JP4103266B2 - Discharge lamp lighting device and lighting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a discharge lamp lighting device including a plurality of discharge lamps for lighting a discharge lamp at a high frequency, and an illumination device using the same.
[0002]
[Prior art]
A multi-lamp parallel lighting circuit system in which a plurality of series circuits of a discharge lamp and a current limiting inductive reactance are connected in parallel to a lighting power source of the discharge lamp is known. In the case of this circuit system, the remaining discharge lamps are lit even if some of the discharge lamps are thinned out.
[0003]
However, the multi-lamp parallel lighting circuit system requires a current-limiting inductive reactance for each individual discharge lamp, and is therefore expensive.
[0004]
On the other hand, a multi-lamp series lighting circuit system in which a plurality of discharge lamps are connected in series to the lighting power source of the discharge lamp and connected to the lighting power source through a common current-limiting inductive reactance is also known. In the case of this circuit system, some of the discharge lamps cannot be thinned and the remaining discharge lamps cannot be lit.
[0005]
Japanese Patent Application Laid-Open No. 57-84598 discloses a discharge lamp lighting device in which a part of the discharge lamps is thinned out so that the remaining discharge lamps can be turned on in the multi-lamp series lighting circuit system.
[0006]
[Problems to be solved by the invention]
However, since the above-mentioned conventional technology of the multi-lamp series lighting circuit system is a configuration in which a switch is provided in the lighting circuit and the remaining discharge lamp is lit when thinning one lamp, a switch is necessary and a discharge lamp that can be thinned out There is a fatal problem that it is decided uniquely.
[0007]
Although the present invention is a multi-lamp series lighting circuit system, any desired discharge lamp can be thinned out without requiring a switch. Turn on the remaining discharge lamp It is a main object of the present invention to provide a discharge lamp lighting device and an illumination device using the same.
[0008]
Another object of the present invention is to provide a discharge lamp lighting device capable of automatically adjusting the lamp current to a required value at the time of thinning lighting and a lighting device using the same.
[0009]
[Means for achieving the object]
The discharge lamp lighting device according to the first aspect of the present invention includes a high-frequency generating means; a plurality of series-connected discharge lamps energized by a high-frequency output of the high-frequency generating means; and interposed in series between the high-frequency generating means and the discharge lamp Inductive reactance for current limiting; connected in parallel to each discharge lamp Capacitive reactance Resonant with current-limiting inductive reactance for high-frequency output When some discharge lamps are thinned out, the capacitive reactance connected in parallel to the thinned discharge lamps is connected in series to the remaining discharge lamps and connected in parallel to the remaining discharge lamps. The capacitive reactance acts in series with the current-limiting inductive reactance to produce a voltage sufficient to start across the remaining discharge lamp. Ru plural And capacitive reactance.
[0010]
In the present invention and each of the following inventions, the definitions and technical meanings of terms are as follows unless otherwise specified.
[0011]
<About high frequency generation means>
In the present invention, “high frequency” is set to 10 KHz or more in the present invention from the viewpoint of reducing the size and weight of the lighting device and improving the lamp efficiency. However, it is preferably 40 KHz to 500 KHz from the viewpoint of switching loss and cost of the switching means.
[0012]
The high frequency generation means may have any configuration as long as it generates a high frequency, but it is desirable to use an inverter.
[0013]
The inverter may be any inverter such as a one-stone inverter, a parallel inverter, a half-bridge inverter, a full-bridge inverter, or a modification of each of the above inverters.
[0014]
The inverter may be either self-excited or separately-excited.
[0015]
Further, in order to obtain a high-frequency output from the inverter, an insulating output transformer may be used, or a direct connection type may be used. In the latter case, a DC cut capacitor may be connected in series with the discharge lamp to prevent the DC component from flowing into the load circuit.
[0016]
Furthermore, an active filter such as a chopper can be interposed between the non-smoothing rectified power supply and the input terminal of the inverter in order to increase the power factor of the input current and to reduce the harmonic distortion. Alternatively, a composite inverter configured to obtain a smoothed DC voltage by using high-frequency switching of the switching means of the inverter can be used.
[0017]
Furthermore, the high frequency generating means can be controlled so that only the filament preheating is performed by reducing the high frequency output for a predetermined period in order to preheat the filament electrode as required before starting the discharge lamp.
[0018]
Furthermore, the high-frequency generating means can increase the high-frequency output during the starting period and set a reasonable starting time during which all the discharge lamps can be started in order to start the plurality of discharge lamps satisfactorily.
[0019]
< plural About discharge lamp>
plural The discharge lamp is not limited to a specific configuration as long as it includes a pair of electrodes and discharge is performed between the electrodes. The electrodes are allowed to be cold cathodes, ceramic electrodes, filament electrodes, and the like. However, the present invention is suitable for low pressure discharge lamps with filament electrodes, in particular low pressure gas or mercury vapor discharge lamps. Examples of this type of discharge lamp include a fluorescent lamp and a sterilizing lamp.
[0020]
Further, a plurality of discharge lamps are connected in series with the current-reducing inductive reactance and connected between the output terminals of the high-frequency generating means, but the plurality of discharge lamps must all form one series circuit. If However, it is not necessary to connect a plurality of series circuits of a plurality of discharge lamps in parallel. However, in this case, each series circuit Against each The current limiting inductive reactance described below must be connected in series.
[0021]
Furthermore, when a plurality of discharge lamps are connected in series, it is preferable that the discharge lamps are of the same type, but this is not an essential requirement. For example, the ring-shaped fluorescent lamp FCL30 has a rated lamp current of 0.6A and the FCL32 has the same 0.425A, but these are connected in series so that any of the rated lamp currents or the average lamp current thereof can be obtained. Can be lit.
[0022]
<About inductive reactance for current limiting>
Inductive reactance for current limiting is Connected in series to this Discharge lamp Against each To compensate for the negative characteristics of Concerned Discharge lamp In Used to flow.
[0023]
In addition, the current limiting inductive reactance is not limited to a specific configuration such as a choke coil and a leakage transformer as long as the inductance has a required value. When a leaky transformer is used as the inductive reactance for current limiting, the transformer is allowed to double as an output transformer of high-frequency generating means.
[0024]
Furthermore, the inductive reactance for current limiting is as described above, when the discharge lamp connects a plurality of series circuits in parallel. Are connected to each other, Multiple used.
[0025]
Furthermore, the inductive reactance for current limiting is not only an inductance, but if necessary, even if it is a composite circuit with capacitive reactance and resistance, overall inductive reactance is superior, that is, inductive reactance. That's fine.
[0026]
< plural About capacitive reactance>
plural A capacitive reactance is connected in parallel to each discharge lamp. When any one of the discharge lamps is thinned out, the capacitive reactance connected in parallel to the thinned discharge lamp is connected in series with the remaining discharge lamps.
[0027]
In addition, the capacitive reactance may include inductive reactance as long as it is not only a capacitor but also capacitive reactance as a whole.
[0028]
Furthermore, the capacitive reactance is determined when the discharge lamp is provided with a filament electrode, when other current adjustment impedance is connected between both ends of the filament electrode, that is, when necessary, the discharge lamp is connected to the discharge lamp via the filament electrode. It may be connected in parallel. In this case, when the discharge lamp is thinned out, the capacitive reactance is connected in series to the remaining discharge lamp through the current adjusting impedance in series.
[0029]
Further, when the current adjustment impedance is connected in series to the discharge lamp, the capacitive reactance may be connected in parallel via the current adjustment impedance.
[0030]
As can be understood from the above, the current adjusting impedance can be used to adjust the lamp current of the remaining discharge lamp as desired.
Therefore, the current adjustment impedance can be used to adjust the lamp current of the remaining discharge lamp as desired.
[0031]
<Operation of the present invention>
In the present invention, when starting with a plurality of discharge lamps connected in series without being thinned, each Since the capacitive reactances connected in parallel to the discharge lamps are in series resonance with the current-reducing inductive reactance appropriately for the high frequency generated from the high frequency generating means, there is sufficient voltage to start both ends of the capacitive reactance. appear. This plural The discharge lamp starts and lights up.
[0032]
At the time of start-up, in order to preheat the filament electrode in advance, the output of the high-frequency generating means can be previously reduced for a predetermined period, and the filament electrode can be preheated during that time.
[0033]
Next, when any one of the discharge lamps is thinned out, the capacitive reactance connected in parallel with the discharge lamps is connected in series with the remaining discharge lamps at the part where the discharge lamps are thinned out. For this reason, since the high frequency is applied to the capacitive reactance connected in parallel between the electrodes of the remaining discharge lamp through the capacitive reactance connected in parallel to the thinned discharge lamp, the former capacitive The reactance is induced for current limiting, and moderately resonates with the reactance to increase the voltage across the both ends. As a result of this resonant voltage being applied to the remaining discharge lamp, the remaining discharge lamp is started.
[0034]
From the above description, it can be understood that the plurality of discharge lamps connected in series can start and light the remaining discharge lamps well even if any desired discharge lamp is thinned out.
[0035]
As described above, when a plurality of discharge lamps are connected in series, discharge lamps having different rated lamp currents can be used. However, when the rated lamp currents are different, the starting voltage is often different. In such a case, the value of the capacitive reactance connected in parallel with the discharge lamp may be selected so that a series resonance voltage corresponding to the starting voltage of the discharge lamp can be obtained.
[0036]
Further, in the present invention, since the inductive reactance for current limiting can be commonly applied to each of the plurality of discharge lamps, the number of circuit components is reduced, and the discharge lamp lighting device can be provided at low cost. In addition, as described above, any desired discharge lamp can be lit out and lit.
[0037]
A discharge lamp lighting device according to a second aspect of the present invention is the discharge lamp lighting device according to the first aspect, wherein the lamp voltage detection means detects the lamp voltage of the discharge lamp; and the detection output of the lamp voltage detection means exceeds a predetermined value. And control means for controlling the output of the high-frequency generation means.
[0038]
When some discharge lamps are thinned out from a series circuit of a plurality of discharge lamps, generally, the lamp current flowing through the remaining discharge lamps increases and the lamp voltage at both ends of the series circuit of the discharge lamps tends to increase.
[0039]
Therefore, in the present invention, the lamp voltage of the discharge lamp is detected, and when the detected value exceeds a predetermined value, the high frequency generating means is controlled to reduce its output, thereby reducing the lamp for the remaining discharge lamp. The current is set to an appropriate value.
[0040]
In addition, according to the present invention, even when the discharge lamp reaches the end of its life, the protective operation can be safely performed by controlling the high frequency generating means. That is, when the discharge lamp reaches the end of its life, the lamp voltage rises, so that the lamp voltage is detected and the high frequency output of the high frequency generating means is controlled so that the discharge lamp cannot maintain the discharge or is dimmed, or Discharge intermittently.
[0041]
In order to determine whether or not the detected value of the lamp voltage exceeds a predetermined value, a determining means can be disposed between the lamp voltage detecting means and the control means.
[0042]
A discharge lamp lighting device according to a third aspect of the present invention is the discharge lamp lighting device according to the first or second aspect, wherein the high-frequency generating means is a self-oscillation type one-stone inverter using a saturable current transformer. It is a feature.
[0043]
A one-stone inverter is a circuit-type inverter that uses a single switching means to turn on and off direct current to convert it into alternating current. In order to make the output voltage a sine wave, it resonates at the fundamental frequency of switching. A resonance circuit is provided.
[0044]
The high frequency output can be taken out via an output transformer or a direct current cut capacitor.
[0045]
The self-excited oscillation type is a circuit system that obtains the drive signal of the switching means in a feedback manner from the circuit operation of the high-frequency generation means.
[0046]
In the present invention, the self-excited oscillation is configured to obtain a drive signal by feeding back a high-frequency output via a supersaturated current transformer. When using a supersaturated current transformer, the oscillation frequency can be controlled by varying the saturation time by controlling the impedance of the secondary winding.
[0047]
Thus, in the present invention, by using a self-excited oscillation type monolithic inverter using a supersaturated current transformer as a high-frequency generating means, the circuit configuration is simplified and an inexpensive discharge lamp lighting device can be obtained. it can.
[0048]
In addition, the one-stone inverter can make the output voltage waveform sine wave by the LC resonance circuit and obtain a high resonance voltage, so that the required starting voltage can be easily obtained even in series lighting.
[0049]
Furthermore, since the one-stone inverter is soft-switched, it generates less noise.
[0050]
A discharge lamp lighting device according to a fourth aspect of the present invention is the discharge lamp lighting device according to any one of the first to third aspects, wherein the discharge lamp lighting device is connected in series mainly with the remaining discharge lamps when some of the discharge lamps are removed. A lamp current adjusting impedance for adjusting the lamp current is provided.
[0051]
The present invention defines a configuration different from claim 2 for adjusting the lamp current flowing in the remaining discharge lamps when some of the discharge lamps are thinned out.
[0052]
It is claimed that when some discharge lamps are thinned out from a series circuit of a plurality of discharge lamps, generally, the lamp current flowing through the remaining discharge lamps increases and the lamp voltage at both ends of the series circuit of the discharge lamps tends to increase. As described in the description of item 2, when the discharge lamp is mainly thinned out, the lamp current adjustment impedance is connected in series with the remaining discharge lamp to suppress the increase in the lamp current to a required value. it can.
[0053]
“Mainly when thinning out” means not only when some discharge lamps are thinned out, but also when the discharge lamps are not thinned out, they are connected to the discharge lamp. In some cases, there is little influence on the discharge lamp, and when a part of the discharge lamp is thinned out, a clear lamp current adjusting action is exhibited.
[0054]
When the plurality of discharge lamps connected in series have different rated lamp currents, the lamp current adjusting impedance can be selected so that the rated lamp currents of the discharge lamps that have been thinned out remain.
[0055]
As an aspect of the connection of the lamp current adjusting impedance, there is the following configuration.
[0056]
(1) Connect so as to be connected in parallel to the discharge lamp via a capacitive reactance connected in parallel to the discharge lamp. (See claim 5)
(2) Connect in parallel to the filament electrode of the discharge lamp. (See claim 6)
(3) While being connected in series to the discharge lamp, the capacitive reactance is connected in parallel to the series circuit of the discharge lamp and the lamp current adjusting impedance.
[0057]
A discharge lamp lighting device according to a fifth aspect of the present invention is the discharge lamp lighting device according to any one of the first to fourth aspects, wherein the impedance for adjusting the lamp current is connected in parallel to the discharge lamp via a capacitive reactance. It is characterized by that.
[0058]
In the present invention, the connection position of the lamp current adjusting impedance is defined as a position connected in parallel to the discharge lamp through the capacitive reactance.
[0059]
The present invention is suitable when a plurality of discharge lamps have the same rating. This is because the lamp current adjusting impedance is commonly connected in series to any discharge lamp. However, if necessary, the present invention is allowed to be applied in a mode in which discharge lamps having different rated lamp currents are connected in series.
[0060]
A discharge lamp lighting device according to a sixth aspect of the present invention is the discharge lamp lighting device according to any one of the first to fourth aspects, wherein the pair of electrodes are filament electrodes; the lamp current adjusting impedance is at least It is characterized by being connected in parallel to one filament electrode of some discharge lamps.
[0061]
The lamp current adjusting impedance is connected in series with the remaining discharge lamp together with the capacitive impedance when a discharge lamp having a filament electrode connected at both ends thereof is thinned out. Therefore, the lamp current can be adjusted for each discharge lamp.
[0062]
Further, since the lamp current adjusting impedance is connected in parallel with the filament electrode of the discharge lamp, there is also an effect of adjusting the filament heating current flowing through the filament electrode.
[0063]
In addition, the lamp current adjustment impedance is one or both of some discharge lamps.
It may be connected in parallel to the filament electrode.
[0064]
A lighting device according to a seventh aspect of the present invention includes a lighting device body; and the discharge lamp lighting device according to any one of claims 1 to 6 supported by the lighting device body.
[0065]
The lighting device of the present invention is a broad concept including all devices that use the light emission of a discharge lamp for some purpose. Includes various lighting fixtures, image display devices, germicidal lamp devices, photocatalyst application devices, and the like.
[0066]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0067]
FIG. 1 is a circuit diagram showing a first embodiment of a discharge lamp lighting device according to the present invention.
[0068]
In the figure, AS is a low frequency AC power supply, ab is an AC input terminal, RDC is a rectified DC power supply, SM is a smoothing means, HFI is a high frequency generating means, c and d are high frequency output terminals, and L1 is an inductive reactance for current limiting. DL1 and DL2 are discharge lamps, and C1 and C2 are capacitive reactances.
[0069]
The low frequency AC power supply AS is a commercial 100V AC power supply.
[0070]
The AC input terminals a and b are input terminals as discharge lamp lighting devices that operate by inputting a low-frequency AC power supply.
[0071]
The rectified DC power supply RDC includes a full-wave rectifier circuit, and rectifies a low-frequency AC voltage from the low-frequency AC power supply AS to obtain a non-smooth rectified DC voltage.
[0072]
A noise filter is interposed between the low-frequency AC power supply AS and the rectified DC power supply RDC, but is not shown because it is a conventional means of this kind of discharge lamp lighting device.
[0073]
As the smoothing means SM, an active filter such as a smoothing capacitor, a partial smoothing circuit, or a chopper circuit is used.
[0074]
The high frequency generation means HFI includes a high frequency inverter.
[0075]
The high frequency output terminals c and d are output terminals of the high frequency generating means.
[0076]
The current limiting inductive reactance L1 is formed of a choke coil, and one end thereof is connected to the high frequency output terminal c of the high frequency generating means HFI.
[0077]
Two discharge lamps DL1 and DL2 are connected in series, and are connected between the high-frequency output terminals c and d via a current-limiting inductive reactance L1 in series.
[0078]
The capacitive reactances C1 and C2 are each composed of a capacitor, and one capacitive reactance C1 is connected in parallel to one discharge lamp DL1, and the other capacitive reactance C2 is connected in parallel to the other discharge lamp DL2.
[0079]
Next, circuit operation will be described.
[0080]
When the AC input terminals a and b are connected to the low frequency AC power supply AS, a non-smoothed DC voltage is obtained at the rectified DC power supply RDC, smoothed by the smoothing means SM, and supplied to the input terminal of the high frequency generating means HFI. The
[0081]
The high frequency generation means HFI is activated by applying a smoothed DC voltage, and the high frequency output terminal c. A high frequency output appears between d.
[0082]
Current-limiting inductive reactance L1 and capacitive reactances C1 and C2 cause moderate series resonance. As a result, the terminal voltages of the capacitive reactances C1 and C2 are increased.
[0083]
When the terminal voltages of the capacitive reactances C1 and C2 increase, starting of the discharge lamps DL1 and DL2 is promoted, and one of them starts and lights up. Then, the other discharge lamp is also started and lit.
[0084]
Then, when the discharge lamps DL1 and DL2 are turned on, the capacitive reactances C1 and C2 are substantially short-circuited by the discharge lamps DL1 and DL2.
[0085]
Next, if any discharge lamp, for example DL1, is decimated, The capacitive reactance C1 connected in parallel to the thinned discharge lamp DL1 is connected in series to the capacitive reactance C2. Since a high voltage due to resonance is applied to both ends of the capacitive reactance C2, the discharge lamp DL2 starts and lights up in the same manner as when the thinning is not performed.
[0086]
When the discharge lamp DL2 is thinned out, similarly, a high voltage due to resonance is applied to both ends of the capacitive reactance C1, so that the discharge lamp DL1 similarly starts and lights up.
[0087]
FIG. 2 is a circuit diagram showing a second embodiment of the discharge lamp lighting device of the present invention.
[0088]
In the figure, the same parts as those in FIG. VlD is a lamp voltage detection means, DC is a determination means, and CC is a control means.
[0089]
The present embodiment is different in that the current flowing through the remaining discharge lamps is optimized when some of the discharge lamps are thinned out, and the safety is ensured when the discharge lamp reaches the end of its life. .
[0090]
That is, the lamp voltage detection means V1D is connected to a position for detecting the voltage between both ends of the series circuit of the pair of discharge lamps DL1 and DL2, and controls and inputs the detection output to the determination means DC.
[0091]
The judging means DC produces an output when the output of the lamp voltage detecting means V1D exceeds a preset value, judges that and inputs it to the control means CC.
[0092]
The control means CC controls the drive circuit of the high frequency generation means HFI to reduce the high frequency output when the output from the determination means DC is sent.
[0093]
Therefore, when a part of the discharge lamps DL1, DL2 such as DL1 is thinned out, the detection output of the lamp voltage detection means V1D increases.
[0094]
In the determination means DC, since the detection output exceeds a preset level, a determination output is generated.
[0095]
In the control means CC, the high frequency output is controlled by controlling the high frequency generation means HFI by the control input of the judgment output.
[0096]
As a result, the remaining discharge lamp DL2 is lit alone and at an appropriate lamp current.
[0097]
On the other hand, when one of the discharge lamps reaches the end of its life, the lamp voltage increases, so the output of the lamp voltage detection means V1D increases, and the determination means DC and the control means CC operate in the same manner as described above, and the high frequency generation means. Reduce the output of HFI and protect it safely.
[0098]
FIG. 3 is a circuit diagram showing a third embodiment of the discharge lamp lighting device of the present invention.
[0099]
In the figure, the same parts as those in FIG.
[0100]
This embodiment is different in that a plurality of series circuits of a current limiting inductive reactance L1 and a plurality of discharge lamps DL1 and DL2 are connected in parallel.
[0101]
In this embodiment, the circuit operation is basically the same. That is, thinning-out lighting is possible in each series circuit.
[0102]
FIG. 4 is a circuit diagram showing a fourth embodiment of the discharge lamp lighting device of the present invention.
[0103]
In the figure, the same parts as those in FIG.
[0104]
In the present embodiment, the discharge lamps DL1 and DL2 include filament electrodes F11, F12, F21, and F22, respectively, and the filament heating windings wx, wy, and wz are magnetically coupled to the current-limiting inductive reactance L1. It is different.
[0105]
That is, the filament electrodes F12 and F21 of the discharge lamps DL1 and DL2 are connected in parallel, and the filament heating winding wz is connected in parallel thereto.
[0106]
A filament winding wx is connected to the filament electrode F11 of the discharge lamp DL1.
[0107]
On the other hand, the filament heating winding wy is connected to the filament electrode F22 of the discharge lamp DL2.
[0108]
On the other hand, the capacitive reactance C1 is connected between one ends of the filament electrodes F11 and F12 of the discharge lamp DL1.
[0109]
The capacitive reactance C2 is connected between one ends of the filament electrodes F21 and F22 of the discharge lamp DL2.
[0110]
Thus, the filament electrodes E11, E12, E21, E22 of the discharge lamps DL1, DL2 are heated by the filament windings wx, wy, wz.
[0111]
FIG. 5 is a circuit diagram showing a fifth embodiment of the discharge lamp lighting device of the present invention.
[0112]
In the figure, the same parts as those in FIG.
[0113]
This embodiment is different in that the capacitive reactances C1 and C2 are both connected to one end of the filament electrodes F12 and F21 via the lamp current adjusting impedance Z1 in series.
[0114]
That is, when any one of the discharge lamps DL1 or DL2 is thinned out, the lamp current adjusting impedance Z1 is connected in series to the remaining discharge lamps. For this reason, since the remaining discharge lamp is connected in series with the impedance Z1 for adjusting the lamp current in addition to the capacitive reactance, an increase in the lamp current is suppressed.
[0115]
The above operation is the same regardless of which discharge lamp DL1 or DL2 is thinned out.
[0116]
FIG. 6 is a circuit diagram showing a sixth embodiment of the discharge lamp lighting device of the present invention.
[0117]
In the figure, the same parts as those in FIG.
[0118]
This embodiment is different in that lamp current adjusting impedances Z2 and Z3 are connected in series with the respective discharge lamps DL1 and DL2.
[0119]
That is, the lamp current adjusting impedance Z2 is connected in series between the filament electrode F11 of the discharge lamp DL1 and the current limiting inductive reactance L1.
[0120]
The lamp current adjusting impedance Z3 is connected in series between the filament electrode F22 of the discharge lamp DL2 and the high-frequency output end d.
[0121]
The capacitive reactance C1 is connected in parallel to the lamp current adjusting impedance Z2 and the discharge lamp DL1.
[0122]
Similarly, the capacitive reactance C2 is connected in parallel to the discharge lamp DL2 and the lamp current adjusting impedance Z3.
[0123]
Thus, when the discharge lamps DL1 and DL2 are not thinned out, the lamp current adjusting impedances Z2 and Z3 are inserted in series with the discharge lamps DL1 and DL2.
[0124]
On the other hand, when the discharge lamp DL1 is thinned out, the lamp current adjusting impedance Z3 is connected in series to the discharge lamp DL2. Similarly, when the discharge lamp DL2 is thinned out, the lamp current adjusting impedance Z2 is connected in series to the discharge lamp DL1. That is, the lamp current adjusting impedance Z2 adjusts the lamp current of the discharge lamp DL1 when the discharge lamp DL2 is thinned out. Similarly, the lamp current adjusting impedance Z3 adjusts the lamp current of the discharge lamp DL2.
[0125]
FIG. 7 is a circuit diagram showing a seventh embodiment of the discharge lamp lighting device of the present invention.
[0126]
In the figure, the same parts as those in FIG.
[0127]
In the present embodiment, a lamp current adjusting impedance Z4 is connected in series with each of the discharge lamps DL1 and DL2, and a lamp current adjusting impedance Z5 is connected in parallel to the filament electrode F11 of the discharge lamp DL1. Similarly, a lamp current adjusting impedance Z6 is connected in parallel to the filament electrode F22 of the discharge lamp DL2.
[0128]
The capacitive reactance C1 is connected between the filament electrodes F11 and F12 of the discharge lamp DL1.
[0129]
In addition, a pair of filament windings wx and wy are magnetically coupled to the current limiting inductive reactance L1. The filament winding wx is connected to the filament electrode E12. Similarly, the filament winding wy is connected to the filament electrode E21.
[0130]
On the other hand, the capacitive reactance C2 is connected in parallel to the series part of the lamp current adjusting impedance Z4 and the discharge lamp DL2.
[0131]
Thus, when the discharge lamps DL1 and DL2 are not thinned out, the filament electrodes E11 and E22 pass through the filament heating circuit formed by the filament electrode E11, the capacitive reactances C1 and C2, and the filament electrode E22. Is heated by. The filament electrodes E12 and E21 are heated by the filament windings wx and wy. During the lighting of the discharge lamps DL1 and DL2, the lamp current flows through only the lamp current adjusting impedance Z4 in series.
[0132]
On the other hand, when the discharge lamp DL1 is thinned out, the filament electrode E21 of the discharge lamp DL2 is heated by the filament winding wy, but the filament electrode E22 has a current adjustment impedance Z5, capacitive reactances C1 and C2, and filaments. Heated by the current flowing through the filament heating circuit formed by the path of the electrode E22. During the lighting of the discharge lamp DL2, the lamp current lamp flows through the current adjustment impedance Z5, the capacitive reactance C1, and the lamp current adjustment impedance Z4. Therefore, the lamp current adjusting impedance Z5 may be set so as to adjust the lamp current of the discharge lamp DL2.
[0133]
On the other hand, when the discharge lamp DL2 is thinned out, the lamp current of the discharge lamp DL1 flows through the discharge lamp DL1, the capacitive reactance C2, and the lamp current adjusting impedance Z6. Therefore, the lamp current adjusting impedance Z6 may be set so as to adjust the lamp current of the discharge lamp DL1.
[0134]
The lamp current adjusting impedance Z4 is set so as to adjust the lamp current when the discharge lamps DL1 and DL2 are lit in series.
[0135]
FIG. 8 is a circuit diagram showing an eighth embodiment of the discharge lamp lighting device of the present invention.
[0136]
In the figure, the same parts as those in FIG.
[0137]
In the present embodiment, a filament heating circuit is configured using capacitive reactances C1 and C2 connected in parallel to the discharge lamps DL1 and DL2, and Z7 and Z8 are connected instead of the lamp current adjusting impedance Z4. It is different in point.
[0138]
That is, the filament electrode F11, the capacitive reactance C1, and the filament electrode F12 are connected in series to form the filament heating circuit FHC1 of the discharge lamp DL1.
[0139]
Further, the filament electrode F21, the capacitive reactance C2, and the filament electrode F22 are connected in series to form a filament heating circuit FHC2 of the discharge lamp DL2.
[0140]
In contrast, the lamp current adjusting impedance Z7 is arranged in parallel with the filament electrode F12.
[0141]
The lamp current adjusting impedance Z8 is arranged in parallel with the filament electrode F21.
[0142]
Thus, in the state where the discharge lamps DL1 and DL2 are connected in series, the lamp current adjusting impedances Z5, Z6, Z7 and Z8 do not act at the time of filament preheating, so that the filament heating current is the capacitive reactance C1, C2. Determined by
[0143]
Further, since the lamp current adjusting impedances Z5, Z6, Z7 and Z8 do not act at the time of lighting, the lamp current at this time is determined by the current-limiting inductive reactance L. Note that the influence of the output voltage of the high frequency generation means HFI is ignored.
[0144]
Next, when the discharge lamp DL1 is thinned out, the preheating current at the time of filament preheating is determined by the lamp current adjusting impedances Z5 and Z7 by the capacitive reactances C1 and C2.
[0145]
At the time of lighting, the lamp current is determined by the lamp current adjusting impedances Z5 and Z7 and the capacitive reactance C1.
[0146]
Similarly, when the discharge lamp DL2 is thinned out, the preheating current is determined by the capacitive reactances C1 and C2 and the lamp current adjusting impedances Z8 and Z6. The lamp current at the time of lighting is determined by lamp current adjustment impedances Z8 and Z6 and capacitive reactance C2.
[0147]
In the above description, the shunting action of the filament heating currents of the lamp current adjusting impedances Z5 and Z6 is omitted, but actually the shunting action is achieved according to the values of the impedance and the resistance of the filament electrode.
[0148]
FIG. 9 is a circuit diagram showing a ninth embodiment of the discharge lamp lighting device of the present invention.
[0149]
FIG. 10 is a circuit diagram showing the lamp voltage detecting means.
[0150]
FIG. 11 is a circuit diagram showing the determination means.
[0151]
FIG. 12 is a circuit diagram showing the control means.
[0152]
FIG. 13 is a circuit diagram showing the smoothing means.
[0153]
In each figure, the same parts as those in FIG.
[0154]
This embodiment shows an example of a circuit in which the embodiment shown in FIG.
[0155]
That is, the high frequency generation means HFI is constituted by a one-stone inverter, and the determination means DC is interposed between the lamp voltage detection means V1D and the control means CC,
The smoothing means SM is constituted by a partial smoothing circuit. Hereinafter, the main differences will be mainly described.
[0156]
<About high frequency generation means HFI>
As shown in FIG. 9, the high frequency generation means HFI includes an inductor L2, a switching means Q1, a diode D1, a capacitor C3, a resonance capacitor C4, a supersaturated current transformer SCT, and a gate drive circuit GDC.
[0157]
The inductor L2 is connected in series with the switching means Q1 and connected between the output terminals of the smoothing means SM.
[0158]
The switching means Q1 is composed of a bipolar transistor.
[0159]
The diode D1 is connected in antiparallel between the collector and emitter of the switching means Q1.
[0160]
The capacitor C3 is connected in parallel between the collector and emitter of the switching means Q1.
[0161]
The resonant capacitor C4 is connected in parallel to the series circuit of the inductor L2 and the switching means Q1, and forms a resonant circuit with the inductor L2.
[0162]
In the supersaturated current transformer CT, one end of the primary winding p is connected to the high-frequency output end d, and the other end is connected to the connection point of the inductor L2 and the switching means Q1.
[0163]
The gate drive circuit GDC includes a secondary winding s of supersaturated current transformer CT, capacitors C5 and C6, and MOSFET Q2.
[0164]
One end of the secondary winding s is connected to the base of the switching means Q1.
[0165]
The capacitor C5 has one end connected to the other end of the secondary winding s and the other end connected to the emitter of the switching means Q1.
[0166]
One end of the capacitor C6 is connected to the other end of the secondary winding s.
[0167]
MOSFET Q2 has its drain connected to the other end of capacitor C6 and its source connected to the emitter of switching means Q1. Further, a resistor R11 and a capacitor C12 are connected between the gate and source of the MOSFET Q2.
The series circuit is connected.
[0168]
<About the lamp voltage detection means VlD>
As shown in FIG. 10, the lamp voltage detection means V1D is connected between the connection point of the discharge lamp DL2 and the inductive reactance L1 for current limiting and the emitter of the switching means Q1, and is mainly composed of a voltage doubler rectifier circuit. Yes.
[0169]
That is, resistors R1, R2, capacitors C7, C8, and diodes D2, D3, and D4 are provided. A series circuit of a resistor R1, a capacitor C7, and a diode D2 is connected between the connection point of the discharge lamp DL2 and the current-limiting inductive reactance L1 and the emitter of the switching means Q1.
[0170]
A series circuit of a diode D3 and a capacitor C8 is connected to both ends of the diode D2. Diodes D2 and D3 have antiparallel polarity.
[0171]
A resistor R2 is connected in parallel with the capacitor C8.
[0172]
Thus, a detection output of the lamp voltage is obtained between both ends of the resistor R2, and is input to the determination means DC.
[0173]
Further, the detection output is configured to be control-inputted to the control means CC via the diode D4.
[0174]
<About determination means DC>
As shown in FIG. 11, the determination unit DC includes resistors R3, R4, R5, a Zener diode ZD1, a capacitor C9, a diode D5, and a bipolar transistor Q3.
[0175]
Resistor R3, Zener diode ZD1, and resistors R4 and R5 form a series circuit, with the upper end connected to the positive electrode of smoothing means SM in the diagram of resistor R3, and the lower side in the diagram of resistor R5. Is connected to the negative electrode.
[0176]
A capacitor C9 is connected in parallel with the resistor R5, and further, the base and emitter of the bipolar transistor Q3 are connected.
[0177]
The collector of the bipolar transistor Q3 constitutes the determination output terminal and is connected to the gate of the MOSFET Q2 of the drive circuit.
[0178]
A connection point between the Zener diode ZD1 and the resistor R3 is connected to the output terminal of the lamp voltage detection means V1D through the diode D5.
[0179]
<About control means CC>
The control means CC includes a bipolar transistor Q4, resistors R6, R7, R8, R9, 13, a voltage dividing resistor R10, capacitors C10, C11, a diode D6, and zener diodes ZD2, ZD3.
[0180]
Resistor R6 and zener diodes ZD2 and ZD3 form a series circuit. In the figure of resistor R6, the left end is connected to the positive electrode of smoothing means SM, and the anode of zener diode ZD3 is connected to the negative electrode of smoothing means SM. ing.
[0181]
A series circuit of a resistor 13, a bipolar transistor Q4, a voltage dividing resistor R10, a resistor R7 and a diode D6, a resistor R8, and a capacitor C10 are connected in parallel to the Zener diodes ZD2 and ZD3.
[0182]
A parallel circuit of a resistor R9 and a capacitor C11 is connected between the base of the bipolar transistor Q4 and the negative electrode of the smoothing means SM.
[0183]
<Other configuration>
(1) NF is a noise filter and is interposed between the low-frequency AC power supply AS and the rectified DC power supply RDC.
[0184]
(2) The capacitor C12 is a DC cut capacitor that removes a DC component from the high-frequency output.
[0185]
(3) The discharge lamp DL1 is an FCL30 ring fluorescent lamp. On the other hand, the discharge lamp DL2 is an FCL32 ring fluorescent lamp.
[0186]
(4) Capacitive reactance C1 is 6800 pF and C2 is 6200 pF.
[0187]
(5) The inductive reactance L1 for current limiting is set to a value such that the lamp current becomes the rated lamp current 0.425A of the discharge lamp DL2.
[0188]
(6) The connection point between the resistor R1 and the capacitor C7 of the lamp voltage detection means V1D and the control input terminal of the control means CC are connected via the diode D7, so that the fluctuation of the low-frequency AC power supply voltage is reduced. On the other hand, negative feedback control is performed to reduce the output fluctuation of the high frequency generating means HFI.
[0189]
<About circuit operation>
The circuit operation will be described below mainly with respect to operations relating to the lamp voltage detection means VlD, the determination means DC, and the control means CC.
[0190]
The lamp voltage detection means VlD detects the lamp voltage appearing at both ends of the discharge lamps DL1 and DL2 over each positive and negative half cycle, and an average value thereof appears between both ends of the resistor R2 as a detection output. When the discharge lamps DL1 and DL2 are not thinned out and are normal, the output of the lamp voltage detecting means V1D is small.
[0191]
On the other hand, in the determination means DC, when the potential at the output terminal of the ramp voltage detection means Vld is lower than the potential at the connection point of the resistor R3 and the Zener diode ZD1, since the diode D5 is on, the Zener diode ZD1 does not break down Therefore, there is no determination output, and the bipolar transistor Q3 is in the off state.
[0192]
In the control means CC, the bipolar transistor Q4 operates as an amplifier for class A operation. The voltage dividing output terminal of the voltage dividing resistor R10 is the control output terminal of the control means CC. Further, the control output terminal of the control means CC is connected to the gate of the MOSFET Q2 of the gate drive circuit GDC via a resistor R12.
[0193]
Further, since the power supply voltage fluctuation is negatively fed back to the base of the bipolar transistor Q4 via the diode D7, the output of the high frequency generating means HFI is less fluctuated with respect to the power supply voltage fluctuation via the bipolar transistor Q4. Be controlled.
[0194]
In addition, since the high frequency output is negatively fed back via the diode D4, the protection operation is performed by reducing the output when an excessively high voltage is applied at the start.
[0195]
Furthermore, the control output terminal of the determination means DC is connected to the control output terminal of the control means CC, and when the control output is generated in the determination means DC, the MOSFET Q2 of the gate drive circuit GDC is controlled.
[0196]
Next, when the low-frequency AC power supply AS is turned on, since the resistor R6 and the capacitor C10 form a timer, the continuity of the bipolar transistor Q4 is small until the potential of the capacitor C10 becomes higher due to charging. The divided output voltage of resistor R10 is low. For this reason, since the gate voltage of the MOSFET Q2 is also low, the saturation time of the supersaturation current transformer SCT is accelerated, the oscillation frequency is increased, and the output of the high-frequency generating means HFI is reduced. During this time, the filament electrodes of the discharge lamps DL1 and DL2 are preheated. In FIG. 9, illustration of filament electrodes of the discharge lamps DL1 and DL2 is omitted.
[0197]
When the voltage of the capacitor C10 rises, the constant voltage is applied to the bipolar transistor Q4 by being clamped by the Zener diodes ZD2 and ZD3. At the same time, the preheating time ends, and the conductivity of the bipolar transistor Q4 increases. The high frequency output of the high frequency generation means HFI increases and the discharge lamps DL1 and DL2 are started.
[0198]
By the way, when a part of the discharge lamp, for example DL1, is thinned out, the output voltage of the lamp voltage detecting means V1D becomes high and the Zener diode ZD1 of the judging means CC breaks down, so that the bipolar transistor Q3 is turned on. As a result, the voltage at the voltage dividing output terminal of the voltage dividing resistor R10 of the control means CC is lowered, so that the gate voltage of the MOSFET Q2 of the gate drive circuit GDC is lowered, and accordingly, the saturation time of the supersaturated current transformer SCT is reduced. The output is shortened and the output of the high frequency generating means HFI is reduced. The lamp current of the remaining discharge lamp DL2 is maintained at an appropriate value.
[0199]
In addition, when one of the discharge lamps DL1 and DL2 reaches the end of its life, the control output of the lamp voltage detection means V1D increases, so that the high frequency output of the high frequency generation means HFI can be reduced and protected.
[0200]
<About smoothing means SM>
As shown in FIG. 13, the smoothing means is formed by connecting a series circuit of an inductor L3 and an electrolytic capacitor C13 in parallel with a series circuit of an inductor L2 and a switching means Q1.
[0201]
The circuit composed of the capacitor C14, the diode D8 and the resistor R12 is a snubber circuit that operates and clamps the high voltage applied to the switching means Q1 with the electrolytic capacitor C13.
[0202]
If the constants of the inductor L3 and the electrolytic capacitor C13 are appropriately selected, the amplitude is large in the valley of the half cycle of the low-frequency AC power supply voltage with the switching of the switching means Q1, and conversely, the amplitude is small at the peak. A high frequency oscillating voltage is generated and superimposed on the low frequency AC power supply voltage.
[0203]
This of The high-frequency oscillation voltage causes free oscillation in the closed circuit of the inductor L2 and the resonance capacitor C4 forming the resonance circuit due to the high-frequency switching of the switching means Q1, and at that time, the inductor L3 and the smoothing are applied to the voltage across the resonance capacitor C4. This occurs when the series circuit of the capacitor C13 resonates. Therefore, when the resonance current flows through the diode D1 in the reverse direction with respect to the switching means Q1, and then the polarity is reversed and the resonance current flows through the switching means Q1 in the forward direction, a part of the resonance current flows through the rectified DC power supply RDC. Of diodes D15 to D18 directly flow in from D15 and D16, and a part thereof charges electrolytic capacitor C13 as a high-frequency current.
[0204]
As a result, the electrolytic capacitor C13 is charged with the average value of the high-frequency oscillation voltage to obtain a smoothed DC voltage, and supplies a DC power source to the high-frequency generating means HFI.
[0205]
FIG. 14 is a cross-sectional view showing a cord pendant lighting fixture as an embodiment of the lighting device of the present invention.
[0206]
In the figure, reference numeral 1 denotes a lighting fixture body, and 2A and 2B denote fluorescent lamps as discharge lamps.
[0207]
The lighting fixture body 1 includes a fixture case 1a, a pendant cord 1b, a hooking sealing cap 1c, and a shade 1d.
[0208]
The appliance case 1a has a lower surface bulged and an outer surface formed as a reflective surface, and houses a lighting circuit 1a1, an connector 1a2, a switch unit 1a3, and a nightlight 1a4 including an inverter.
[0209]
Moreover, the instrument case 1a is equipped with the lamp holder 1a5 in the outer periphery. A cord suspension / storage device 1a6 is disposed on the upper surface.
[0210]
The lower end of the pendant cord 1b is drawn into the cord suspension / storage device 1a6 of the instrument case 1a and connected to the connector 1a2. The upper end of the pendant cord 1b is connected to the hooking sealing cap 1c. And a lighting fixture is suspended and used from a ceiling via the pendant cord 1b and the hooking sealing cap 1c.
[0211]
The hanging length of the lighting fixture can be set to a desired hanging height by storing the surplus portion of the pendant cord 1b in the cord hanging / storage device 1a6.
[0212]
The hook ceiling cap 1c can be mechanically and electrically connected to the lighting fixture by attaching and detaching the hook ceiling cap 1c to and from a hook ceiling body that is arranged in advance on the ceiling and connected to a power source.
[0213]
The fluorescent lamp 2A is an FCL30 type, and 2B is an FCL32 type.
[0214]
These fluorescent lamps 2A and 2B are supported by the lamp holder 1a5, and a lamp socket (not shown) is attached to the base pin.
[0215]
The seed 1d is made of a translucent synthetic resin, has a shade shape, and is supported by the instrument case 1a with its upper end locked around the cord suspension / storage device 1a6. The air inside the shade 1d whose temperature has risen due to heat generated by the fluorescent lamps 2A and 2B is discharged out of the lighting fixture through the vent 1d1, thereby being cooled by thermal convection of the room air.
[0216]
【The invention's effect】
According to each of the first to sixth aspects of the present invention, a plurality of discharge lamps are connected in series, connected to the high frequency output terminal of the high frequency generating means via the current limiting inductive reactance, and connected in parallel to each discharge lamp to output the high frequency. Can resonate with current limiting inductive reactance plural With capacitive reactance In the state where some of the discharge lamps are thinned out, the capacitive reactance connected in parallel to the thinned discharge lamps is connected in series to the remaining discharge lamps and connected in parallel to the remaining discharge lamps. The capacitive reactance is in series resonance with the inductive reactance for current limiting and acts so that sufficient voltage appears to start across the remaining discharge lamp. Thus, it is possible to provide a discharge lamp lighting device capable of lighting by thinning out any desired part of the discharge lamps.
[0217]
According to the invention of claim 2, the lamp voltage detecting means of the discharge lamp and the control means b for controlling the output of the high frequency generating means when the detection output of the lamp voltage detecting means exceeds a predetermined value are provided. Thus, it is possible to provide a discharge lamp lighting device that adjusts the lamp current when the discharge lamp is thinned out.
[0218]
According to the invention of claim 3, in addition, since the high frequency generating means is a self-excited oscillation type one-stone inverter using a supersaturated current transformer, the circuit configuration is simple and inexpensive, and the LC resonance circuit is higher. A discharge lamp lighting device that obtains a high-frequency output of a sine wave can be provided.
[0219]
According to the invention of claim 4, in addition, when a part of the discharge lamps is thinned, the lamp current adjustment impedance is provided which is connected in series with the remaining discharge lamps to adjust the lamp current. Thus, a discharge lamp lighting device in which the lamp current of the remaining discharge lamp is adjusted can be provided.
[0220]
According to the invention of claim 5, in addition, the lamp current adjusting impedance is connected in parallel to the discharge lamp through the capacitive reactance, so that a discharge lamp lighting device suitable for a plurality of discharge lamps having the same rating is provided. Can be provided.
[0221]
According to the sixth aspect of the invention, there is provided a discharge lamp lighting device capable of adjusting the lamp current for each remaining discharge lamp by additionally connecting the lamp current adjusting impedance in parallel with the filament electrode of the discharge lamp. be able to.
[0222]
According to the invention of claim 7, it is possible to provide a lighting device having the effects of the inventions of claims 1 to 6.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a first embodiment of a discharge lamp lighting device according to the present invention.
FIG. 2 is a circuit diagram showing a second embodiment of a discharge lamp lighting device of the present invention.
FIG. 3 is a circuit diagram showing a third embodiment of a discharge lamp lighting device of the present invention.
FIG. 4 is a circuit diagram showing a fourth embodiment of a discharge lamp lighting device according to the present invention.
FIG. 5 is a circuit diagram showing a fifth embodiment of a discharge lamp lighting device according to the present invention.
FIG. 6 is a circuit diagram showing a sixth embodiment of a discharge lamp lighting device according to the present invention;
FIG. 7 is a circuit diagram showing a seventh embodiment of a discharge lamp lighting device according to the present invention;
FIG. 8 is a circuit diagram showing an eighth embodiment of a discharge lamp lighting device according to the present invention;
FIG. 9 is a circuit diagram showing a ninth embodiment of a discharge lamp lighting device according to the present invention;
FIG. 10 is a circuit diagram showing the lamp voltage detecting means.
FIG. 11 is a circuit diagram showing the determination means.
FIG. 12 is a circuit diagram showing the control means.
FIG. 13 is a circuit diagram showing the smoothing means.
FIG. 14 is a cross-sectional view showing a cord pendant type lighting apparatus as an embodiment of the lighting device of the present invention.
[Explanation of symbols]
AS ... Low frequency AC power supply
a ... AC input terminal
b ... AC input terminal
RDC ... Rectified DC power supply
SM: Smoothing means
HFI: High frequency generation means
c ... High frequency output terminal
d ... High frequency output terminal
L1 ... Inductive reactance for current limiting
DL1 ... Discharge lamp
DL2 ... Discharge lamp
C1 ... Capacitive reactance
C2: Capacitive reactance

Claims (7)

High frequency generating means;
A plurality of series connected discharge lamps energized by the high frequency output of the high frequency generating means;
A current limiting inductive reactance interposed in series between the high frequency generating means and the discharge lamp;
Capacitive reactance connected in parallel to each discharge lamp, and in parallel with the thinned discharge lamp in a state where some discharge lamps are thinned due to resonance with the inductive reactance for current limiting with respect to the high frequency output The connected capacitive reactance is connected in series to the remaining discharge lamp and connected in parallel to the remaining discharge lamp. a plurality of capacitive reactance you act as a sufficient voltage appears to start to;
A discharge lamp lighting device comprising: Lamp voltage detecting means for detecting the lamp voltage of the discharge lamp;
Control means for controlling the output of the high-frequency generation means when the detection output of the lamp voltage detection means exceeds a predetermined value;
The discharge lamp lighting device according to claim 1, comprising: The discharge lamp lighting device according to claim 1 or 2, wherein the high-frequency generating means is a self-oscillation type monolithic inverter using a saturable current transformer. 4. A lamp current adjusting impedance which is connected in series with the remaining discharge lamps when a part of the discharge lamps is removed and adjusts the lamp current. The discharge lamp lighting device described. 5. The discharge lamp lighting device according to claim 1, wherein the lamp current adjusting impedance is connected in parallel to the discharge lamp via a capacitive reactance. The discharge lamp has a pair of electrodes that are filament electrodes;
The discharge lamp lighting device according to any one of claims 1 to 4, wherein the lamp current adjusting impedance is connected in parallel to at least one filament electrode of the discharge lamp. A lighting device body;
A discharge lamp lighting device according to any one of claims 1 to 6 supported by a lighting device body;
An illumination device comprising:

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