JP2010272424A - Discharge lamp lighting device and lighting fixture - Google Patents

Abstract

Disclosed is a discharge lamp lighting device having a simple configuration capable of keeping the lighting power of a discharge lamp constant.
A discharge lamp lighting device 101 is driven according to a rectifier circuit 1, a DC power supply circuit 2 that boosts a pulsating voltage output from the rectifier circuit 1, and a drive signal having a predetermined frequency. An inverter circuit 3 for converting a supplied DC voltage into a high-frequency voltage and outputting it, a load circuit 4 to which a discharge lamp 8 is mounted, a microcomputer 10 for generating and outputting a control signal of the predetermined frequency, and a control signal Is input to generate a drive signal and output it to the inverter circuit 3, and a power detection circuit 12 that detects a DC voltage corresponding to the power consumption consumed by the load circuit 4 to which the discharge lamp 8 is mounted. And with. The microcomputer 10 keeps the power consumption of the discharge lamp 8 constant by correcting the frequency of the control signal based on the DC voltage value detected by the power detection circuit 12 in a frequency range higher than the frequency set as the limit value. To do.
[Selection] Figure 1

Description

  The present invention relates to a discharge lamp lighting device for lighting a discharge lamp.

  It is apparent that the discharge lamp lighting device is advantageously controlled using a microcomputer (hereinafter referred to as a microcomputer) in terms of multifunctionalization and circuit simplification.

  As disclosed in Japanese Patent Application Laid-Open No. 4-269500 (Patent Document 1), it is common to perform oscillation control of an inverter with a microcomputer.

  Further, as disclosed in Japanese Patent Application Laid-Open No. 2004-206930 (Patent Document 2), the operating frequency of the inverter circuit is changed in response to the load power, so that even when the environment of the discharge lamp as a load changes, it is substantially uniform. It has been shown to obtain brightness.

  Japanese Laid-Open Patent Publication No. 7-57887 (Patent Document 3) discloses a simple power supply circuit that is a basic power source for operating a microcomputer.

JP-A-4-269500 JP 2004-206930 A Japanese Patent Laid-Open No. 7-57887

  Patent Document 2 discloses a technique for changing the operating frequency of an inverter circuit in response to load power, but the circuit configuration is complicated.

  In addition, using a microcomputer is very effective, but there is a problem of how to configure a power supply circuit of the microcomputer. Usually, the power supply circuit of a microcomputer can be obtained by generating a DC voltage by dropping a voltage from a potential obtained by rectifying a commercial power supply through a resistor. However, in such a power supply circuit, the current obtained with respect to changes in the commercial power supply is different, so that there is a problem that the resistance loss increases as the current increases. Thus, as disclosed in Patent Document 3, a power supply circuit with low loss has been proposed, but many circuit components are required, and it is contrary to the recent demand for space saving.

  An object of this invention is to provide the discharge lamp lighting device of the simple structure which can hold | maintain the lighting power of a discharge lamp uniformly.

The discharge lamp lighting device of the present invention is
In a discharge lamp lighting device for lighting a discharge lamp,
A rectifier circuit for rectifying an AC power supply into a pulsating voltage;
A DC power supply circuit that generates a DC power supply by boosting or stepping down the pulsating voltage obtained from the rectifier circuit;
An inverter circuit that converts a DC voltage supplied from the DC power supply circuit into a high-frequency voltage by driving at the predetermined frequency according to a drive signal of a predetermined frequency, and outputs the converted high-frequency voltage;
A load circuit to which the high-frequency voltage output from the inverter circuit is input while the discharge lamp is mounted;
A microcomputer that generates and outputs a control signal of the predetermined frequency;
The drive signal of the predetermined frequency for driving the inverter circuit is generated from the control signal of the predetermined frequency output by the microcomputer, and the generated drive signal of the predetermined frequency is output to the inverter circuit An inverter drive circuit to
A power detection circuit for detecting a DC voltage corresponding to power consumption consumed by the load circuit to which the discharge lamp is mounted;
The microcomputer is
The predetermined frequency of the control signal is corrected based on a value of the DC voltage detected by the power detection circuit in a frequency range higher than a frequency set in advance as a limit value.

  According to the present invention, it is possible to provide a discharge lamp lighting device having a simple configuration capable of keeping the lighting power of a discharge lamp constant.

FIG. 2 is a circuit configuration diagram of the discharge lamp lighting device 101 according to the first embodiment. The figure which shows the frequency signal which the microcomputer 10 of Embodiment 1 outputs. FIG. 6 is a diagram illustrating correction of the lighting frequency f _{1 according to} the _first embodiment. 3 is a flowchart of constant power control according to the first embodiment. The figure which shows the correction | amendment at the time of preheating of Embodiment 2, and the time of starting. The figure which shows the correction | amendment at the time of preheating of Embodiment 2, and the time of starting. FIG. 10 is a diagram illustrating correction of a threshold value V _{th according to} the second embodiment. The circuit block diagram of the discharge lamp lighting device 102a of Embodiment 2. FIG. The circuit block diagram of the discharge lamp lighting device 102b of Embodiment 2. FIG. FIG. 5 is a circuit configuration diagram of a discharge lamp lighting device 103 according to a third embodiment. The figure which shows the rectangular wave voltage signal which the power supply synchronizing circuit 23 of Embodiment 3 outputs. FIG. 10 is a diagram illustrating a detection cycle determined from an operation clock according to the third embodiment. FIG. 10 shows a lighting system 1000 according to a fourth embodiment.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS. FIG. 1 is a circuit configuration diagram of the discharge lamp lighting device 101 according to the first embodiment. The discharge lamp lighting device 101 includes a rectifier circuit 1, a DC power supply circuit 2 (also called a chopper circuit), an inverter circuit 3, a load circuit 4, an inverter drive circuit 9, a microcomputer 10, a microcomputer power supply circuit 11, and power detection. Circuit 12.

(1) The rectifier circuit 1 rectifies the commercial power supply 31 into a pulsating voltage.
(2) The DC power supply circuit 2 generates a DC power supply by boosting or stepping down the pulsating voltage obtained from the rectifier circuit 1. FIG. 1 shows a booster circuit.
(3) The inverter circuit 3 inputs a drive signal having a predetermined frequency output from the inverter drive circuit 9 (same as the frequency of the control signal output from the microcomputer 10), and is driven at the frequency of the drive signal in accordance with the drive signal. By doing so, the DC voltage supplied from the DC power supply circuit 2 is converted into a high frequency voltage, and the converted high frequency voltage is output to the load circuit 4.
(4) The load circuit 4 is a resonance circuit to which the discharge lamp 8 is attached and the high frequency voltage output from the inverter circuit 3 is input.
(5) The microcomputer 10 generates a control signal having a predetermined frequency and outputs it to the inverter drive circuit 9.
(6) The inverter drive circuit 9 generates a drive signal (having the same frequency as the control signal generated by the microcomputer 10) for driving the inverter circuit 3 from the control signal having a predetermined frequency output from the microcomputer 10. A signal is output to the inverter circuit 3 to drive the inverter circuit 3.
(7) The power detection circuit 12 detects a DC voltage corresponding to the power consumption consumed by the load circuit 4 to which the discharge lamp 8 is attached.
(8) The microcomputer power supply circuit 11 supplies power to the microcomputer 10.

(Driving process of inverter circuit 3)
(1) As described above, the microcomputer 10 generates a control signal having a predetermined frequency and outputs it to the inverter drive circuit 9.
(2) The inverter drive circuit 9 receives a control signal having a predetermined frequency output from the microcomputer 10, generates a drive signal having the same frequency as the control signal, and outputs the drive signal to the inverter circuit 3.
(3) The inverter circuit 3 receives the drive signal output from the inverter drive circuit 9 and drives at the frequency of the drive signal according to the drive signal.

  In the discharge lamp lighting device 101, the microcomputer 10 controls the output (lighting mode) based on the value of the DC voltage detected by the power detection circuit 12 in a frequency range higher than the frequency set in advance as a limit value. Correct the frequency of the signal. This process will be described below.

(Power detection circuit 12)
The power detection circuit 12 detects the load power (corresponding to the power of the discharge lamp 8) of the load circuit 4 when the discharge lamp 8 is lit. As shown in FIG. 1, the power detection circuit 12 converts a current flowing through the load circuit 4 when the discharge lamp 8 is lit into a DC voltage. The microcomputer 10 inputs this DC voltage, digitally converts this DC voltage using an A / D (Analog to Digital) conversion function, and compares / determines with a threshold value _Vth preset in the microcomputer 10. . This threshold value V _th is a value preset in the microcomputer 10 as a target value of power consumption of the discharge lamp 8. The microcomputer 10 corrects the frequency of the control signal being output based on the comparison result. That is, the microcomputer 10 corrects the frequency of the control signal to bring the power consumption of the discharge lamp closer to the threshold value _Vth .

FIG. 2 shows a frequency signal that the microcomputer 10 gives to the inverter drive circuit 9. That is, FIG. 2 is a table showing the frequency of the control signal output from the microcomputer 10 to the inverter drive circuit 9. The microcomputer 10 outputs a control signal having a predetermined frequency to the inverter drive circuit 9, and the frequency of the control signal is a value obtained by dividing the clock f _{cpu of the} microcomputer 10 by an instruction value n which is an integer. The command value n is specified in the program of the microcomputer 10. The microcomputer 10, the preheating of the discharge lamp 8 (preheat mode) and during the starting (starting mode), and outputs a control signal of frequency f _{p (preheat} frequency) and f _{i (starting} frequency), the discharge lamp 8 is lit when you are (lighting mode) outputs _{f 1.}

(Lighting frequency)
Figure 3 is a diagram showing a modification of the operating frequency f _1. As shown in FIG. 3, the microcomputer 10 increases or decreases the initial frequency f ₁ according to the power detection result (DC voltage detection value) by the power detection circuit 12, and the frequency f ′ corresponding to the constant power threshold V _th. Transition to ₁ . As described above, the frequency of the control signal output from the microcomputer 10 is a value obtained by dividing the inherent clock f _cpu for operating the microcomputer 10 by the integer n. That is, the frequency f _x of the output enable control signal of the microcomputer 10 is determined by the command value n as in the following equation (1).
f _x = f _cpu / n (1)
That is, the frequency (operating frequency) f ₁ of the control signal and outputs of the microcomputer 10 when the discharge lamp 8 is lit corresponds to the command value n _1.
That is,
f ₁ = f _cpu / n ₁
It is. In order for the microcomputer 10 to respond to the power detection result by the power detection circuit 12 and perform constant power control, that is, to bring the power detection result closer to the threshold voltage _Vth , a command is obtained from the resonance characteristics and the equation (1) in FIG. What is necessary is just to correct the value n. That is, for the command value n ₁ corresponding to the lighting frequency f ₁ ,
n ₁ = n ₁ ± 1 Formula (2)
By the correction process, the lighting frequency f ′ ₁ corresponding to the threshold value V _th shown in FIG. 2 can be brought close to.

(Correction of the lighting frequency _{f 1} by the microcomputer 10)
FIG. 4 is a flowchart for explaining a constant power control method in which the microcomputer 10 lights the discharge lamp 8 with constant power.
In S <b> 11, the microcomputer 10 acquires a detection voltage from the power detection circuit 12.
In S12, the microcomputer 10 A / D converts the acquired detection voltage.
In S13, the microcomputer 10 compares the A / D converted detection voltage V with the threshold value _Vth .
V <V _th
For, the microcomputer 10 increases the command value _{n 1} corresponding to the current operating frequency _{f 1} by "1" (S14). This
f ₁ = f _cpu / n ₁
Since the denominator becomes larger, the lighting frequency f ₁ becomes smaller, and the detection voltage V increases in accordance with FIG. The microcomputer 10 outputs a control signal with the frequency of the corrected command value (S15).
on the other hand,
V ≧ V _th
In this case, the microcomputer 10 proceeds to S16.
V> V _th
Or V = V _th
Determine.
V> V _th
For, the microcomputer 10 decreases the instruction value n ₁ corresponding to the current operating frequency f ₁ by "1". This
f ₁ = f _cpu / n ₁
Denominator lighting frequency f ₁ is increased becomes smaller in by 2, the detected voltage V is in the direction to decrease. The microcomputer 10 outputs a control signal with the frequency of the corrected command value (S15).
V = V _th
For, the microcomputer 10 does not correct the command value n _1.

(Limit value: limit frequency _f 2)
In general, the load circuit 4 includes the inductor L and the capacitor C as described above. The current flowing through the discharge lamp 8 is determined by the output voltage V of the inverter circuit 3, the inductor L and the capacitor C, and the impedance RL of the discharge lamp 8. The power of the discharge lamp 8 is determined by the product of the discharge lamp current and the impedance RL of the discharge lamp 8. Assuming that the load power of the load circuit 4 described so far is approximately equal to the power of the discharge lamp 8, the impedance RL of the discharge lamp 8 is reduced by the ambient environment (temperature, etc.) of the discharge lamp 8, and the power of the discharge lamp 8 is reduced. When it becomes smaller, the detection voltage of the power detection circuit 12 becomes smaller. In this case, as shown in FIG. 4, the microcomputer 10 increases the power of the discharge lamp 8 by bringing the operating frequency shown in FIG. 3 closer to the resonance frequency side, which is a lower frequency than the conventional operating frequency. However, when the ambient environment of the discharge lamp 8 is more severe, the impedance RL of the discharge lamp 8 becomes considerably small, and the resonance curve at that time is as shown on the left side of FIG. When the left resonance characteristic is obtained, even if the microcomputer 10 modifies the command value to change the frequency, the set threshold value _Vth is not reached. That is, there is no constant load power. In this case, the microcomputer 10 continues to control the frequency low. That is, in the flowchart of FIG. 4, S11, S12, S13, S14, S15, and S11 are looped.

  In general, the operating frequency of the inverter, that is, the frequency of the control signal output from the microcomputer 10, is a slow phase region of resonance characteristics composed of L, C, and RL. Therefore, it is necessary to provide a limit in order to keep the operation in the slow phase region under constant power control that keeps the load power constant. Therefore, the microcomputer 10 holds a predetermined command value as a limit value, and does not employ a command value larger than this limit value. That is, the microcomputer 10 corrects the frequency of the control signal based on the value of the DC voltage detected by the power detection circuit 12 in the frequency range higher than the frequency set in advance as the limit value.

  FIG. 3 shows the relationship between the resonance characteristics and the limit frequency. That is, the microcomputer 10 performs constant power control when the discharge lamp 8 is lit. However, it is not necessary to carry out immediately after the preheating and starting of the discharge lamp 8, and it may be operated after a predetermined time has elapsed. In particular, when the discharge lamp 8 is not stable immediately after lighting, such as when the temperature is low, it is better to operate after a stable discharge state after a delay of a predetermined time.

  In the discharge lamp lighting device 101 of the first embodiment, since the microcomputer 10 performs constant power control of the discharge lamp 8, constant power control is possible with a simple configuration. Further, since the microcomputer 10 refers to the limit value, it is possible to prevent the frequency of the control signal from becoming too low due to a decrease in the impedance RL of the discharge lamp 8.

Embodiment 2. FIG.
Next, the second embodiment will be described with reference to FIGS. The second embodiment is the same as that described in the first embodiment.
(1) and preheating frequency, starting frequency, lighting frequency (before correction based on the detection result of the power detection circuit 12)
(2) Threshold value V _th ,
(3) limit value,
The determination method of will be described.

(Setting of preheating frequency, starting frequency and lighting frequency)
Since L and C constituting the load circuit 4 have characteristic variations, it is difficult to obtain predetermined operating characteristics. However, if the operating frequency (frequency of the control signal output from the microcomputer 10) is corrected, the component characteristics Even if there is a variation, it is possible to obtain predetermined operating characteristics. The microcomputer 10 operates with a command value n preset in the microcomputer 10 when constant power control is not performed when the discharge lamp 8 is lit. However, it is difficult to obtain predetermined operation characteristics due to variations in component characteristics. For this reason, the above-described command value n is set as the sum of the correction value “± A” having a sign in the initial value n ₀ (factory default value) as shown in Expression (3). As a result, the operation characteristics can be corrected.
_{n = n 0 + (± A} ) ··· (3)
In other words, the microcomputer 10 stores “n ₀ ” and “± A” and, according to the program,
f _n = f _cpu / (n ₀ + (± A))
The control signal of the frequency of is generated. As described above, the correction value “± A” is determined by operating the discharge lamp lighting device on the production line.

  5 and 6 are diagrams showing the above correction. If necessary, the correction value is provided at any of the preheating frequency, the starting frequency, and the lighting frequency (before constant power control). That is, since the microcomputer 10 performs constant power control according to the output voltage of the power detection circuit 12 while the discharge lamp 8 is lit as shown in FIG. 4, the correction value “± A” is not related, but the initial value operation At this time, as shown in FIGS. 5 and 6, a control signal having a frequency reflecting the correction value “± A” is output.

(Threshold value V _th setting)
Since the components of the power detection circuit 12 also vary in characteristics, the detection voltage of the power detection circuit 12 needs to be corrected. That is, even if the discharge lamp 8 actually consumes 40 W (watts) of power, for example, a DC voltage equivalent to 35 W is detected as the DC voltage detected by the power detection circuit 12. The microcomputer 10 may correct the threshold value V _th in order to compare the output voltage of the power detection circuit 12 and the threshold value V _th .
For example, the output of the discharge lamp lighting device is detected on the production line, and the lighting frequency is changed so as to obtain an appropriate output (for example, 40 W). When the output of the discharge lamp lighting device is properly output to detect the output voltage of the power detecting circuit 12 to calculates a correction value for correcting the threshold value V _th. As described above, the threshold value V _th uses the A / D detection function of the microcomputer 10. The detection judgment value of the microcomputer 10 is generally
V = (V _DD / m) × n (4)
Can be decided by. Here, m indicates the inherent A / D detection resolution of the microcomputer 10, and n is a command value.

FIG. 7 shows the correction of the threshold value _Vth . By setting the command value n as the sum of “correction value ± B” having a sign and initial n ₀ , the variation of the power detection circuit 12 can be corrected.
n = n ₀ + (± B) Formula (5)
This correction value “± B” is determined by operating the discharge lamp lighting device on the production line. The microcomputer 10 stores “n ₀ ” and “± B” and calculates Expression (5) by a program.

(Limit value setting)
Similarly, the limit value described above also has a variation in characteristics of the load circuit 4, in particular, a variation in resonance characteristics, and thus it is necessary to reflect the correction value. The limit value is the same as in the case of the preheating frequency or the like. Note that the default correction value of the limit value may be the same value as the lighting frequency correction value.

The correction values of (1) the preheating frequency, the starting frequency and the lighting frequency, (2) the threshold value V _th , and (3) the limit value described above are stored in a nonvolatile memory (storage unit), and the microcomputer 10 Reflect in the program. As described above, the correction value is determined by operating the discharge lamp lighting device on the production line. In particular, since a microcomputer is used, it is effective to send a pulse from an external device as a correction value. 8 and 9 show examples in which a nonvolatile memory for storing information such as correction values and initial command values is mounted. FIG. 8 shows a discharge lamp lighting device 102a in which the microcomputer 10 is mounted with a non-volatile memory, and FIG. 9 shows a discharge lamp lighting device 102a using an EEPROM as a non-volatile memory separately from the microcomputer 10. Further, as shown in FIG. 8, the microcomputer 10 has a ROM and a RAM, and a program is stored in the ROM.

  The discharge lamp lighting devices 102a and 102b according to the second embodiment store correction values corresponding to control signals, correction values corresponding to power control threshold values, and correction values corresponding to limit values, and reflect these correction values. Therefore, it is possible to correct variations in the characteristics of elements constituting the circuit.

Embodiment 3 FIG.
Next, the discharge lamp lighting device 103 according to the third embodiment will be described with reference to FIGS. FIG. 10 is a circuit configuration diagram of the discharge lamp lighting device 103. The discharge lamp lighting device 103 is further provided with a microcomputer second power supply circuit 22 and a power supply synchronization circuit 23 in addition to the discharge lamp lighting device 103 of the first embodiment. In the discharge lamp lighting device 103, the power detection circuit 12 is omitted, but by providing the power detection circuit 12, the constant power control can be performed during the lighting of the discharge lamp 8, as in the discharge lamp lighting device 101. . In the third embodiment, the microcomputer power supply circuit 11 in the discharge lamp lighting device 101 is referred to as a microcomputer first power supply circuit 11.

(Two microcomputer power supply circuits)
As shown in FIG. 10, the power supply circuit of the microcomputer 10 is a microcomputer first power supply circuit 11 that can be supplied from a commercial power supply 31 or a pulsating voltage, and the microcomputer circuit that is obtained from the output of the inverter circuit 3 after outputting the drive frequency. There is a second power supply circuit 22. The first power supply circuit 11 for the microcomputer supplies the microcomputer 10 with a DC voltage based on one of a pulsating voltage obtained from the rectifying circuit 1 and a voltage obtained by half-wave rectifying the output voltage of the AC power supply 31. Although FIG. 10 shows the case where the pulsating voltage obtained from the rectifier circuit 1 is supplied as the first power supply circuit 11 for the microcomputer, a DC voltage based on a voltage obtained by half-wave rectifying the output voltage of the AC power supply 31 is supplied to the microcomputer 10. It may be a power source.
The second power supply circuit 22 for the microcomputer supplies a DC voltage based on the output of the inverter circuit 3 to the microcomputer 10.

(Power supply synchronization circuit 23)
The power supply synchronization circuit 23 is a circuit that detects the presence or absence of the commercial power supply 31, and is a detection circuit that is synchronized with the commercial power supply 31. As will be described later with reference to FIG. 11, when the voltage value of the commercial power supply 31 is normal, the power supply synchronization circuit 23 outputs a rectangular wave voltage corresponding to the voltage value of the commercial power supply 31 at a constant period and is turned on. When the voltage value of the commercial power supply 31 is lower than normal, a voltage corresponding to the high signal of the rectangular wave voltage is output.

  FIG. 11 shows a rectangular wave voltage signal obtained from the power supply synchronization circuit 23. In the rectangular wave voltage shown in FIG. 11, when there is an L (Low level) signal, it indicates that the voltage of the commercial power supply 31 is equal to or higher than a predetermined value. That is, when the voltage value of the commercial power supply 31 is normal, the power supply synchronization circuit 23 outputs a rectangular wave voltage corresponding to the voltage value of the commercial power supply 31 at a constant period. When the voltage value is lower than normal, a voltage corresponding to a rectangular wave High signal is output.

  The first power supply circuit 11 for the microcomputer serves as a starting power supply until power is supplied from the second power supply circuit 22 for the microcomputer. The first power supply circuit 11 for microcomputer is a startup power supply. For this reason, the microcomputer 10 operates with lower power consumption when the power is supplied from the first power supply circuit 11 for the microcomputer than in the steady state where the power is supplied from the second power supply circuit 22 for the microcomputer. That is, in the microcomputer 10, the first operation clock when the first power supply circuit 11 for microcomputer is used as the power supply is lower than the second operation clock when the second power supply circuit 22 for microcomputer is used as the power supply.

  Since the operation clock is low when operating with this low power consumption (first power supply circuit 11 for microcomputer), the detection of the power supply synchronization detection signal by the microcomputer 10 is the second operation clock of the second power supply circuit 22 for microcomputer. It must be detected with a period larger than the case. Usually, when it is desired to determine the time of the rectangular wave voltage, it is preferable to carry out with a detection cycle less than the time to be determined. However, when the operation clock described above is low, the detection cycle becomes long.

FIG. 12 is a diagram showing a detection cycle determined from the operation clock. As shown in FIG. 12, the detection cycle t ₃ by the microcomputer 10 is the difference “T ₀ −t ₃ × n” obtained by subtracting a value obtained by multiplying the detection cycle t _{3 by} an integer n from the generation cycle T ₀ of the power supply synchronization detection signal. If it is smaller than the time t ₁ of the rectangular wave voltage to be detected, it can be detected.
That is,
T ₀ −t ₃ × n <t ₁ Formula (6)
Can be detected.
At this time, the longest time T ₁ until detection is possible is shown in FIG.
_{T 1 = (t 3 / (} T 0 -t 3 × n) × T 0) -t 3
(However, n is an integer of 1, 2,..., And the maximum value that satisfies t ₁ > 0)
Can be shown.

That is, the microcomputer 10 starts to operate using the first power supply circuit 11 for microcomputer as a power source when the commercial power supply 31 is turned on, and is output from the power supply synchronization circuit 23 when starting operation using the first power supply circuit 11 for microcomputer as a power source. voltage type was to start a detection process of detecting a Low signal of the rectangular wave voltage in the first detection period t ₃ when satisfying the predetermined formula (6) depending from the input voltage to the first operation clock. When the microcomputer 10 detects the Low signal (when the AC power supply 31 is normal), the microcomputer 10 starts generating the control signal and transfers the power from the microcomputer first power supply circuit 11 to the microcomputer second power supply circuit 22. Switch. On the other hand, when the Low signal is not detected (when the AC power supply 31 is not a normal voltage), the microcomputer 10 does not start generating the control signal (does not drive the inverter circuit 3). Further, when the microcomputer 10 becomes unable to detect the Low signal while outputting the control signal using the second power supply circuit 22 for the microcomputer as a power source, the microcomputer 10 stops the drive of the inverter circuit 3 according to the program incorporated in advance and the inverter circuit. One of the low output control to reduce the output of 3 is executed.

  The discharge lamp lighting device 103 has a second power supply circuit 22 for microcomputer. After the drive frequency (control signal) is output by the microcomputer 10, the microcomputer 10 is supplied with power from the second power supply circuit 22 for microcomputer and operates with a second operation clock having a higher clock than the first operation clock. Therefore, when using the second power supply circuit 22 for the microcomputer as a power source, the microcomputer 10 executes a detection process for detecting a low signal of a rectangular wave voltage at a predetermined second detection cycle in accordance with the second operation clock. . By shortening the detection cycle, for example, an instantaneous power failure or instantaneous voltage drop of the commercial power supply 31 is detected, and by stopping or reducing the output of the inverter circuit 3, it is possible to prevent a component failure or the like.

  The discharge lamp lighting device 103 according to the third embodiment includes the first power supply circuit 11 for microcomputer, the second power supply circuit 22 for microcomputer, and the power supply synchronization circuit 23. For this reason, it is possible to provide a power supply circuit for a microcomputer having a simple configuration and low loss.

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIG. FIG. 13 is a diagram illustrating a lighting system 1000 including a plurality of lighting fixtures 50 incorporating the discharge lamp lighting device described in the first embodiment or the second embodiment.

  FIG. 13 is an overall view of the lighting system 1000. The lighting system 1000 includes a plurality of lighting fixtures 50 and a switch box 70. Each lighting fixture 50 includes sockets 53a and 53b to which the fixture main body 51, the reflection plate 52, and the discharge lamp 8 are attached. In FIG. 13, the socket 53 b is hidden in the instrument body 51. The appliance main body 51 is attached with the discharge lamp lighting device described in the first embodiment or the second embodiment. Outputs from the discharge lamp lighting device are connected to both ends in the longitudinal direction of the appliance main body 51 via electric wires. In FIG. 13, the discharge lamp 8 is attached to the lamp socket of the appliance main body 21. The switch box 70 includes a first power switch 60.

  In the lighting system 1000 shown in FIG. 13, since the discharge lamp lighting device of each lighting fixture 50 performs constant power control, a constant brightness can be obtained regardless of the surrounding environment of the discharge lamp.

  DESCRIPTION OF SYMBOLS 1 Rectification circuit, 2 DC power supply circuit, 3 Inverter circuit, 4 Load circuit, 5 Inductor, 6, 7 Capacitor, 8 Discharge lamp, 9 Inverter drive circuit, 10 Microcomputer, 11 1st power supply circuit for microcomputers, 12 Power detection circuit, 13 Nonvolatile memory, 22 Second power supply circuit for microcomputer, 23 Power supply synchronization circuit, 50 Lighting fixture, 51 Appliance body, 52 Reflector, 53a, 53b Socket, 60 Power switch, 70 Switch box, 101, 102a, 102b, 103 Discharge lamp lighting device, 1000 lighting system.

Claims (10)

In a discharge lamp lighting device for lighting a discharge lamp,
A rectifier circuit for rectifying an AC power supply into a pulsating voltage;
A DC power supply circuit that generates a DC power supply by boosting or stepping down the pulsating voltage obtained from the rectifier circuit;
An inverter circuit that converts a DC voltage supplied from the DC power supply circuit into a high-frequency voltage by driving at the predetermined frequency according to a drive signal of a predetermined frequency, and outputs the converted high-frequency voltage;
A load circuit to which the high-frequency voltage output from the inverter circuit is input while the discharge lamp is mounted;
A microcomputer that generates and outputs a control signal of the predetermined frequency;
The drive signal of the predetermined frequency for driving the inverter circuit is generated from the control signal of the predetermined frequency output by the microcomputer, and the generated drive signal of the predetermined frequency is output to the inverter circuit An inverter drive circuit to
A power detection circuit for detecting a DC voltage corresponding to power consumption consumed by the load circuit to which the discharge lamp is mounted;
The microcomputer is
A discharge lamp characterized by correcting the predetermined frequency of the control signal based on a value of the DC voltage detected by the power detection circuit in a frequency range higher than a frequency set in advance as a limit value. Lighting device. The microcomputer is
2. The release according to claim 1, wherein a predetermined threshold value is compared with the DC voltage detected by the power detection circuit, and the predetermined frequency of the control signal is corrected based on a comparison result. Electric light lighting device. The microcomputer is
A preheating mode for outputting the control signal for preheating the discharge lamp, a start mode for outputting the control signal for starting the discharge lamp, and a lighting mode for outputting the control signal for lighting the discharge lamp are sequentially shifted. In addition, when shifting from the start mode to the lighting mode, the control signal for lighting is set based on the lighting frequency preset for lighting and the lighting frequency correction value preset as the correction value of the lighting frequency. 3. The release according to claim 1, wherein when generating and correcting the predetermined frequency, a value obtained by adding a correction value of the default value to a default value of the limit value is referred to as the limit value. Electric light lighting device. The microcomputer is
4. The correction value for correcting the threshold value by detecting the voltage of the power detection circuit when the power output information is input from the outside and the power output information is a predetermined power value is calculated. The discharge lamp lighting device according to any one of the above. The correction value of the default value of the limit value is
The discharge lamp lighting device according to claim 3, wherein the lighting lamp correction device has the same value as the lighting frequency correction value. The discharge lamp lighting device further includes:
The discharge lamp lighting device according to claim 3, further comprising a storage unit that stores the correction value. The discharge lamp lighting device further includes:
A first power supply circuit for the microcomputer that supplies a DC voltage to the microcomputer based on any one of a pulsating voltage obtained from the rectifier circuit and a voltage obtained by half-wave rectifying the output voltage of the AC power supply; ,
A second power supply circuit for the microcomputer that supplies the microcomputer with a DC voltage based on the output of the inverter circuit;
When the voltage value of the supplied AC power supply is normal, a rectangular wave voltage corresponding to the voltage value of the AC power supply is output at a constant cycle, and the voltage value of the supplied AC power supply is more than normal. A power supply synchronizing circuit that outputs a voltage corresponding to the high-frequency signal of the rectangular wave voltage when low,
The microcomputer is
A first operation clock when the first power supply circuit is used as a power supply is lower than a second operation clock when the second power supply circuit is used as a power supply, and the first power supply circuit when the AC power supply is turned on. When the operation is started using the first power supply circuit as a power supply, the voltage output by the power supply synchronization circuit is input, and the input voltage is predetermined according to the first operation clock. Detection processing for detecting the Low signal of the rectangular wave voltage is started in a first detection cycle, and when the Low signal is detected, generation of the control signal is started and power is supplied from the first power supply circuit. The discharge lamp lighting device according to any one of claims 1 to 6, wherein the control signal generation is not started when the second power supply circuit is switched and the Low signal is not detected. The microcomputer is
If the Low signal cannot be detected while the control signal is being output using the second power supply circuit as a power supply, stop control for stopping the drive of the inverter circuit and reduction of the output of the inverter circuit according to a program incorporated in advance 8. The discharge lamp lighting device according to claim 7, wherein any one of the low output control is executed. The microcomputer is
When the second power supply circuit is used as a power supply, a detection process of detecting the Low signal of the rectangular wave voltage at a second detection period that is predetermined according to the second operation clock is performed. The discharge lamp lighting device according to claim 7 or 8. The discharge lamp device according to any one of claims 1 to 9,
A lighting fixture comprising a socket connected to a load circuit of the discharge lamp device and mounted with the discharge lamp.

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