JP4753963B2 - Discharge lamp lighting device, lighting device - Google Patents

Description

  The present invention relates to a device for lighting a discharge lamp and a lighting device including a discharge lamp to be lit using the device, and particularly to a device capable of dimming lighting.

The configuration of the discharge lamp lighting device that enables dimming lighting is to turn on the discharge lamp at high frequency using an inverter circuit that converts commercial AC power into high frequency voltage, and adjust the inverter drive frequency to reduce the impedance of the ballast coil. In general, the light is adjusted by adjusting the electric power supplied to the discharge lamp.
In such a discharge lamp lighting device, the lighting state of the discharge lamp becomes unstable during dimming lighting at a low luminous flux, and a phenomenon such as flickering or extinction may occur.

  Therefore, conventionally, there is provided a discharge lamp lighting device capable of suppressing the oscillation of the lamp current during dimming of the low luminous flux, reducing the crest factor, preventing flickering and extinguishing, and enabling stable feedback control. As a technology for the purpose of the above, “the power conversion unit 1 that converts the DC power of the DC power supply Vdc into high-frequency power by switching control of the switching elements Q1 and Q2 and supplies it to the discharge lamp FL; A feedback unit 2 that compares a reference value corresponding to the dimming ratio with a high-frequency output of the power conversion unit 1 and adjusts a control amount of switching control in a direction to match the high-frequency output with the reference value. An amplifier 3 is provided. A series circuit of a resistor R1 and a capacitor C1 is connected in parallel to an input resistor R3 of an operational amplifier OP constituting the error amplifier 3. Is proposed (Patent Document 1).

On the other hand, when the ambient temperature is low, for example, 0 ° C., the characteristics of the discharge lamp are different from those at room temperature, for example, 25 ° C., and the discharge lamp voltage during dimming lighting is very high.
For this reason, when the ambient temperature is low, the voltage for stably lighting the discharge lamp cannot be supplied from the discharge lamp lighting device, so that stable lighting becomes difficult, and a phenomenon called a jump phenomenon in which the luminous flux of the lamp changes rapidly occurs. To do.

  In this case, in the conventional discharge lamp lighting device by feedback control, due to the limit of the response speed of the feedback control circuit, the feedback control cannot follow the rapid light flux change due to the jump phenomenon, and normal lighting may be difficult. .

  Therefore, conventionally, as a technique for the purpose of “providing a dimming discharge lamp lighting device capable of easily continuously varying the light output”, “the dimming control unit 11 controls the high frequency power supply 10 and the impedance Z1. To dimm the discharge lamp 3. The lamp operation point switching control unit 12 receives the dimming signal S1 or the lamp current detection signal S2, and alternately repeats an operation period at a stable operation point at a low output and an operation period at an operation point that changes rapidly. Then, a control signal for continuously controlling the light output is given to the light control unit 11. Is proposed (Patent Document 2).

  Further, “the stability of the light amount in the region where the light output of the discharge lamp is a low luminous flux is improved, and a wide range of light control is possible. As a technique for the purpose, “the chopper circuit CP outputs a DC voltage, and the inverter circuit INV converts the DC voltage into a high-frequency voltage and supplies high-frequency power to the discharge lamp La through the resonance circuit. The output voltage of the chopper circuit CP and the operating frequency of the inverter circuit INV are determined by a voltage command value and a frequency command value determined by the microcomputer MPU with a dimming signal dim from the outside. The microcomputer MPU periodically generates a first command value and a second command value corresponding to the frequency command value, and a voltage waveform applied to the discharge lamp La in response to the second command value is determined by the microcomputer MPU. In addition, the voltage is set to be equal to or higher than the voltage applied to the discharge lamp La in response to the first command value. Is proposed (Patent Document 3).

  Patent Document 3 discloses that a D / A converter that converts a frequency command signal that is a digital signal output from the command value determining means into an analog value of the frequency command value, and an output from the D / A converter. It is also disclosed that a voltage-controlled oscillator that operates an inverter circuit at a frequency proportional to a frequency command value, which is a voltage signal to be generated, and a D / A converter uses a ladder resistor.

JP 2005-71874 A (summary) JP-A-6-76979 (summary) JP 2003-347096 A (Abstract, Claim 2)

In the technique described in Patent Document 2, discharge is stabilized by periodically applying a pulse voltage to the discharge lamp, and the jump phenomenon is suppressed. Further, during a period in which no pulse voltage is applied, the inverter driving frequency is increased to narrow the luminous flux of the discharge lamp.
In the method of applying the pulse voltage as described above, since the energy supplied to the discharge lamp increases when the pulse voltage is applied, the inverter drive frequency is increased during dimming compared to the conventional example in which the pulse voltage is not applied. There is a need.

Regarding the control of the inverter drive frequency, the technique described in Patent Document 3 described above uses a microcomputer MPU in the control circuit to simplify the configuration of the control unit, and to provide a D / A converter (DAC) and a voltage controlled oscillator (VCO). Is used for analog control to generate inverter drive frequency.
In this case, the inverter frequency can be smoothly changed by analog control, but since the D / A converter (DAC) and the voltage controlled oscillator (VCO) are provided, the configuration of the control unit is simplified using the microcomputer MPU. In spite of this, the configuration of the control unit will eventually become complicated.

Instead of using the D / A converter (DAC) and the voltage controlled oscillator (VCO) as described in Patent Document 3 to generate the inverter drive frequency, it is considered to output the inverter drive frequency directly from the microcomputer output.
In this case, the control circuit can be greatly simplified, while the inverter drive frequency is directly output from the microcomputer. If the frequency resolution of the frequency created by the microcomputer is low, the following problems occur.

Since the microcomputer control is digital control, the frequency changes stepwise (stepwise).
When the frequency resolution of the microcomputer is low, when dimming the discharge lamp by changing the inverter frequency, the frequency change width of one step becomes large, so the brightness changes suddenly in a staircase and smooth continuous dimming can be performed. It becomes impossible.
This is because the power change to the lamp changes abruptly because the frequency change width of one step is large, and the brightness changes abruptly.

  The present invention has been made to solve the above-described problems. Even when the ambient temperature is lowered, flickering, extinction, and jumping phenomenon can be suppressed during dimming, and stable dimming lighting can be achieved. An object of the present invention is to provide a discharge lamp device capable of performing smooth continuous light control with a simple circuit configuration.

  A discharge lamp lighting device according to the present invention is a device for lighting a discharge lamp, has a smoothing capacitor, converts a DC power into a DC, and converts the output of the DC power circuit into an AC. An inverter that supplies power; a resonance circuit connected to an output terminal of the inverter; and a control unit that controls an operation of the inverter to adjust a dimming rate of the discharge lamp, and the control unit includes: When adjusting the dimming rate, the inverter is driven at a first frequency period in which the inverter is driven at a first frequency that substantially matches the resonance frequency of the resonance circuit, and a second frequency in which the inverter is driven at a frequency higher than the first frequency. The inverter is driven while being alternately switched in a frequency period, and in the second frequency period, the drive frequency of the inverter is changed from the second frequency higher than the first frequency and the control unit from the second frequency. The second frequency is obtained by driving the inverter while switching at a third frequency that is different by the same frequency as the frequency resolution, and gradually increasing the period during which the inverter is driven at the third frequency in the second frequency period. The average drive frequency of the inverter in the period is gradually increased from the second frequency toward the third frequency.

According to the discharge lamp lighting device according to the present invention, even when the ambient temperature is lowered, by applying a pulse voltage at the first frequency, flickering, extinction, and jump phenomenon during dimming can be suppressed, and stable dimming can be achieved. Can be lit.
Moreover, since the average drive frequency of the inverter is gradually increased from the second frequency to the third frequency by gradually increasing the period during which the inverter is driven at the third frequency, the frequency control is finer than the frequency resolution of the control unit. Is possible.
As a result, the circuit configuration can be simplified using a control unit that performs digital control such as a microcomputer, and the frequency can be smoothly varied to perform smooth continuous light control.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram of a discharge lamp lighting device according to Embodiment 1 of the present invention.
In FIG. 1, a discharge lamp lighting device is a device for lighting a discharge lamp 8 by receiving supply of AC power from a commercial AC power source 1, and includes a rectifier circuit 2, a boost chopper circuit 3, a smoothing capacitor 4, an inverter circuit 5, and a driver. 6, a ballast coil 7, a discharge lamp 8 (when mounted), a resonance capacitor 9, a DC cut capacitor 10, an inverter control unit 11, and a dimming controller 12.

The rectifier circuit 2 performs full-wave rectification on the AC power supplied from the commercial AC power source 1.
The step-up chopper circuit 3 includes a switching element, and boosts the DC voltage that has been full-wave rectified by the rectifier circuit 2 using the switching element.
The smoothing capacitor 4 smoothes the DC voltage output from the boost chopper circuit 3.
The inverter circuit 5 is a half-bridge type inverter provided in series with switching elements 5a and 5b connected in parallel to the smoothing capacitor 4 and converting a DC voltage into a high frequency.

The driver 6 drives the switching elements 5a and 5b based on an instruction from the inverter control unit 11.
Ballast coil 7, discharge lamp 8, and resonant capacitor 9 connected to the output of inverter circuit 5 form a load circuit. The ballast coil 7 and the resonance capacitor 9 form an LC series resonance circuit.
The direct current cut capacitor 10 plays a role of preventing direct current from passing therethrough.

The inverter control unit 11 is configured by an arithmetic device such as a microcomputer or CPU (Central Processing Unit) and software that defines the operation thereof, and the drive frequency (of each switching element) of the inverter circuit 5 is expressed by the first frequency and the second frequency. Control to switch.
The first frequency is set in the vicinity of the resonance frequency of the resonance circuit composed of the ballast coil 7 and the resonance capacitor 9, and the second frequency is set to adjust the input power to the discharge lamp 8. Details of these will be described later.
The dimming controller 12 outputs a dimming signal that indicates the dimming rate of the discharge lamp 8 to the inverter control unit 11. The inverter control unit 11 drives and controls the inverter circuit 5 based on the dimming signal.

The “DC power supply circuit” in the first embodiment corresponds to the rectifier circuit 2 and the boost chopper circuit 3.
The “resonance circuit” corresponds to an LC series resonance circuit including the ballast coil 7 and the resonance capacitor 9.
The “control unit” corresponds to the driver 6 and the inverter control unit 11.

The configuration of the discharge lamp lighting device according to Embodiment 1 has been described above.
Next, the operation of the discharge lamp lighting device according to Embodiment 1 will be described. First, a basic concept regarding operation control is shown, and then a specific operation procedure is described.

The inverter control unit 11 adjusts the input power to the discharge lamp 8 by changing the second frequency in a section where the dimming rate instructed by the dimming signal from the dimming controller 12 is near 100% to about the middle range. To adjust the light.
In this section, it is not necessary to raise the second frequency so much for variable control of the dimming rate. Therefore, even if the second frequency is varied, the upper limit value is kept within a certain range, and switching loss and electromagnetic The influence of disturbing noise is not so high.

In addition, the inverter control unit 11 drives the inverter circuit 5 at the second frequency while fixing the second frequency in a section where the dimming rate indicated by the dimming signal from the dimming controller 12 is near the lower limit value. Only by variably adjusting the oscillation period of the second frequency), dimming is performed by adjusting the input power to the discharge lamp 8.
As a result, an increase in the second frequency is suppressed, and a decrease in circuit efficiency and an increase in electromagnetic interference noise due to switching loss of the inverter circuit 5 are suppressed.

  Further, the inverter controller 11 applies a pulse voltage to the discharge lamp 8 at the first frequency, thereby suppressing flickering, extinction, and jump phenomenon during dimming even when the ambient temperature is lowered, and stable dimming. Aim to achieve lighting.

  The threshold value of the middle range or the low range of the dimming rate is appropriately determined according to the characteristics of the discharge lamp 8 and the inverter circuit 5 and the like.

The basic concept of operation control of the discharge lamp lighting device according to Embodiment 1 has been described above.
Next, a specific operation procedure of the discharge lamp lighting device according to the first embodiment will be described.

(1) Turning on the commercial AC power source 1 When the commercial AC power source 1 is turned on to the discharge lamp lighting device, the rectifier circuit 2 rectifies the AC power supplied from the commercial AC power source 1, and the obtained DC voltage is the boost chopper circuit 3 And is smoothed by the smoothing capacitor 4.
The DC power source smoothed by the smoothing capacitor 4 is converted into a high-frequency voltage when the switching elements 5a and 5b of the inverter circuit 5 are alternately turned on and off.
The inverter control unit 11 performs on / off control of the switching elements 5a and 5b.

(2) Filament preheating mode After turning on the commercial AC power supply 1 and before turning on the discharge lamp 8, the inverter control unit 11 operates in a preheating mode in which the filaments 8a and 8b included in the discharge lamp 8 are preheated in advance. It becomes.
The preheating here means that the temperature of the filaments 8a and 8b is raised to a temperature suitable for the start of discharge in a state before the discharge lamp 8 starts discharge.
The inverter control unit 11 operates the inverter circuit 5 at a sufficiently high inverter driving frequency so that the voltage applied to the discharge lamp 8 is equal to or lower than the discharge start voltage, and the ballast coil 7, the filament 8a, the resonant capacitor 9, and the filament 8b. In order, current is passed through the filament to preheat the filament.

(3) Start mode to lighting mode When sufficient time elapses after the start of the preheating mode, for example, when the preheating of the filaments 8a and 8b is completed, the inverter control unit 11 causes the inverter circuit to turn on the discharge lamp 8. 5 is controlled in the start mode.
The start mode is a mode in which the drive frequency of the inverter circuit 5 is brought close to the resonance frequency of the LC resonance circuit composed of the ballast coil 7 and the resonance capacitor 9.
When the drive frequency of the inverter circuit 5 approaches the resonance frequency of the LC resonance circuit described above, a high voltage is applied to the discharge lamp 8, so that the discharge lamp 8 starts discharging and the discharge lamp 8 is lit, Become.

FIG. 2 shows the lamp voltage waveform of each dimming rate in the lighting mode.
FIG. 2A shows a voltage waveform at almost all light in the vicinity of 100% of the dimming rate (illuminance ratio when the illuminance at the rated lighting is 100%).
In the vicinity of the dimming rate of 100%, the discharge of the discharge lamp 8 is stable, so there is not much concern about a jump phenomenon, and therefore a pulse voltage with the first frequency is not applied.

FIG. 2B shows a voltage waveform in which the dimming rate is near the middle range.
Under the state of FIG. 2A, when the dimming controller 12 outputs a dimming signal indicating that the power of the discharge lamp should be reduced to reduce the luminous flux, the inverter controller 11 drives the inverter circuit 5. The frequency is switched alternately between the first frequency and the second frequency described above.
A period during which the inverter circuit 5 is driven at the first frequency is referred to as a “first frequency period”, and a period during which the inverter circuit 5 is driven at the second frequency is referred to as a “second frequency period”.
A pulse voltage is periodically applied to the discharge lamp 8 at the first frequency, thereby suppressing the jump phenomenon and extinction at a low temperature.

Note that, under the state of FIG. 2 (b), the inverter control unit 11 adjusts the input power to the lamp by fixing the first frequency and its pulse voltage application period T1 and changing only the second frequency. Do light.
That is, a pulse voltage is applied to the discharge lamp 8 by setting the first frequency near the resonance frequency, and the impedance of the ballast coil 7 is increased by increasing the second frequency to reduce the input power to the discharge lamp 8. .

FIG. 2C shows a voltage waveform in which the dimming rate is near the lower limit.
When the dimming rate is near the lower limit, the inverter control unit 11 fixes the first frequency, the pulse voltage application period T1, and the second frequency, and adjusts the lamp power only by variable adjustment of the oscillation period T2 of the second frequency. To adjust the light.
That is, when the pulse voltage is applied, the input energy to the discharge lamp 8 increases, but the average input power to the discharge lamp 8 is increased by extending the oscillation period T2 of the second frequency where the input energy to the discharge lamp 8 is small. Can be small.
Thereby, dimming is possible without increasing the second frequency.

  Moreover, the inverter control part 11 can apply a pulse voltage to the discharge lamp 8 reliably by fixing the pulse voltage application period T1 by a 1st frequency.

Under the state of FIG. 2C, by controlling the voltage waveform as described above, the increase in the second frequency is suppressed, the circuit efficiency is reduced due to the switching loss of the inverter circuit 5, and the electromagnetic interference noise is increased. Can be suppressed.
Further, since the pulse voltage application period T1 to the discharge lamp 8 at the first frequency is fixed and only the second frequency application period T2 is variable, the pulse voltage can be reliably applied to the discharge lamp 8 and the ambient temperature is lowered. Even in this case, it is possible to suppress flickering, extinction, and jump phenomenon during dimming, and to achieve stable dimming lighting.

FIG. 3 shows the relationship between the dimming rate, the second frequency, and the oscillation period T2 of the second frequency.
It can be seen that in the low range where the dimming rate is near the lower limit, the control is performed to lower the dimming rate by fixing the second frequency and lengthening the oscillation period T2 of the second frequency.
Further, it can be seen that in the section where the dimming rate is in the middle range, the dimming rate is adjusted by narrowing the luminous flux by fixing the oscillation period T2 of the second frequency and increasing the second frequency.
Needless to say, there may be a period in which the second frequency and the oscillation period T2 of the second frequency are simultaneously varied.

FIG. 4 is a diagram illustrating a procedure for changing the second frequency in the first embodiment. Here, the operation when the dimming rate is decreased by increasing the second frequency will be described.
As described in FIG. 2B and FIG. 3, when the lamp control is performed to reduce the dimming rate, the inverter control unit 11 sets the inverter frequency (second frequency) in the second frequency period higher than the frequency f2. The lamp power is lowered by changing the frequency to f3.

  Note that the change width for one step when the inverter control unit 11 changes the drive frequency from the frequency f2 to f3 is equal to the frequency resolution of the inverter control unit 11.

At this time, if the frequency resolution of the inverter control unit 11 is small and the frequency change width per step is large, the impedance change of the ballast coil 7 becomes large and the brightness changes abruptly. Therefore, the brightness changes stepwise. Therefore, smooth continuous light control cannot be performed.
Therefore, in the first embodiment, the average drive frequency of the inverter circuit 5 is gradually changed from f2 to f3 by gradually increasing the section in which the inverter circuit 5 is driven at the frequency f3 in the second frequency period.
Hereinafter, the procedure for changing the second frequency in the first embodiment will be described in comparison with the conventional procedure.

FIG. 4A shows a conventional frequency variable procedure.
Conventionally, when the second frequency is changed from f2 to f3, which is higher by one step, the frequency change for one step is immediately executed. Therefore, the change from the frequency f2 to f3 becomes steep, and the user's eyes It was felt as flickering.

FIG. 4B shows a frequency variable procedure in the first embodiment.
In the first embodiment, the period during which the inverter circuit 5 is driven at the second frequency is equally divided into two sections 1 and 2. Then, the period for driving the inverter circuit 5 at the frequency f3 is gradually increased as time elapses.
Steps (1) to (3) in FIG. 4B will be described below.

(1) In the initial state, the drive frequency of the inverter circuit 5 in the second frequency period is f2.
(2) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 in section 2 to f3.
(3) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 in section 1 to f3.

After going through steps (1) to (3), every two cycles of the second frequency period, the ratio of the period for driving the inverter circuit 5 at the frequency f3 increases by 50%, and the second frequency is increased from f2. It changes in steps toward f3.
That is, the second frequency in step (1) is f2, the average value of the second frequency in step (2) is (f2 + f3) / 2, and the second frequency in step (3) is f3. The resolution is twice that of FIG. 4A (variable in two steps), and smoother continuous light control is possible.

  In the above steps (1) to (3), the ratio of the section of the frequency f3 is increased by 50% every two cycles of the second frequency period. However, for example, the state of step (2) is predetermined. It may continue for a number of times. In this case, the change from the frequency f2 to f3 becomes more gradual.

Also, in FIG. 4, the second frequency period is divided into two parts, the first half (section 1) and the second half (section 2), the frequency of section 2 is set to f3 in step (2), and the frequency of section 1 in step (3). The frequency is set to f3, and the ratio of the section of the frequency f3 is increased by 50%.
The division of the second frequency period is not limited to the division into the first half and the second half, and other division methods may be used as long as the ratio of the frequency f3 section is increased by 50%. Good.

The repetition cycle (frequency) for alternately switching the first frequency and the second frequency is preferably 100 Hz or more. This is because the frequency that is not perceived as flicker by human eyes is generally 100 Hz or more.
That is, for example, even if the drive frequency of the inverter circuit 5 is switched from f2 to f3 within the second frequency period, if the repetition period (frequency) is set to 100 Hz or more, it will not be recognized as flicker by human eyes. .
The same principle is applied to other embodiments.

  As described above, in the discharge lamp lighting device according to Embodiment 1, the inverter control unit 11 fixes the first frequency and makes only the second frequency variable when the dimming rate is around the middle range. Dimming is performed by adjusting the input power to the lamp. When the dimming rate is near the lower limit, the first frequency and the second frequency are fixed, and the lamp power is adjusted only by variable adjustment of the oscillation period T2 of the second frequency. Therefore, the second frequency can be prevented from rising.

  Therefore, the discharge lamp lighting device according to the first embodiment can suppress a decrease in circuit efficiency and an increase in electromagnetic interference noise due to the switching loss of the inverter circuit 5 with a simple circuit configuration, and even when the ambient temperature decreases, It is possible to suppress flickering, extinction and jump phenomenon during dimming, and achieve stable dimming lighting.

Further, in the discharge lamp lighting device according to the first embodiment, when the drive frequency of the inverter circuit 5 is varied from the frequency f2 toward f3 that is higher by one step, the inverter circuit 5 at the frequency f3 in the second frequency period. Is increased by 50%.
As a result, the average drive frequency of the inverter circuit 5 can be increased stepwise in two steps from f2 to f3. Compared with the conventional frequency variable method using the same inverter control unit 11, The frequency resolution can be doubled, and smooth continuous light control can be performed.

Embodiment 2. FIG.
In the second embodiment of the present invention, a procedure different from that in the first embodiment when changing the second frequency will be described. Other circuit configurations and the like are the same as those of the first embodiment, and thus description thereof is omitted.

  FIG. 5 is a diagram for explaining a procedure for changing the second frequency in the second embodiment. Steps (1) to (4) in FIG. 5 will be described below.

(1) In the initial state, the drive frequency of the inverter circuit 5 in the second frequency period is f2.
(2) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 to f3 in a predetermined proportion of the second frequency period.

(3) The inverter control part 11 increases the ratio of the area which drives the inverter circuit 5 by the frequency f3 among 2nd frequency periods rather than step (2).
(4) The inverter control unit 11 gradually increases the ratio of the section of the frequency f3 as in the steps (2) to (3), and finally the inverter circuit 5 is set to the frequency f3 in all the second frequency periods. To drive.

After the steps (1) to (4), the ratio of the period for driving the inverter circuit 5 at the frequency f3 gradually increases in the second frequency period, and the second frequency changes stepwise from f2 to f3. To do.
The number of steps from f2 to f3 depends on how many steps are provided between steps (1) and (4). In the example of FIG. 5, the frequency varies in three stages from f2 to f3, but the number of stages may be set arbitrarily.

As described above, in the discharge lamp lighting device according to the second embodiment, when the drive frequency of the inverter circuit 5 is varied from the frequency f2 toward f3 that is higher by one step, the frequency f3 in the second frequency period. The ratio of the period for driving the inverter circuit 5 is gradually increased.
As a result, the average drive frequency of the inverter circuit 5 can be increased stepwise from f2 to f3, so that the same effect as in the first embodiment is exhibited.

Embodiment 3 FIG.
In the third embodiment of the present invention, a procedure different from the first and second embodiments when changing the second frequency will be described. Other circuit configurations and the like are the same as those of the first embodiment, and thus description thereof is omitted.

  FIG. 6 is a diagram illustrating a procedure for changing the second frequency in the third embodiment. Steps (1) to (3) in FIG. 6 will be described below.

(1) In the initial state, in the period in which the inverter circuit 5 is driven at the second frequency, the drive frequency of the inverter circuit 5 is f2.
(2) The inverter control unit 11 drives the inverter circuit 5 at the frequency f3 every other period (every two periods) of the second frequency period.
(3) The inverter control unit 11 drives the inverter circuit 5 at the frequency f3 in all the second frequency periods.

After going through steps (1) to (3), every two cycles of the second frequency period, the ratio of the period for driving the inverter circuit 5 at the frequency f3 increases by 50%, and the second frequency is increased from f2. It changes in steps toward f3.
That is, the second frequency in step (1) is f2, the average value of the second frequency in step (2) is (f2 + f3) / 2, and the second frequency in step (3) is f3. The resolution is twice that of FIG. 4A (variable in two steps), and smoother continuous light control is possible.

  As in FIG. 4B of the first embodiment, the state of step (2) may be continued a predetermined number of times. In this case, the change from the frequency f2 to f3 becomes more gradual.

As described above, in the discharge lamp lighting device according to Embodiment 3, when the drive frequency of the inverter circuit 5 is varied from the frequency f2 toward f3 that is higher by one step, the frequency f3 in the second frequency period. The ratio of the period for driving the inverter circuit 5 is increased by 50% every two cycles of the second frequency period.
As a result, the average drive frequency of the inverter circuit 5 can be increased in two stages from f2 to f3, so that the same effect as in the first embodiment is exhibited.

Embodiment 4 FIG.
In Embodiment 4 of the present invention, a procedure different from Embodiments 1 to 3 when changing the second frequency will be described. Other circuit configurations and the like are the same as those of the first embodiment, and thus description thereof is omitted.

FIG. 7 is a diagram illustrating a procedure for changing the second frequency in the fourth embodiment.
In the fourth embodiment, a period corresponding to two cycles among the periods for driving the inverter circuit 5 at the second frequency is equally divided into four sections 1 to 4. Then, the period for driving the inverter circuit 5 at the frequency f3 is gradually increased as time elapses.
Steps (1) to (5) in FIG. 7 will be described below.

(1) In the initial state, in the period in which the inverter circuit 5 is driven at the second frequency, the drive frequency of the inverter circuit 5 is f2.
(2) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 in section 1 to f3.
(3) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 in section 2 to f3.
(4) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 in the section 3 to f3.
(5) The inverter control unit 11 changes the drive frequency of the inverter circuit 5 in the section 4 to f3.

After going through steps (1) to (5), every two cycles of the second frequency period, the ratio of the period for driving the inverter circuit 5 at the frequency f3 increases by 25%, and the second frequency is increased from f2. It changes in steps toward f3.
That is, the second frequency in step (1) is f2, the average value of the second frequency in step (2) is (3 × f2 + f3) / 4, the second frequency in step (3) is (f2 + f3) / 2, step ( Since the average value of the second frequency in 4) is (f2 + 3 × f3) / 4 and the second frequency in step (5) is f3, the frequency resolution of the one-cycle average is four times that of FIG. Variable), and smoother continuous light control becomes possible.

  As in FIG. 4B of the first embodiment, each state of steps (2) to (4) may be continued a predetermined number of times. In this case, the change from the frequency f2 to f3 becomes more gradual.

In the fourth embodiment, the repetition cycle (frequency) for alternately switching between the first frequency and the second frequency is preferably 200 Hz or more. This is because the frequency that is not perceived as flicker by human eyes is generally 100 Hz or more.
That is, in the fourth embodiment, since one repetition period is equivalent to two periods of the second frequency period, the repetition period (frequency) of the first frequency period and the second frequency period is set to 200 Hz or more so that human This is because it is not recognized as flickering in the eyes.

As described above, in the discharge lamp lighting device according to Embodiment 4, when the drive frequency of the inverter circuit 5 is varied from the frequency f2 toward f3, which is higher by one step, the frequency f3 in the second frequency period. The ratio of the period for driving the inverter circuit 5 is increased by 25% every two cycles of the second frequency period.
As a result, the average drive frequency of the inverter circuit 5 can be increased in four stages from f2 to f3, so that the same effect as in the first embodiment is exhibited.

Embodiment 5 FIG.
FIG. 8 is a configuration diagram of a discharge lamp lighting device according to Embodiment 5 of the present invention.
The difference between the configuration of the discharge lamp lighting device according to the fifth embodiment and the configuration described in FIG. 1 of the first embodiment is that the detection resistor 13 is connected in series with the low-side switching element 5b. .
The detection resistor 13 can detect the current of the inverter circuit 5 and can detect the electric power supplied to the discharge lamp 8 equivalently. The detected signal is smoothed through the filter circuit 14 and input to the inverter control unit 11.
The inverter control unit 11 compares the power supplied to the discharge lamp 8 obtained based on the detected signal value detected with the target lamp power value so that the power supplied to the discharge lamp 8 approaches the target lamp power value. Feedback control means (not shown) for controlling the inverter circuit 5 is provided.
The target lamp power value here is a power value to be supplied to the discharge lamp 8 determined by the correspondence relationship with the dimming rate.

  The feedback control means is configured as a part of the inverter control circuit 11 by an arithmetic device such as a microcomputer or a CPU as in the inverter control unit 11.

The configuration of the discharge lamp lighting device according to Embodiment 5 has been described above.
Next, a basic concept of operation control of the discharge lamp lighting device according to Embodiment 5 will be described.

In the discharge lamp lighting device according to the fifth embodiment, the inverter control circuit 11 adjusts the first frequency for applying the pulse voltage to the discharge lamp 8 and the power to be supplied to the discharge lamp 8, as in the first embodiment. The second frequency for switching is alternately switched.
Further, the feedback control means detects or calculates the input power to the discharge lamp 8 via the detection resistor 13, the target lamp power value determined by the dimming signal, and the power actually input to the discharge lamp 8. And at least one of the second frequency or the oscillation period T2 of the second frequency is variably adjusted so that they match.
As a result, a substantially constant power is supplied to the discharge lamp 8 in response to variations in the characteristics of the discharge lamp and changes in the ambient temperature.

The basic concept of operation control of the discharge lamp lighting device according to Embodiment 5 has been described above.
Next, a specific operation procedure of the discharge lamp lighting device according to the fifth embodiment will be described.

(1) Turning on the commercial AC power source 1 to (3) Starting mode to lighting mode From turning on the commercial AC power source 1 to the lighting mode in which the discharge lamp 8 starts to be lit, as described in the first embodiment. Since it is the same as the operation, the description is omitted.

(4) Control of input power When the discharge lamp 8 is lit, the detection resistor 13 detects the current flowing through the inverter circuit 5, and the detection signal is smoothed by the filter circuit 14 and input to the inverter control unit 11.
The feedback control means calculates the input power to the discharge lamp 8 based on the input current detection signal, compares the calculation result with the target lamp power value, and controls the inverter circuit 5 so that they match.

  The control of the input power to the discharge lamp 8 in step (4) will be described in detail below.

(4.1) When the dimming rate is in the middle range The feedback control means detects the dimming rate by controlling the second frequency only by the inverter control unit 11 and fixing the first frequency when the dimming rate is in the middle range. Dimming is performed by adjusting the input power to the discharge lamp 8 so that the input power to the discharge lamp 8 determined based on the detection value of the resistor 13 matches the target lamp power value.

(4.2) When the dimming rate is near the lower limit value When the dimming rate is near the lower limit value, the feedback control means controls the inverter only for the oscillation period T2 of the second frequency with the first frequency and the second frequency fixed. The dimming is performed by adjusting the input power to the discharge lamp 8 so that the input power to the discharge lamp 8 calculated based on the detection value of the detection resistor 13 and the target lamp power value coincide with each other. I do.

By controlling the voltage waveform as described above, when the dimming rate is in the vicinity of the lower limit value, the input power to the discharge lamp 8 is adjusted only in the application period T2 of the second frequency. Can be suppressed.
Needless to say, there may be a period in which the second frequency and the oscillation period T2 of the second frequency are simultaneously varied.

  In the fifth embodiment, the current of the inverter circuit 5 is detected, and the electric power input to the discharge lamp 8 is equivalently detected with this, but the means for detecting the input electric power to the discharge lamp 8 is However, the present invention is not limited to this, and a means (not shown) for directly detecting the current flowing through the discharge lamp 8 may be provided and used to obtain the input power to the discharge lamp 8.

As described above, in the discharge lamp lighting device according to the fifth embodiment, as in the first embodiment, the inverter control unit 11 applies the first frequency for applying the pulse voltage to the discharge lamp 8 and the discharge lamp 8. The second frequency for adjusting the power to be input is alternately switched.
Further, the feedback control means detects the input power to the discharge lamp 8 via the detection resistor 13, and obtains the target lamp power value determined by the dimming signal and the power actually input to the discharge lamp 8. The comparison calculation is performed, and the input power to the discharge lamp 8 is adjusted by changing the second frequency or the application period T2 of the second frequency so that the two coincide.
Thereby, substantially constant power can be supplied to the discharge lamp 8 in response to variations in characteristics of the discharge lamp 8 and changes in ambient temperature.

Further, the feedback control means fixes the first frequency and the second frequency when the dimming rate is in the vicinity of the lower limit value, and controls only the oscillation period T2 of the second frequency by the inverter control unit 11 to the discharge lamp 8. Dimming by adjusting the input power.
As a result, an increase in the drive frequency of the inverter circuit 5 can be suppressed, a decrease in circuit efficiency accompanying an increase in switching loss and an increase in electromagnetic interference noise can be suppressed, and stable dimming lighting can be achieved.

Embodiment 6 FIG.
FIG. 9 is a configuration diagram of a discharge lamp lighting device according to Embodiment 6 of the present invention.
The discharge lamp lighting device according to the sixth embodiment is newly provided with a voltage dividing resistor 15 in parallel with the smoothing capacitor 4 in addition to the configuration described in FIG. 1 of the first embodiment. Further, a fuse 16 for overcurrent protection is connected between the commercial AC power supply 1 and the rectifier circuit 2.
In addition to the configuration described in the fifth embodiment, a voltage dividing resistor 15 and a fuse 16 may be provided.

The inverter control unit 11 detects the voltage applied to the smoothing capacitor 4 using the voltage dividing resistor 15.
The fuse 16 has a function as an overcurrent interruption means that melts when an overcurrent flows and prevents electric power from being supplied to the discharge lamp lighting device.
Since other configurations and operations are the same as those of any one of the discharge lamp lighting devices described in the first to fifth embodiments, the following description focuses on the differences.

In general, the life of the discharge lamp lighting device is determined by the life of the smoothing capacitor 4.
This is because when the smoothing capacitor 4 deteriorates due to its life, the capacitance decreases, the internal resistance increases, the ripple voltage ΔV of the voltage applied to the smoothing capacitor 4 increases, and the temperature of the smoothing capacitor 4 increases. Due to the fear of smoke, fire, etc.
Therefore, in the sixth embodiment, such a situation is prevented by detecting the ripple voltage ΔV of the smoothing capacitor 4.

The inverter control unit 11 detects the voltage applied to the smoothing capacitor 4 using the voltage dividing resistor 15. When it is detected that the ripple voltage ΔV is equal to or higher than a predetermined threshold value, the driving of the switching elements included in the boost chopper circuit 3 and the switching elements 5a to 5b included in the inverter circuit 5 is stopped to stop the oscillation.
As a result, the boosting function of the boosting chopper circuit 3 and the inverter circuit 5 is stopped, and it is possible to avoid the rise in temperature of the smoothing capacitor 4 and the possibility of smoke and fire.

Even if the oscillation of the boost chopper circuit 3 and the inverter circuit 5 is stopped, the AC power itself supplied from the commercial AC power supply 1 is applied to the smoothing capacitor 4 via the rectifier circuit 2.
Therefore, the inverter control unit 11 always turns on the switching element of the boost chopper circuit 3 or simultaneously turns on the switching elements 5a to 5b included in the inverter circuit 5, thereby short-circuiting the commercial AC power supply 1 and blowing the fuse 16. To do.
As a result, the discharge lamp lighting device can be completely disconnected from the commercial AC power source 1, and the risk of the temperature rise of the smoothing capacitor 4, smoke, and fire can be avoided.

Further, instead of detecting the ripple voltage ΔV of the smoothing capacitor 4, the surface temperature of the smoothing capacitor 4 may be directly detected by a thermistor or the like (not shown).
In this case, when the temperature of the smoothing capacitor 4 becomes equal to or higher than the predetermined temperature, the inverter control unit 11 stops the oscillation of the switching elements of the boost chopper circuit 3 and the switching elements 5a to 5b in the same manner as described above. The switching elements of the boost chopper circuit 3 are always turned on, or the switching elements 5a to 5b included in the inverter circuit 5 are simultaneously turned on.
As a result, the boosting function of the boosting chopper circuit 3 and the inverter circuit 5 is stopped, or the discharge lamp lighting device is completely disconnected from the commercial AC power source 1 to avoid the temperature rise of the smoothing capacitor 4 and the possibility of smoke and ignition. it can.

Embodiment 7 FIG.
FIG. 10 is a side cross-sectional view of a lighting apparatus according to Embodiment 7 of the present invention.
The discharge lamp lighting device 20 described in any of the first to sixth embodiments is housed inside the lighting device body 18, and the discharge lamp 19 is mounted on a lamp socket 21 outside the lighting device body 18, and wiring 22 Is connected to the discharge lamp lighting device 20 to form a lighting device.

  According to the lighting device according to the seventh embodiment, it is possible to suppress a decrease in circuit efficiency and an increase in electromagnetic interference noise due to the switching loss of the inverter circuit 5, and even when the ambient temperature is lowered, flickering during lighting control and disappearance The jump phenomenon can be suppressed and stable dimming lighting can be achieved.

1 is a configuration diagram of a discharge lamp lighting device according to Embodiment 1. FIG. The lamp voltage waveform of each light control rate in lighting mode is shown. The relationship between the light control rate, the second frequency, and the oscillation period T2 of the second frequency is shown. 6 is a diagram for explaining a procedure for changing a second frequency in the first embodiment. FIG. FIG. 10 is a diagram illustrating a procedure for changing the second frequency in the second embodiment. FIG. 10 is a diagram illustrating a procedure for changing a second frequency in the third embodiment. FIG. 10 is a diagram illustrating a procedure for changing a second frequency in the fourth embodiment. FIG. 10 is a configuration diagram of a discharge lamp lighting device according to a fifth embodiment. FIG. 10 is a configuration diagram of a discharge lamp lighting device according to a sixth embodiment. FIG. 10 is a side sectional view of a lighting device according to Embodiment 7.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Commercial AC power supply, 2 Rectifier circuit, 3 Boost chopper circuit, 4 Smoothing capacitor, 5 Inverter circuit, 6 Driver, 7 Ballast coil, 8 Discharge lamp, 8a-8b Filament, 9 Resonance capacitor, 10 DC cut capacitor, 11 Inverter control Part, 12 dimming controller, 13 detection resistor, 14 filter circuit, 15 voltage dividing resistor, 16 fuse, 18 lighting device body, 19 discharge lamp, 20 discharge lamp lighting device, 21 lamp socket, 22 wiring.

Claims (16)

A device for lighting a discharge lamp,
A DC power supply circuit that has a smoothing capacitor and converts AC power into DC,
An inverter that converts the output of the DC power supply circuit into AC and supplies AC power;
A resonant circuit connected to the output end of the inverter;
A control unit for controlling the operation of the inverter to adjust the dimming rate of the discharge lamp;
With
The controller is
When adjusting the dimming rate,
The inverter;
A first frequency period driven at a first frequency that substantially matches the resonant frequency of the resonant circuit;
A second frequency period for driving at a frequency higher than the first frequency;
Drive while switching alternately,
And,
In the second frequency period,
The drive frequency of the inverter is
A second frequency higher than the first frequency;
A third frequency that differs from the second frequency by the same frequency as the frequency resolution of the control unit;
Drive the inverter while switching with
By gradually increasing the period of driving the inverter at the third frequency in the second frequency period,
The discharge lamp lighting device, wherein the average drive frequency of the inverter in the second frequency period is gradually increased from the second frequency toward the third frequency. A device for lighting a discharge lamp,
A DC power supply circuit that has a smoothing capacitor and converts AC power into DC,
An inverter that converts the output of the DC power supply circuit into AC and supplies AC power;
A resonant circuit connected to the output end of the inverter;
A control unit for controlling the operation of the inverter to adjust the dimming rate of the discharge lamp;
With
The controller is
When adjusting the dimming rate,
The inverter;
A first frequency period driven at a first frequency that substantially matches the resonant frequency of the resonant circuit;
A second frequency period for driving at a frequency higher than the first frequency;
Drive while switching alternately,
And,
In the second frequency period,
The drive frequency of the inverter is
A second frequency higher than the first frequency;
A third frequency that differs from the second frequency by the same frequency as the frequency resolution of the control unit;
Drive the inverter while switching with
By increasing the ratio of the period during which the inverter is driven at the third frequency in the second frequency period by 50% each time the second frequency period is reached a predetermined number of times,
The discharge lamp lighting device characterized by gradually increasing the average drive frequency of the inverter in the second frequency period from the second frequency to the third frequency in two stages. A device for lighting a discharge lamp,
A DC power supply circuit that has a smoothing capacitor and converts AC power into DC,
An inverter that converts the output of the DC power supply circuit into AC and supplies AC power;
A resonant circuit connected to the output end of the inverter;
A control unit for controlling the operation of the inverter to adjust the dimming rate of the discharge lamp;
With
The controller is
When adjusting the dimming rate,
The inverter;
A first frequency period driven at a first frequency that substantially matches the resonant frequency of the resonant circuit;
A second frequency period for driving at a frequency higher than the first frequency;
Drive while switching alternately,
And,
In the second frequency period,
The drive frequency of the inverter is
A second frequency higher than the first frequency;
A third frequency that differs from the second frequency by the same frequency as the frequency resolution of the control unit;
Drive the inverter while switching with
By gradually increasing the period during which the inverter is driven at the third frequency in the second frequency period every time the second frequency period is reached a predetermined number of times,
The discharge lamp lighting device, wherein the average drive frequency of the inverter in the second frequency period is gradually increased from the second frequency toward the third frequency. A device for lighting a discharge lamp,
A DC power supply circuit that has a smoothing capacitor and converts AC power into DC,
An inverter that converts the output of the DC power supply circuit into AC and supplies AC power;
A resonant circuit connected to the output end of the inverter;
A control unit for controlling the operation of the inverter to adjust the dimming rate of the discharge lamp;
With
The controller is
When adjusting the dimming rate,
The inverter;
A first frequency period driven at a first frequency that substantially matches the resonant frequency of the resonant circuit;
A second frequency period for driving at a frequency higher than the first frequency;
Drive while switching alternately,
And,
In the second frequency period,
The drive frequency of the inverter is
A second frequency higher than the first frequency;
A third frequency that differs from the second frequency by the same frequency as the frequency resolution of the control unit;
Drive the inverter while switching with
In the second frequency period, the inverter is alternately driven a predetermined number of times at the second frequency and the third frequency,
By switching the drive frequency of the inverter to the third frequency,
The discharge lamp lighting device characterized by gradually increasing the average drive frequency of the inverter in the second frequency period from the second frequency to the third frequency in two stages. A device for lighting a discharge lamp,
A DC power supply circuit that has a smoothing capacitor and converts AC power into DC,
An inverter that converts the output of the DC power supply circuit into AC and supplies AC power;
A resonant circuit connected to the output end of the inverter;
A control unit for controlling the operation of the inverter to adjust the dimming rate of the discharge lamp;
With
The controller is
When adjusting the dimming rate,
The inverter;
A first frequency period driven at a first frequency that substantially matches the resonant frequency of the resonant circuit;
A second frequency period for driving at a frequency higher than the first frequency;
Drive while switching alternately,
And,
In the second frequency period,
The drive frequency of the inverter is
A second frequency higher than the first frequency;
A third frequency that differs from the second frequency by the same frequency as the frequency resolution of the control unit;
Drive the inverter while switching with
By increasing the ratio of the period during which the inverter is driven at the third frequency in the second frequency period by 25% each time the second frequency period is reached a predetermined number of times,
The discharge lamp lighting device, wherein an average driving frequency of the inverter in the second frequency period is gradually increased in four stages from the second frequency to the third frequency. Current detecting means for detecting a current flowing through the inverter;
A feedback control unit for controlling the power supplied by the inverter;
With
The feedback control unit includes:
Based on the detection result of the current detection means,
By varying the drive frequency of the inverter in the second frequency period,
The discharge lamp lighting device according to any one of claims 1 to 5, wherein the power supplied by the inverter is brought close to a target power value of the discharge lamp. Current detecting means for detecting a current flowing in the discharge lamp;
A feedback control unit for controlling the power supplied by the inverter;
With
The feedback control unit includes:
Based on the detection result of the current detection means,
By varying the drive frequency of the inverter in the second frequency period,
The discharge lamp lighting device according to any one of claims 1 to 5, wherein the power supplied by the inverter is brought close to a target power value of the discharge lamp. Voltage detecting means for detecting a ripple voltage of the smoothing capacitor;
The controller is
When the voltage detection means detects the ripple voltage of the smoothing capacitor,
The discharge lamp lighting device according to any one of claims 1 to 7, wherein driving of the inverter is stopped. An overcurrent interrupting means for interrupting the overcurrent;
Voltage detecting means for detecting a ripple voltage of the smoothing capacitor;
With
The controller is
When the voltage detection means detects the ripple voltage of the smoothing capacitor,
Operate the overcurrent interrupting means by short-circuiting the inverter,
The electric power supplied from the outside of the said discharge lamp lighting device is interrupted | blocked. The discharge lamp lighting device in any one of the Claims 1 thru | or 7 characterized by the above-mentioned. Voltage detecting means for detecting a ripple voltage of the smoothing capacitor;
The DC power supply circuit is
A boost chopper circuit that boosts a DC voltage using a switching element that is driven and controlled by the control unit;
The controller is
When the voltage detection means detects the ripple voltage of the smoothing capacitor,
The discharge lamp lighting device according to any one of claims 1 to 7, wherein driving of the switching element provided in the boost chopper circuit is stopped. An overcurrent interrupting means for interrupting the overcurrent;
Voltage detecting means for detecting a ripple voltage of the smoothing capacitor;
With
The DC power supply circuit is
A boost chopper circuit that boosts a DC voltage using a switching element that is driven and controlled by the control unit;
The controller is
When the voltage detection means detects the ripple voltage of the smoothing capacitor,
Short circuiting the boost chopper circuit and operating the overcurrent interrupting means;
The electric power supplied from the outside of the said discharge lamp lighting device is interrupted | blocked. The discharge lamp lighting device in any one of the Claims 1 thru | or 7 characterized by the above-mentioned. Temperature detecting means for detecting the temperature of the smoothing capacitor,
The controller is
When the temperature detecting means detects a predetermined temperature or higher,
The discharge lamp lighting device according to any one of claims 1 to 7, wherein driving of the inverter is stopped. An overcurrent interrupting means for interrupting the overcurrent;
Temperature detecting means for detecting the temperature of the smoothing capacitor;
With
The controller is
When the temperature detecting means detects a predetermined temperature or higher,
Operate the overcurrent interrupting means by short-circuiting the inverter,
The electric power supplied from the outside of the said discharge lamp lighting device is interrupted | blocked. The discharge lamp lighting device in any one of the Claims 1 thru | or 7 characterized by the above-mentioned. Temperature detecting means for detecting the temperature of the smoothing capacitor;
The DC power supply circuit is
A boost chopper circuit that boosts a DC voltage using a switching element that is driven and controlled by the control unit;
The controller is
When the temperature detecting means detects a predetermined temperature or higher,
The discharge lamp lighting device according to any one of claims 1 to 7, wherein driving of the switching element provided in the boost chopper circuit is stopped. An overcurrent interrupting means for interrupting the overcurrent;
Temperature detecting means for detecting the temperature of the smoothing capacitor;
With
The DC power supply circuit is
A boost chopper circuit that boosts a DC voltage using a switching element that is driven and controlled by the control unit;
The controller is
When the temperature detecting means detects a predetermined temperature or higher,
Short circuiting the boost chopper circuit and operating the overcurrent interrupting means;
The electric power supplied from the outside of the said discharge lamp lighting device is interrupted | blocked. The discharge lamp lighting device in any one of the Claims 1 thru | or 7 characterized by the above-mentioned. The discharge lamp lighting device according to any one of claims 1 to 15,
A discharge lamp to be lit by the discharge lamp lighting device;
An illumination device comprising:

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