive circuit 122e (step 5), and the drive circuit 122e has a duty for switching control of the MOS-FET 122a. The constant current power supply circuit 122 is controlled to output a constant current by changing the ratio.

  The determination part 125a repeats the loop which returns to the process of step 3 after performing the process of step 4 or step 5, and the light source lighting device 120 makes LED222 light.

  Next, the operation of the light source lighting device 120 when the LED 222 has an open failure while the light source lighting device 120 is lighting the LED 222 will be described.

  In the lamp 200, 13 LEDs 222 are connected in series, and when an open failure occurs in at least one of the LEDs 222 connected in series, a current does not flow through the normal LEDs 222 connected in series, and the resistor 223. Only the current flowing through the

  Therefore, the constant current power supply circuit 122 increases the output voltage so that the current flowing through the resistor 223 becomes the target current.

  However, since no current flows through the LEDs 222 connected in series, the current flowing through the resistor 223 does not change, and the constant current power supply circuit 122 continues to increase the output voltage (see FIG. 5A, time t1). .

  When the control circuit 125 determines that the output voltage of the constant current power supply circuit 122 detected by the output voltage detection circuit 123 exceeds the first threshold (step 3), the control circuit 125 generates a stop signal for stopping the operation of the constant current power supply circuit 122. Output to the drive circuit 122e (step 6). When this stop signal is input, the drive circuit 122e stops the oscillation of the MOS-FET 122a.

  Therefore, the electric charge of the capacitor 122d of the constant current power supply circuit 122 is discharged through the output voltage detection circuit 123 and other circuits, and the capacitor voltage of the capacitor 122d decreases (see time t1 to t2 in FIG. 5A). .

  The determination unit 125a starts counting the time after outputting the stop signal (step 7), and determines whether the predetermined time T0 has elapsed (step 8). The determination unit 125a repeats Step 7 and Step 8 until the counting time reaches the predetermined time T0.

  In this state, when the predetermined time T0 has elapsed, the DC voltage output from the DC power supply circuit 121 is divided by the lamp detection circuit 126, the output voltage detection circuit 123, and the resistor 223 connected in parallel to the output voltage detection circuit 123. The output voltage is detected from the output voltage detection circuit 123.

  The detected divided voltage is lower than the second threshold value, and the control circuit 125 can determine that the lamp 200 has failed (the LED 222 has failed to open) (steps 9 and 10). The state where the operation of the constant current power supply circuit 122 is stopped can be maintained.

  Next, the operation of the light source lighting device 120 when the lamp 200 is removed from the light source lighting device 120 while the light source lighting device 120 lights the LED 122 will be described.

  In the constant current power supply circuit 122, when the lamp 200 is removed, no current flows through the output current detection circuit 124. Therefore, the output power output from the constant current power supply circuit 122 is such that the target current flows through the output current detection circuit 124. Control to increase (step 5), specifically, the on-duty ratio at which the drive circuit 122e switches the MOS-FET 122a is lengthened to increase the output power. At that time, since the lamp 200 is removed, no current flows, so the output voltage rises (see FIG. 5B, time t1).

  The output voltage detection circuit 123 detects this output voltage, and when the determination unit 125a determines that the output voltage exceeds the first threshold voltage (step 3), the drive circuit 122e receives an oscillation stop signal (step 6). And the drive circuit 122e stops switching of the MOS-FET 122a.

  Therefore, the electric charge charged in the capacitor 122d of the constant current power supply circuit 122 is gradually discharged through the output voltage detection circuit 123 and other circuits (see FIG. 5B, time t1 to t2).

  The determination unit 125a starts counting the time after outputting the stop signal (step 7), and determines whether the predetermined time T0 has elapsed (step 8). The determination unit 125a repeats Step 7 and Step 8 until the counting time reaches the predetermined time T0.

  At this time, the DC voltage output from the DC power supply circuit 121 is divided by the lamp detection circuit 126 and the output voltage detection circuit 123, and the voltage output from the output voltage detection circuit 123 is output from the lamp detection circuit 126. The divided voltage depends on the voltage divided by the voltage detection circuit 123 (see FIG. 5B, time t2).

  The divided voltage is greater than the second threshold value, and the determination unit 125a compares the divided voltage with the second threshold value (step 9). The determination unit 125a indicates that the lamp 200 is not abnormal. It can be determined that the light source lighting device 120 is disconnected (step 11).

  From this state, when the lamp 200 is connected to the light source lighting device 120, the voltage output from the DC power supply circuit 121 is connected in parallel to the lamp detection circuit 126, the output voltage detection circuit 123, and the output voltage detection circuit 123. The divided voltage is divided by the resistor 223. Thus, since the resistor 223 is connected in parallel to the output voltage detection circuit 123, the impedance is lowered, and the voltage output from the output voltage detection circuit 123 is also reduced.

  Therefore, whether the output voltage of the constant current power supply circuit 122 (the output voltage detection signal output from the output voltage detection circuit 123) is less than the second threshold after the predetermined time T0 has elapsed after the lamp 200 is removed (the lamp The determination unit 125a determines whether the lamp 200 has been removed (step 11).

  From this state, when the lamp 200 is connected to the light source lighting device 120, the voltage output from the DC power supply circuit 121 is connected in parallel to the lamp detection circuit 126, the output voltage detection circuit 123, and the output voltage detection circuit 123. A divided voltage obtained by dividing the resistor 223 is obtained. Since the resistor 223 is connected in parallel to the output voltage detection circuit 123, the impedance is lowered, and the voltage output from the output voltage detection circuit 123 is also reduced.

  Therefore, the determination unit 125a determines whether the output voltage detection signal of the output voltage detection circuit 123 is less than the second threshold value (whether the lamp 200 is mounted) (step 12), and the output voltage detection signal is If it is less than the threshold value, the process returns to step 2.

  Therefore, when the lamp 200 is removed, the operation of the constant current power supply circuit 122 can be maintained in a stopped state, and the lamp 200 is removed for the cleaning of the lamp 200 and the lamp 200 is attached again. When it is done, the lamp 200 can be turned on again.

  If the lamp 200 is mounted again after the predetermined time T0 has elapsed after the lamp 200 is removed (see time t3 in FIG. 5 (c)), the lamp 200 is removed when the predetermined time T0 has elapsed. Since it is in the mounted state, the output voltage output from the DC power supply circuit 121 is supplied to the lamp detection circuit 126, the output voltage detection circuit 123, and the output voltage detection circuit 123 as shown in FIG. The voltage divided by the resistor 223 connected in parallel is detected from the output voltage detection circuit 123. For this reason, when the lamp 200 is detached and attached for a short time (during the predetermined time T0), the determination unit 125a may determine that the lamp 200 has failed (the diode has an open failure). However, the predetermined time T0 is about 500 ms. Therefore, when removing the lamp 200 by cleaning or the like, the lamp 200 is removed from the light source lighting device 120 for a predetermined time T0 or more, so there is no practical problem.

  If the determination unit 125a determines that the output voltage detection signal has exceeded the second threshold value after determining that the lamp 200 has failed (step 10), the process proceeds from step 10 to step 11, and the new lamp 200 is obtained. When the replacement is performed, the light source lighting device 120 can turn on the new lamp 200.

  Further, when the DC power supply circuit 121 is configured by a boost chopper circuit, the output voltage of the boost chopper circuit can be made constant regardless of fluctuations in the AC voltage AC. In particular, when the operation of the constant current power supply circuit 122 is stopped, if the step-up chopper circuit is operated, the output voltage detection signal output from the output voltage detection circuit 123 is kept constant even if the AC voltage AC fluctuates. Therefore, the determination unit 125a can determine whether the lamp 200 has failed or whether the lamp 200 has been removed from the light source lighting device 120.

Embodiment 2. FIG.
In the present embodiment, the determination accuracy determined by the control circuit (determination unit) of the first embodiment is further increased. In the present embodiment, since the configurations of the lighting fixture and the light source lighting device are the same as those in the first embodiment, description thereof will be omitted, and the operation of a control circuit (determination unit) different from that in the first embodiment will be described. In the present embodiment, the same configurations and operations as those of the first embodiment are denoted by the same reference numerals and description thereof may be omitted.

  FIG. 6 is a flowchart showing the operation of the control circuit. FIG. 7 is a waveform diagram showing an example of the output voltage of the light source lighting device, and FIG. 7A shows an example of a change in the output voltage of the light source lighting device when an optical component constituting the lamp has an open failure. FIG. 7B is a waveform diagram showing an example of a change in the output voltage of the light source lighting device when the lamp is removed, and FIG. 7C is a short time after the lamp is removed. FIG. 7D is a waveform diagram showing an example of a change in the output voltage of the light source lighting device when the lamp is attached, and FIG. 7D is an output voltage of the light source lighting device when the lamp is attached in a short time after the lamp is removed. It is a wave form diagram which shows another example of a change of.

First, the operation until the light source lighting circuit 120 lights the LED 222 will be described.
When the AC voltage AC is supplied to the light source lighting device 120, the DC power supply circuit 121 operates and the constant current power supply circuit 122 enters an operation stop state as in the first embodiment. At this time, a current flows through the lamp detection circuit 126 in a loop of the inductor 122c → the output voltage detection circuit 123 and the resistor 223 of the LED module 220 → the output current detection circuit 124.

  The determination unit 125a sets the variable N to 0 (step S13), and determines whether the output voltage detection signal is input from the output voltage detection circuit 123 to the control circuit 125 (step 1).

  If the determination unit 125a determines that the output voltage detection signal is lower than the second threshold as a result of comparing the output voltage detection signal and the second threshold in Step 1, the determination unit 125a outputs a lighting control signal to the drive circuit 122e (Step S1). 2) Do.

  When this lighting control signal is input, the drive circuit 122e controls the oscillation of the MOS-FET 122a of the constant current power supply circuit 122 and lights the LED 222 of the LED module 220. At this time, the output voltage detection circuit 123 detects the output voltage of the constant current power supply circuit 122 and outputs an output voltage detection signal based on the detected output. The output voltage detection signal is input to the control circuit 125, and the determination unit 125a compares the input output voltage detection signal with the first threshold value (step 3). In step 3, when the determination unit 125a determines that the first threshold is not reached (does not exceed the first threshold), the output current detection signal output from the output current detection circuit 124, the current reference value, Are compared (step 4), and if the output current detection signal is not equal to the current reference value, a lighting control signal instructing current increase or current decrease is output (step 5) and then the process proceeds to step 3 to detect the output current. If the signal is equal to the current reference value, go to step 3.

  Thus, the control circuit 125 and the determination unit 125a operate, and the light source lighting device 120 lights the LED 222.

  Next, the operation of the light source lighting device 120 when the LED 222 has an open failure while the light source lighting device 120 is lighting the LED 222 will be described.

  In the lamp 200, 13 LEDs 222 are connected in series, and when an open failure occurs in at least one of the LEDs 222 connected in series, a current does not flow through the normal LEDs 222 connected in series, and the resistor 223. Only the current flowing through the

  Therefore, the constant current power supply circuit 122 increases the output voltage so that the current flowing through the resistor 223 becomes the target current.

  However, since no current flows through the LEDs 222 connected in series, the current flowing through the resistor 223 does not change, and the constant current power supply circuit 122 continues to increase the output voltage (see FIG. 7A, time t1). .

  When the determination unit 125a determines that the output voltage of the constant current power supply circuit 122 detected by the output voltage detection circuit 123 has reached (or exceeded) the first threshold value (step 3), the operation of the constant current power supply circuit 122 is performed. Is output to the drive circuit 122e (step 6). When this stop signal is input, the drive circuit 122e stops the oscillation of the MOS-FET 122a.

  Therefore, the electric charge of the capacitor 122d of the constant current power supply circuit 122 is discharged through the output voltage detection circuit 123 and other circuits, and the capacitor voltage of the capacitor 122d decreases (see time t1 to t2 in FIG. 7A).

  Next, the determination unit 125a determines whether the variable N is 1 (step 15). If the variable N is not 1, the determination unit 125 adds 1 to the variable N (step 16). In addition, the determination unit 125 counts time (step 7) and determines whether the first predetermined time T1 has elapsed (step 8). Thereafter, the determination unit 125a determines that the first predetermined time T1 has elapsed. Step 7 and Step 8 are repeated until the determination unit 125a determines that the first predetermined time T1 has elapsed, it is determined whether the output voltage detection signal input to the control circuit 125 is lower than the second threshold ( Step 9).

  When the determination unit 125a determines that the output voltage detection signal is lower than the second threshold value (less than the second threshold value), the determination unit 125a outputs a lighting control signal to the drive circuit 122e, and the constant current The power supply circuit 122 is operated (step 17), and counting of the time after the lighting control signal is output (step 18) is started.

  The determination unit 125a determines whether or not the output voltage detection signal input to the control circuit 122e has reached the first threshold (step 19). If the output voltage detection signal has reached the first threshold, step Returning to 6, when the output voltage detection signal does not reach the first threshold value, it is determined whether the second predetermined time T2 has elapsed (step 20). Steps 18, 19 and 20 are repeated until the second predetermined time T2 elapses when the output voltage detection signal does not reach the first threshold value until the second predetermined time T2 elapses. When the second predetermined time T2 elapses, the variable N is set to 0 (step 21), and the process returns to step 3.

  If the LED 222 has an open failure, the output voltage output from the constant current power supply circuit 120 rises again, and the output voltage detection signal output from the output voltage detection circuit 123 reaches the first threshold value. The determination unit 125a operates in the sequence of step 6 → step 15. At this time, in step 15, since the determination unit 125a determines that the variable N is 1, it determines that the lamp 200 is in failure (step 10).

  Next, the operation of the light source lighting device 120 when the lamp 200 is removed from the light source lighting device 120 while the light source lighting device 120 lights the LED 222 will be described.

  In the constant current power supply circuit 122, when the lamp 200 is removed, no current flows through the output current detection circuit 124. Therefore, the output power output from the constant current power supply circuit 122 is such that the target current flows through the output current detection circuit 124. Control to increase (step 5), specifically, the on-duty ratio at which the drive circuit 122e switches the MOS-FET 122a is lengthened to increase the output power. At this time, since the lamp 200 is removed, no current flows through the LED module 220, so that the output voltage rises. (See FIG. 7A, time t1.)

  The output voltage detection circuit 123 detects the output voltage. When the determination unit 125a determines that the output voltage exceeds the first threshold (step 3), the determination unit 125a sends an oscillation stop signal to the drive circuit 122e. (Step 6) is output, and the drive circuit 122e stops the switching of the MOS-FET 122a.

  Therefore, the electric charge charged in the capacitor 122d of the constant current power supply circuit 122 is gradually discharged through the output voltage detection circuit 123 and other circuits (see FIG. 7B, time t1 to t2).

  Next, the determination unit 125a determines whether the variable N is 1 (step 15). If the variable N is not 1, the determination unit 125 adds 1 to the variable N (step 16). Further, the determination unit 125a starts counting the time after outputting the stop signal (step 7), and determines whether or not the counting time has passed the first predetermined time T1 (step 8). To do. The determination unit 125a repeats Step 7 and Step 8 until the counting time reaches the first predetermined time T1.

  At this time, the DC voltage output from the DC power supply circuit 121 is divided by the lamp detection circuit 126 and the output voltage detection circuit 123, and the voltage output from the output voltage detection circuit 123 is output from the lamp detection circuit 126. The divided voltage depends on the voltage divided by the voltage detection circuit 123. This divided voltage is greater than the second threshold. (See FIG. 7B, time t2.)

  The determination unit 125 compares the second threshold with the divided voltage (step 9), and the determination unit 125a determines that the lamp 200 is not abnormal but the lamp 200 is removed (step 11). it can.

  From this state, when the lamp 200 is connected to the light source lighting device 120, the voltage output from the DC power supply circuit 121 is connected in parallel to the lamp detection circuit 126, the output voltage detection circuit 123, and the output voltage detection circuit 123. A divided voltage obtained by dividing the resistor 223 is obtained. Since the resistor 223 is connected in parallel to the output voltage detection circuit 123, the impedance is lowered, and the voltage output from the output voltage detection circuit 123 is also reduced (see FIGS. 7C and 7D and time t3). To do.

  Therefore, the determination unit 125a determines whether the output voltage detection signal of the output voltage detection circuit 123 is less than the second threshold value (whether the lamp 200 is mounted) (step 12), and the output voltage detection signal is When the value is less than the threshold value, a lighting control signal is output to the drive circuit 122e (step 22), the variable N is set to 0 (step 23), and the process returns to step 3.

  Therefore, when the lamp 200 is removed for cleaning the lamp 200, the operation of the constant current power supply circuit 122 can be maintained in a stopped state, the cleaning of the lamp 200 is completed, and the lamp 200 is again performed. When is mounted, the lamp 200 can be turned on again.

  In this embodiment, when the light source lighting device 120 is disconnected from the lamp 200 and a failure of the lamp 200 is detected, the determination unit 125a is disconnected from the lamp 200 until the failure of the lamp 200 is determined. Since the operation stop at 122 is set to be twice (re-starting operation is started once), the case where the value of the variable N determined by the determination unit 125a is 1 in step 16 has been described. As shown in FIG. 8, the number of operation stop and re-operation start may be increased. In this case, the value of the variable N determined by the determination unit 125 a in step 16 may be other than 1.

  If the determination unit 125a determines that the output voltage detection signal has exceeded the second threshold value after determining that the lamp 200 has failed (step 10), the process proceeds from step 10 to step 11, and the new lamp 200 is obtained. When the replacement is performed, the light source lighting device 120 can turn on the new lamp 200.

  Further, when the DC power supply circuit 121 is configured by a boost chopper circuit, the output voltage of the boost chopper circuit can be made constant regardless of fluctuations in the AC voltage AC. In particular, when the operation of the constant current power supply circuit 122 is stopped, if the step-up chopper circuit is operated, the output voltage detection signal output from the output voltage detection circuit 123 is kept constant even if the AC voltage AC fluctuates. Therefore, the determination unit 125a can determine whether the lamp 200 has failed or whether the lamp 200 has been removed from the light source lighting device 120.

Embodiment 3 FIG.
In the present embodiment, the operation of the control circuit (determination unit) of the second embodiment is different. In the present embodiment, the configurations of the lighting fixture and the light source lighting device are the same as those in the first embodiment, and thus description thereof will be omitted. The operation of the control circuit 125 different from those in the first and second embodiments will be described. In the present embodiment, the same operations as those in the first embodiment and the second embodiment may be denoted by the same reference numerals and description thereof may be omitted.

Operations of the light source lighting device and the determination unit in the present embodiment will be described.
Since the operation of the determination unit until the light source lighting device turns on the LED is the same as that of the determination unit of the second embodiment, a description thereof will be omitted, and when the light source lighting device is lighting the LED, the lamp is moved from the light source lighting device. The case where it is removed will be described.

  FIG. 9 is a flowchart showing the operation of the control circuit. FIG. 10 is a waveform diagram illustrating an example of the output voltage of the light source lighting device, and FIG. 10A illustrates an example of a change in the output voltage of the light source lighting device when an optical component constituting the lamp has an open failure. FIG. 10B is a waveform diagram showing an example of a change in the output voltage of the light source lighting device when the lamp is removed, and FIG. 10C is a short time after the lamp is removed. It is a wave form diagram which shows an example of the change of the output voltage of the light source lighting device at the time of attaching a lamp | ramp.

  Since the operation of the determination unit 125a until the light source lighting device 120 lights the LED 222 is the same as that of the second embodiment, the description thereof is omitted.

  Next, the operation of the light source lighting device 120 (determination unit 125a) when the LED 222 has an open failure while the light source lighting circuit 120 is lighting the lamp 200 will be described.

  When the LED 222 is in an open failure while the light source lighting device 120 is lighting the lamp 200, the determination unit 125a outputs a lighting control signal for increasing the current to the drive circuit 122e in Step 4, while the LED 222 has an open failure. Since no current flows through the LED 222, the output voltage output from the constant current power supply circuit 122 increases. The determination unit 125a determines whether the output voltage has reached the first threshold (step 3), and determines that the output voltage has reached (or exceeded) the first threshold, the determination unit 125a is driven A stop signal is output to the circuit 122e (step 6). The determination unit 125a counts the time since the stop signal is output to the drive circuit 122e (step 7), determines whether the first predetermined time T1 has elapsed (step 8), and the first predetermined time. Steps 7 and 8 are repeated until T1 has elapsed.

  When the first predetermined time T1 has elapsed, the determination unit 125a determines whether the variable N is 1 (step 24), and when determining that the variable N is not 1, adds 1 to the variable N (step 25). Then, it is determined whether the output voltage detection signal is less than the second threshold value (step 26). When the output voltage detection signal is less than the second threshold value, the lighting control signal is output to the drive circuit 122e (step 27), and the time after the lighting control signal is output (second predetermined time T2) is counted. (Step 17). In step 17, after counting time, it is determined whether the output voltage detection signal has reached (or exceeded) the first threshold value (step 28), and the output voltage detection signal has reached the first threshold value. When it is determined that the second predetermined time T2 has elapsed (step 18), the variable N is set to 0 when the second predetermined time has elapsed. Returning to step 3 in (step 29) and returning to step 17 when determining in step 18 that the second predetermined time has not elapsed.

  If it is determined in step 28 that the output voltage detection signal has reached (or exceeded) the first threshold value, a stop signal is output to the drive circuit 122e (step 6), and step 7 → step 8 are repeated. When the first predetermined time T1 elapses, it is determined whether the variable N is 1 (step 19). In step 24, when the variable N is 1, it is determined whether the output voltage detection signal is less than the second threshold (step 9), and when it is determined that the output voltage detection signal is less than the second threshold. The lamp 200 is determined to be out of order (step 10).

  Next, operations of the light source lighting device 120, the control circuit 125, and the determination unit 125a when the lamp 200 is removed from the light source lighting device 120 while the light source lighting device 120 lights the LED 222 will be described.

  If the lamp 200 is removed from the light source lighting device 120 when the light source lighting device 120 lights the LED 222, it is determined in step 4 that the output current detection signal is not equal to the current reference value, and the determination unit 125a. A lighting control signal for increasing the current is output to the drive circuit 122e (step 5). At this time, since the lamp 200 is not connected, the output voltage output from the constant current power supply circuit 122 increases (see time t1 in FIGS. 10B and 10C). The determination unit 125a determines whether the output voltage has reached the first threshold (step 3), and determines that the output voltage has reached (or exceeded) the first threshold, the determination unit 125a is driven A stop signal is output to the circuit 122e (step 6). The determination unit 125a counts the time since the stop signal is output to the drive circuit 122e (step 7), determines whether the first predetermined time T1 has elapsed (step 8), and the first predetermined time. Steps 7 and 8 are repeated until T1 has elapsed.

  When the first predetermined time T1 elapses, the determination unit 125a determines whether the variable N is 1 (step 24), and when determining that the variable N is not 1, adds 1 to the variable N (step 25). Then, it is determined whether the output voltage detection signal is less than the second threshold (step 26). If the determination unit 125a determines in step 26 that the output voltage detection signal is not less than the second threshold, it is determined that the lamp 200 has been removed (step 11), and the output voltage detection signal is less than the second threshold. (Step 12), and the process is repeated until the output voltage detection signal becomes less than the second threshold value.

  In step 12, when the output voltage detection signal becomes less than the second threshold (the lamp 200 is mounted), a lighting control signal is output to the drive circuit 122e (step 30), and the variable N is set to 0 (step 31). Then, return to Step 3.

  Therefore, when the lamp 200 is removed, the constant current power supply circuit 122 is stopped, and when the lamp 200 is mounted again, the constant current power supply circuit 122 can be operated to light the lamp 200.

In this embodiment, when the light source lighting device 120 is disconnected from the lamp 200 and a failure of the lamp 200 is detected, the determination unit 125a is disconnected from the lamp 200 until the failure of the lamp 200 is determined. Since the operation stop at 122 is set to be twice (re-operation start is once), the case where the value of the variable N determined by the determination unit 125a is 1 in step 24 has been described. 11, the number of times of operation stop and re-operation start may be increased. In this case, the value of the variable N determined by the determination unit 125a in step 24 may be other than 1.

  If the determination unit 125a determines that the output voltage detection signal has exceeded the second threshold value after determining that the lamp 200 has failed (step 10), the process proceeds from step 10 to step 11, and the new lamp 200 is obtained. When the replacement is performed, the light source lighting device 120 can turn on the new lamp 200.

  Further, when the DC power supply circuit 121 is configured by a boost chopper circuit, the output voltage of the boost chopper circuit can be made constant regardless of fluctuations in the AC voltage AC. In particular, when the operation of the constant current power supply circuit 122 is stopped, if the step-up chopper circuit is operated, the output voltage detection signal output from the output voltage detection circuit 123 is kept constant even if the AC voltage AC fluctuates. Therefore, the determination unit 125a can determine whether the lamp 200 has failed or whether the lamp 200 has been removed from the light source lighting device 120.

Embodiment 4 FIG.
In the present embodiment, the light source lighting device of the first embodiment is provided with an initial illuminance correction function.

  In the present embodiment, the same configuration and operation as the configuration of the light source lighting device of Embodiment 1 and the operation of the determination unit are denoted by the same reference numerals, description thereof is omitted, and the configuration and operation different from Embodiment 1 are described. To do.

First, the function of initial illuminance correction will be described.
When many light sources such as the LED 222 are lit with the same power (current), the luminous flux is the largest when it is new, and the luminous flux gradually decreases as the lighting time elapses. When the luminaire 100 is installed on the ceiling of a living room or the like, the illuminance on the desk surface is the lifetime of the light source (generally, when the luminous flux when the light source is new is 100%, when the luminous flux decreases to 70%, the lifetime of the light source is referred to. ), The type and number of lighting fixtures 100 to be installed are determined, so that the initial value of the light source (light flux of a new lamp) has a desk top illuminance higher than the set value. Therefore, if the control is performed so that the power (current) supplied to the light source is adjusted so that the luminous flux at the life of the light source is almost constant from the time of the new lamp, the illuminance on the desk surface also changes from the new light source to the end of its life. It can be almost constant. Such control is referred to as initial illuminance correction in which the light flux from when the light source is new to the lifetime of the light source is substantially constant.

  The control circuit 125 in this embodiment further includes a storage unit 125c in addition to the control circuit 125 in Embodiment 1.

  The setting unit 125b includes a first threshold (for example, a voltage value 3.32V corresponding to the voltage 110V at the output terminal of the constant current power supply circuit 122), and a second threshold (for example, a value lower than the first threshold). A voltage value 550 mV corresponding to a voltage 18 V at the output terminal of the constant current power supply circuit 122 and a current reference value (for example, a voltage value 700 mV corresponding to a current 350 mA flowing through the LED module 220) are set.

  The determination unit 125a compares the output voltage detection signal input to the control circuit 125 with the first threshold value and the second threshold value, and compares the output current detection signal input to the control circuit 125 with the current reference value. Then, based on the comparison result, an oscillation control signal is output to the constant current power supply circuit 122 (drive circuit 122e).

  The storage unit 125c has a relationship between the cumulative lighting time for lighting the lamp 200, the lifetime of the lamp 200, the lifetime of the lamp 200, and the cumulative lighting time for dimming and lighting the lamp 200 based on the lifetime of the lamp 200. The table etc. which show are memorize | stored.

Next, operations of the light source lighting device 120 and the control circuit 125 will be described.
First, an operation for turning on the LED 222 will be described.
When the power is turned on, the control circuit 125 operates, the determination unit 125a reads the accumulated lighting time stored in the storage unit 125c (step 32), and the output voltage detection signal is output from the output voltage detection circuit 123 to the control circuit 125. Is determined (step 1), and when it is determined that the output voltage detection signal 123 is input, a lighting control signal is output to the drive circuit 122e (step 2).

  Next, the determination unit 125a determines whether the output voltage detection signal has reached the first threshold (step 3), and counts the cumulative lighting time when the output voltage detection signal has not reached the first threshold ( Then, a current reference value corresponding to the counted cumulative lighting time is generated (step 34), and the process proceeds to step 4. The reference current value is set to a small value so that the current flowing through the LED 222 is reduced when the lamp 200 is new and the cumulative lighting time is short, and the current is gradually increased so that the current flowing through the LED 222 increases as the cumulative lighting time increases. And It should be noted that the current reference value has a maximum value for a time (for example, 40,000 hours) when the lamp 200 reaches the end of its life.

  Thereafter, the determination unit 125a repeats Step 4 → Step 5 → Step 3 → Step 33 → Step 34 to keep the lamp 200 on.

  Next, an operation when the light source lighting device 120 detects a failure of the lamp 200 (open failure of the LED 222) will be described.

  The determination unit 125a performs the operation of step 3 → step 6 → step 7 → step 8 → step 9 to determine the failure of the lamp 200, and then initialize the accumulated lighting time by returning it to the initial value (step 35). .

  An example of this operation is shown in FIG. FIG. 13 is a graph showing the relationship between the cumulative lighting time and the dimming rate when performing initial illumination correction. This graph shows that the dimming rate is gradually increased to compensate for the light beam deterioration of the lamp 200 according to the cumulative lighting time. When the LED 222 fails to open at time ta after starting to turn on the new lamp (time to), the initial value (time to) is changed to the cumulative lighting time. Next, after the lamp 200 is replaced (time to), the initial value (time to) is also changed to the cumulative lighting time when the LED 222 has an open failure at time tb.

  As described above, the determination unit 125a initializes the cumulative lighting time after determining the failure of the lamp 200. Therefore, when the new lamp (normal lamp) is attached after the failed lamp 200 is removed, the determination unit 125a automatically initializes the cumulative lighting time. The lamp 200 can be turned on from a state where the initial luminous flux is suppressed.

  In the present embodiment, the case where the light source lighting device 120 of the first embodiment has the function of correcting the initial illuminance has been described. However, the light source lighting device 120 of the second embodiment or the third embodiment has the initial illuminance correction. In this case as well, in this case, the operation of the determination unit 125a counts the accumulated lighting time when the LED 222 is lit when the LED 222 is lit, and this cumulative lighting The brightness of the LED 222 is increased according to the time, and when the failure of the lamp 200 is detected, the cumulative lighting time is changed to the initial value.

  In the second embodiment and the third embodiment, the detection accuracy of the failure of the lamp 200 is further increased. Therefore, when the lamp 200 is removed by cleaning the lamp 200 or the like, the determination unit 125a erroneously causes the failure of the lamp 200. And the risk of changing the cumulative lighting time to the initial value is reduced.

  Further, in the present embodiment, the case where the determination unit 125a determines the failure of the lamp 200 has been described with respect to the case where the cumulative lighting time is changed to the initial value. However, when the determination unit 125a determines the failure of the lamp 200, You may make it change into the correction | amendment initial value according to the total use accumulation lighting time of the lighting fixture 100 including replacement | exchange of lamp | ramp 200 or accumulation lighting time.

  This is because, even when the lamp 200 is replaced, optical components such as a reflector and a lens constituting a lighting fixture that cannot be replaced or cannot be replaced also deteriorate the optical properties. Therefore, the deterioration factor of the optical properties is reflected in the corrected initial value. Is. More specifically, when the cumulative lighting time is initialized and returned to the initial value when a failure of the lamp 200 is determined, the cumulative lighting time is counted from 0 hour in the next lamp 200. When the optical characteristic at the time of a new article is 100%, the optical characteristic at the time of replacement of the lamp 200, for example, the reflectance of the reflector is 99% (1% deterioration), the lamp When replacing 200, the cumulative lighting time starts counting from the corrected initial value (for example, 100 hours).

  This operation is shown in FIG. FIG. 14 is a graph showing a relationship between another cumulative lighting time and dimming rate when performing initial illumination correction. This graph shows that the dimming rate is gradually increased according to the cumulative lighting time to compensate for the luminous flux deterioration of the lamp 200, and the change in the dimming rate from this time to is the change in the storage unit 125c. Stored in the table. When the LED 222 fails to open at time ta 'after starting to turn on the new lamp, the corrected initial value corresponding to the total lighting time (in this case, time ta') is changed to the cumulative lighting time (time to '). When the lamp 200 is replaced, the cumulative lighting time starts counting from the time to ′, the dimming rate corresponding to the time to ′ is read from the storage unit 125c, the lamp 200 is turned on, and the time to ′ If the LED 222 fails to open at time tb ′ from the start time, the correction initial value corresponding to the correction initial value corresponding to the total lighting time (time ta ′ + time tb ′) at this time is changed to the cumulative lighting time.

  As described above, when the lamp 200 is replaced, the accumulated lighting time is not changed to the initial value, but is changed to the corrected initial value in consideration of the deterioration of the lighting fixture (optical component), so that the optical components other than the lamp 200 are deteriorated. The luminous flux of the lighting fixture 100 including the characteristics can be made almost constant, the illuminance on the desk surface can be kept at a desired illuminance, and an energy saving effect can be expected.

  Since the optical components used in the lighting fixture 100 differ depending on the specifications such as the light distribution characteristics of the lighting fixture, a deterioration coefficient of the optical characteristics corresponding to the lighting fixture to be attached is set in the light source lighting device 120 (control circuit 125) in advance. Has been.

  Further, when the DC power supply circuit 121 is configured by a boost chopper circuit, the output voltage of the boost chopper circuit can be made constant regardless of fluctuations in the AC voltage AC. In particular, when the operation of the constant current power supply circuit 122 is stopped, if the step-up chopper circuit is operated, the output voltage detection signal output from the output voltage detection circuit 123 is kept constant even if the AC voltage AC fluctuates. Therefore, the determination unit 125a can determine whether the lamp 200 has failed or whether the lamp 200 has been removed from the light source lighting device 120.

  DESCRIPTION OF SYMBOLS 100 Lighting fixture, 110 Appliance main body, 120 Light source lighting device, 121 DC power supply circuit, 122 Constant current power supply circuit, 122a MOS-FET, 122b Diode, 122c Inductor, 122d capacitor, 122e Drive circuit, 123 Output voltage detection circuit, 123a, 123b resistor, 124 output current detection circuit, 124a resistor, 125 control circuit, 125a determination unit, 125b setting unit, 126 lamp detection circuit, 126a resistor, 130 socket, 140 wiring, 200 lamp, 210 straight tube cover, 220 LED module 221 substrate, 222 LEDs, 223 resistors.

Claims (8)

In a light source lighting device for lighting a lamp in which a plurality of LEDs are connected in series and impedance is connected in parallel to the plurality of LEDs,
A constant current source circuit having an output terminal which the lamp is connected,
Connected to said output terminal of the constant current source circuit, an output voltage detection circuit for detecting a voltage to be output to the output terminal,
Wherein when the constant-current power supply circuit is stopped, and a lamp sensing circuit for applying to the output terminal of the constant current source circuit bypassing to the constant current source circuit,
A control circuit for controlling the pre Kijo current power supply circuit,
With
The control circuit includes a setting unit and a determination unit,
In the setting unit, a first threshold and a second threshold lower than the first threshold are set,
The determination unit stops the constant current power supply circuit when the voltage value of the output voltage detection circuit exceeds the first threshold, and when a predetermined period has elapsed since the constant current power supply circuit was stopped, When the voltage value of the output voltage detection circuit is lower than the second threshold, it is determined that the lamp has failed, and when the voltage value of the output voltage detection circuit is higher than the second threshold, the lamp is removed. After determining that the lamp has been removed, if the voltage value of the output voltage detection circuit is lower than the second threshold, the lamp is connected to the output terminal of the constant current power supply circuit. A light source lighting device characterized by determining and starting the operation of the constant current power supply circuit . In a light source lighting device for lighting a lamp in which a plurality of LEDs are connected in series and impedance is connected in parallel to the plurality of LEDs,
A constant current power supply circuit having an output terminal to which the lamp is connected;
An output voltage detection circuit that is connected to an output terminal of the constant current power supply circuit and detects a voltage output to the output terminal;
A lamp detection circuit that bypasses the constant current power supply circuit and applies to the output terminal of the constant current power supply circuit when the constant current power supply circuit is in a stopped state;
A control circuit for controlling the constant current power supply circuit;
With
The control circuit includes a setting unit and a determination unit ,
In the setting unit, a first threshold and a second threshold lower than the first threshold are set,
The determination unit, a voltage value of the output voltage detection circuit, the constant current power supply circuit is stopped, wherein the first predetermined period of time has elapsed after stopping the constant-current power supply circuit when exceeding the first threshold value when the when the voltage value of the output voltage detecting circuit is lower than the second threshold value is re-operating the constant current source circuit, wherein the second predetermined period after re operating a constant current source circuit until but elapses, when the voltage value of the output voltage detection circuit exceeds the first threshold again, the lamp to stop the failure and determine to the constant-current power supply circuit to stop the constant current circuit After the first predetermined period has elapsed, if the voltage value of the output voltage detection circuit is higher than the second threshold, it is determined that the lamp has been removed, and after the lamp has been determined to have been removed, The voltage value of the output voltage detection circuit is the When it becomes lower than the second threshold value, the lamp is determined to have been connected to the output terminal of the constant current source circuit, the constant current source light source to start you wherein Rukoto the operation of the circuit lighting apparatus. In a light source lighting device for lighting a lamp in which a plurality of LEDs are connected in series and impedance is connected in parallel to the plurality of LEDs,
A constant current power supply circuit having an output terminal to which the lamp is connected;
An output voltage detection circuit that is connected to an output terminal of the constant current power supply circuit and detects a voltage output to the output terminal;
A lamp detection circuit that bypasses the constant current power supply circuit and applies to the output terminal of the constant current power supply circuit when the constant current power supply circuit is in a stopped state;
A control circuit for controlling the constant current power supply circuit;
With
The control circuit includes a setting unit and a determination unit ,
In the setting unit, a first threshold and a second threshold lower than the first threshold are set,
The determination unit, when the voltage value of the output voltage detection circuit, wherein said constant current circuit is stopped when exceeding the first threshold value, said elapsed the first predetermined period after the constant current circuit is stopped in, until a voltage value of the output voltage detecting circuit is lower than the second threshold value to operate the constant current source circuit, wherein the second predetermined time period from the constant current power supply circuit operates has elapsed the output voltage the lamp when the operation cycle is repeated a plurality of times the voltage value of the detection circuit exceeds the first threshold value is determined to failure, the voltage value of the output voltage detection circuit exceeds the first threshold value The constant current circuit is sometimes stopped, and when the first predetermined period elapses after the constant current circuit is stopped , the voltage of the output voltage detection circuit is higher than the second threshold value. The run is determined to have been removed. When the voltage value of the output voltage detection circuit becomes lower than the second threshold after determining that the lamp is removed, it is determined that the lamp is connected to the output terminal of the constant current power supply circuit, and light source lighting device you wherein Rukoto to initiate the operation of the constant-current power supply circuit. The determination unit, when said determination unit determines the lamp malfunction, a light source lighting device according to any one of claims 1 to 3, characterized in that to continue to stop the operation of the constant-current power supply circuit . The determination unit includes an initial illuminance correction function that measures the cumulative lighting time during which the lamp is lit and corrects the light output of the lamp according to the cumulative lighting time.
When the determination unit determines that the lamp has failed, the light source lighting device according to any one of claims 1 to 4, characterized by correcting the cumulative lighting time. 6. The light source lighting device according to claim 5 , wherein the correction of the cumulative lighting time is set to a lighting time in an initial state. The determination unit, regardless of the exchange of the lamp, said constant current source circuit counts the total lighting time that is lit the lamp, correction of the cumulative lighting time, the lighting time to respond to a total lighting time The light source lighting device according to claim 6 , wherein the light source lighting device is set. The light source lighting device according to any one of claims 1 to 7 ,
A socket electrically connected to the light source lighting device, to which the lamp is detachably attached;
An illumination device comprising:

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