KR100334657B1 - Discharge lamp and lighting device - Google Patents

Abstract

The direct current of the direct current power source E is switched to the high frequency by the inverter circuit 11, and the filaments FLla and FLlb are preheated. In this state, since the discharge detection circuit 12 does not form a closed circuit in direct current, the direct current component is not applied to the capacitor C3, and the capacitor C3 is not charged. When the fluorescent lamp FL1 discharges and lights up, a direct current component is applied to the capacitor C3, and when the voltage is higher than the reference power supply E1, it is determined that the fluorescent lamp FL1 discharges and lights up. When the discharge is detected in a state where preheating is required, the output of the inverter circuit 11 is lowered by negative feedback, and the filaments FL1a and FLlb are preheated again while maintaining the glow discharge state. If it is sufficiently warmed up, the voltage of the reference power supply E1 is increased by a timer or the like, the output of the inverter circuit 11 is increased, and the fluorescent lamp FL1 is started and turned on.

Description

Discharge lamp lighting device and lighting device

In general, a discharge lamp having a filament that is a hot cathode in a valve is hard to escape hot electrons from the filament and is easily damaged when cold started at start-up and lighting. Therefore, the discharge lamp lighting device preheats the filament to take out hot electrons. After making it easy, the discharge lamp is switched on by arc discharge.

That is, the preheating capacitor is connected to the filament of the discharge lamp in parallel, and the discharge lamp lighting device preheats the preheat current by applying a voltage lower than the starting voltage of the discharge lamp before turning on the discharge lamp. After that, the predetermined time is counted by a timer or the like, and after the predetermined time has elapsed, the voltage applied to the discharge lamp is raised to start the discharge lamp. Moreover, the structure which connects the inverter transformer which has a preheating coil to the discharge lamp lighting apparatus, for example, and preheats a filament by this preheating coil is also known.

When the filament of the discharge lamp is preheated, the discharge lamp may be prematurely blacked if the lamp is momentarily turned on due to a difference in starting voltage, or if it is out of the appropriate value due to lack of preheating or preheating conditions.

For this reason, there is a problem that the configuration becomes complicated because the control circuit or the power supply variation compensating circuit for setting the start-up voltage with sufficient margin or controlling the preheating voltage must be added.

Moreover, in order to prevent blackening of the pipe wall of the valve near the filament heated at the time of preheating, some discharge lamps are known that a white ring is mounted around the filament.

On the other hand, in recent years, for example, a narrow diameter discharge lamp having a thin outer diameter of the valve, for example, a valve having an outer diameter of 21 mm or less, has become widespread. As such a small diameter valve, there is almost no gap around the filament, and a ring is mounted. Can not.

Further, even if a ring can be mounted around the filament, for example, there is no emitter applied to the filament due to the preheating of the filament. When the resistance value of the filament rises because the emitter disappears, the distance between the pipe wall of the valve and the filament becomes short, so that a so-called ring sag phenomenon in which the ring itself is melted occurs. Therefore, the discharge lamp whose diameter is thin without a ring is also preheated as usual and then switched to arc discharge to light.

However, if the filament is preheated and reddish, there is no ring around the filament, so red light becomes visible from the outside and is undesirable. In particular, in the discharge lamp whose diameter of the valve is thin, the distance between the filament and the pipe wall of the valve is short, and red light has a problem that stands out.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a discharge lamp lighting device and a lighting device which make the preheating of the discharge lamp with a simple configuration and adequately preheat the filament while making red light of the filament inconspicuous. It aims to do it.

<Start of invention>

The discharge lamp lighting apparatus of the present invention includes discharge lamp lighting means for lighting a discharge lamp having a filament, discharge detection means for detecting discharge of the discharge lamp, and when discharge is detected by the discharge detection means, the output of the discharge lamp lighting means is reduced. Control means for preheating the filament.

The discharge detecting means detects the discharge of the discharge lamp, and when the discharge of the discharge lamp is detected, the control means lowers the output of the discharge lamp lighting means. Therefore, the discharge lamp is discharged before it is sufficiently warmed up, and the start-up is prevented. , Preheat properly.

In addition, the discharge detecting means detects the discharge of the discharge lamp accurately with a simple configuration on the basis of the detection of the DC voltage generated for the first time when the discharge is started at the start.

In addition, the discharge lamp lighting means preheats the filament in a state of undischarging in the discharge lamp, thereby preheating the discharge lamp under stable preheating conditions.

In addition, the discharge detecting means has a filter for removing the lighting frequency of the discharge lamp, and by removing the lighting frequency of the discharge lamp with the filter, the influence of the pulsation of the lighting frequency is eliminated, and the discharge lamp can be accurately discharged with a simple configuration. Detect.

In addition, the discharge lamp lighting apparatus of the present invention includes a switching element for switching, and has an output variable for applying a voltage between the filament and the filament of a discharge lamp having a diameter of 21 mm or less having a pair of filaments and a phosphor installed thereon. An inverter circuit, an inverter control circuit for controlling the switching operation of the switching element to vary the output of the inverter circuit, and discharge detection means for detecting the discharge of the discharge lamp, wherein the set preheating time is between the filaments of the discharge lamp. A discharge voltage is applied to the lamp to discharge the glow, and after the preheating time, a lamp secondary voltage is transferred between the filaments of the discharge lamp to arc discharge, and the discharge is detected by the discharge detecting means. When the inverter control circuit is operated to lower the voltage between the filaments of the discharge lamp. The control circuit is provided.

Then, the inverter circuit is controlled by the inverter control circuit during the set preheating time, and the discharge breakdown voltage is applied between the filaments of the discharge lamp, so that the transition to the weak glow discharge does not damage the filament by the glow discharge. The glow current flows to preheat, and the lamp voltage becomes high in this glow discharge state, and a large preheat current flows to the filament, and the preheating operation of the filament according to the glow discharge causes light emission to the phosphor of the discharge lamp. The red light is not noticeable, and when the preheating time has elapsed, a lamp secondary voltage that transitions to arc discharge is applied between the filaments. The voltage of the lamp is lowered and the discharge lamp is turned on. Since the filament is preheated by emitting a phosphor with a glow discharge that does not damage the filament, the red light of the filament becomes inconspicuous while not damaging the filament.

The inverter circuit has a direct current cut line which is connected to any one of the filament paired with the discharge lamps, the direct current cut line is interposed with a capacitor for direct current cut, and a direct current output line without the direct current cut, and discharge detection means. Has a DC voltage detection section for detecting the DC voltage of the DC cut line, and outputs the voltage according to the voltage value of the DC cut line detected by the DC voltage detection unit. The DC cut line of the inverter circuit has a direct current as discharge starts between the filaments. Since a voltage is generated and the DC voltage detection unit generates this DC voltage, the discharge between the filaments can be detected. Therefore, when the discharge occurs, the output of the inverter circuit can be controlled by the start control circuit and the inverter control circuit.

The inverter circuit has a direct current cut line which is connected to any one of the filaments in which the discharge lamps are paired, the direct current cut line is interposed with a capacitor for the direct current cut, and a direct current output line where the direct current is not cut. Has a first DC voltage detector for detecting the DC voltage of the DC cut line and a second DC voltage detector for detecting the DC voltage of the DC output line, and the difference between the voltages of the first DC voltage detector and the second DC voltage detector. The DC voltage of the discharge lamp is detected by the first DC voltage detection unit and the second DC voltage detection unit by detecting the DC portion of the voltage between the filaments of the discharge lamp. When the difference between the voltages of the first DC voltage detector and the second DC voltage detector decreases, and the discharge between the filaments can be detected In, when the discharge is generated it can directly control the output of the inverter circuit by the start control circuit and an inverter control circuit.

In addition, the inverter circuit has a direct current cut line which is connected to any one of the filaments in which the discharge lamps are paired and interposed with a capacitor for the direct current cut so that the direct current is cut, and the direct current output line where the direct current is not cut. Has an AC voltage detector for detecting the AC voltage of the DC cut line, and outputs the detection amount of the AC voltage detector according to the voltage on the DC cut line by the secondary voltage control of the lamp, when the discharge lamp is lit by discharge. The discharge voltage between the filaments can be detected by detecting the AC voltage of the DC cut line in the AC voltage detector by the presence or absence of the DC portion when the LED is not lit. The output of the inverter circuit can be controlled.

In addition, the DC voltage detector of the discharge detection means includes a DC voltage detector for all-optical light and a DC voltage detector for dimming light with different detection levels. It simply responds to all-optical light and dimming light.

In addition, the DC voltage detection unit for all-lighting has detection level switching means for changing the detection level at the time of preheating and all-lighting, and is a relationship between the detection level for preheating> detection level for dimming> detection level for all-lighting. By varying the detection levels, the preheating, dimming, and total lighting are assuredly detected.

In addition, the discharge detecting means has a current detecting section for detecting the lamp current, and outputs a signal from the current detecting section to the start control circuit at the time when the lamp current is detected. And the lamp current is detected, the output of the inverter circuit is reduced by the start control circuit and the inverter control circuit, thereby preheating the filament to the maximum while maintaining the glow discharge state.

The inverter circuit has a direct current cut line which is connected to any one of the filament paired with the discharge lamps, the direct current cut line is interposed with a capacitor for direct current cut, and a direct current output line where the direct current cut is not cut. End-life detection having a first DC voltage detector connected to a second DC voltage detector connected to a DC output line and outputting a detection amount corresponding to the difference between the voltages of the first DC voltage detector and the second DC voltage detector; And an oscillation stop circuit for stopping the switching operation of the switching element of the inverter circuit on the basis of the stop signal output by the end-of-life detection circuit. The discharge lamp has a first DC voltage detector and Although no difference occurs in the second DC voltage detector, electrons are not detected from either of the filaments when the discharge lamp ends. A half wave discharge condition results in a difference between the DC component detected by the DC cut line and the DC component detected by the current output line. The difference is detected as the end-of-life detection circuit, and the oscillation stop circuit detects the difference. The oscillation operation of the switching element of the circuit is stopped.

In addition, a plurality of inverter circuits are provided in correspondence with discharge lamps of different lamp powers having the same lighting frequency, and have a full-wave rectification circuit for full-wave rectifying a low-frequency alternating current DC voltage. A power supply input circuit commonly connected to a plurality of inverter circuits and a first capacitor having a capacity that does not exhibit a smoothing action against a low frequency voltage, and a first capacitor having a larger capacity than this first capacitor connected to the power input circuit side from the first capacitor. It is connected in parallel between the rectifier diode and the first capacitor in which the cathode of the first capacitor side is switched by the high frequency current caused by reactive power that is connected between the two capacitors, these first capacitors and the second capacitor and regenerated to the input side. With a plurality of low distortion circuits each connected to a front end of said inverter circuit including a series of smoothed capacitors and inductor elements The low distortion circuit is provided at the front end of the inverter circuit, whereby a high frequency current is caused by a high frequency current caused by reactive power that regenerates to the input side when the switching element of the inverter circuit is turned off. The power factor is improved by superimposing the ripple voltage and operating the rectifier diode at the same frequency as the lighting frequency of the inverter circuit over the entire period of the input current, and if there is a difference in the frequency of the lighting frequency of each inverter circuit, Since the switching frequency is different and the vibration occurs to generate a hum, the lighting frequency of each inverter circuit is made the same to prevent the hum from being generated.

In addition, the inverter circuit has a rectifying circuit which is provided in plural in correspondence with a plurality of discharge lamps of different lamp powers having the same lighting frequency and has a different frequency, and has a rectifier circuit for full-wave rectifying the AC power voltage of low frequency. A power supply input circuit commonly connected to the circuit, a first capacitor having a capacity that does not exhibit a smoothing action against a low frequency voltage, a second capacitor connected to the power input circuit side than the first capacitor and having a larger capacity than this first capacitor, A rectifier diode connected between the first capacitor and the second capacitor and switching the cathode on the first capacitor side by a high frequency current based on reactive power regenerated on the input side, and a smoothing capacitor and an inductor connected in parallel to the first capacitor. A plurality of low distortion circuits each connected to the front end of the inverter circuit including a series circuit of elements, and the respective inverters A circuit board having circuits divided into blocks for each block, and a heat sink mounted on the circuit board with switching elements in the inverter circuits at positions skipping between the blocks, wherein a plurality of discharge lamps are provided for each inverter. It is easy to cause interference between each inverter circuit because it is turned on in the circuit, but since each inverter circuit is divided into blocks and mounted on a circuit board, interference between inverter circuits can be prevented, and each inverter circuit is connected to a switching element. Since a heat sink for dissipating the heat generating element is mounted on the circuit board so as to skip each block, interference between switching elements can be reduced, and the wiring in each block can be easily turned.

The lighting apparatus includes a discharge lamp lighting device and a mechanism body in which the discharge lamp lighting device is installed.

The lighting apparatus includes a discharge lamp lighting apparatus and a discharge lamp comprising a plurality of annular fluorescent lamps having a tube diameter of 21 mm or less and different outside diameters exerted by the respective inverter circuits. It is a disk shape that keeps the lamp concentric.

The present invention relates to a discharge lamp lighting device and a lighting device in which preheating to a discharge lamp is appropriate.

1 is a circuit diagram showing an embodiment of the discharge lamp lighting apparatus of the present invention;

2 is an exploded perspective view showing the lighting device;

Fig. 3 is an equivalent circuit diagram showing a state in which the fluorescent lamp does not discharge.

4 is an equivalent circuit diagram showing a state in which the fluorescent lamp is discharged;

Fig. 5 is an equivalent circuit diagram showing a state where the fluorescent lamp is not mounted.

6 is a circuit diagram showing a discharge lamp lighting apparatus of another embodiment;

7 is an exploded perspective view showing a lighting apparatus of another embodiment;

8 is a circuit diagram showing the same discharge lamp lighting apparatus;

9 is a plan view schematically showing an example of installation on the circuit board;

Fig. 10 is a circuit diagram mainly showing one inverter device.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of the lighting apparatus of this invention is described with reference to drawings.

Fig. 2 is an exploded perspective view showing the lighting apparatus, and as shown in Fig. 2, the thin disk-shaped instrument body 1 is attached to the hooked seal not shown by the adapter 2, and this instrument body 1 ) Is attached to a holder body 3 to which the fluorescent lamps FL1 and FL2 as discharge lamps are attached, and these fluorescent lamps FL1 and FL2 together with the holder body 3 have a light transmitting set 4. Covered by. The discharge lamp lighting device 5 is housed in the mechanism body 1.

1 is a circuit diagram showing a discharge lamp lighting apparatus. This discharge lamp lighting device 5 is shown only for the fluorescent lamp FL1. As shown in FIG. 1, this discharge lamp lighting apparatus 5 is connected to the DC power supply E with the inverter circuit 11 as a discharge lamp lighting means, and this inverter circuit 11 has a capacitor for DC cut. One end of the filaments FL1a and FLlb of the fluorescent lamp FL1 is connected via the C1 and the inductor L1, and a starting capacitor C2 is connected between the other ends of the filaments FL1a and FL1b. Connected. In addition, the inverter circuit 11 is configured to increase the output voltage by limiting the set voltage when the voltage of the fluorescent lamp FL1 rises due to a negative point or the like.

Further, a discharge detection circuit 12 as discharge detection means is connected to a connection point between the inductor L1 on the side having the DC cut capacitor C1 and one end of the filament FL1a of the fluorescent lamp FL1. The discharge detection circuit 12 has a low pass filter 14 for removing the AC component of the lighting frequency of the fluorescent lamp FL1, and has a series circuit of the resistor R1 and the resistor R2. The capacitor C3 is connected in parallel with R2). The connection point of the resistor R1 and the resistor R2 is connected to one input terminal of the comparator 15 as a control means, and the other input terminal of the comparator 15 is connected to a reference power source of variable output voltage ( E1) is connected, and the output terminal of the comparator 15 is connected to the inverter circuit 11 through the VFO 16 which changes the oscillation frequency of the inverter circuit 11 in accordance with the voltage.

The same inverter circuit is provided separately for the fluorescent lamp FL2.

Next, operation | movement of the said embodiment is demonstrated. First, the direct current of the DC power supply E is switched to the high frequency by the inverter circuit 11, and the filaments FLla and FL1b of the fluorescent lamp FL1 are preheated. In this state, as shown in the equivalent circuit of FIG. 3, the starting capacitor C2 is connected to the capacitor C1 and the capacitor C2 through the resistors R1a and R1b of the filaments FL1a and FLlb. Since a closed path is not formed by DC directly, DC powder is not applied to the capacitor C3, and the capacitor C3 is not charged.

When the fluorescent lamp FL1 discharges and lights up, as shown in the equivalent circuit of Fig. 4, since the resistor RFL is connected, the resistors RFL, R1 and R2 are connected to each other. When a series circuit is formed and a direct current component is applied to the capacitor C3, and the voltage of the capacitor C3 becomes higher than the reference voltage E1, it can be determined that the fluorescent lamp FL1 is discharged and turned on. In the preheated state of the fluorescent lamps FL1 filaments FL1a and FLlb, the voltage of the reference power supply E1 is kept low.

When the discharge of the fluorescent lamp FL1 is detected while preheating of the filaments FLla and FL1b is required, the output of the inverter circuit 11 is lowered by negative feedback, and the discharge state, the glow discharge, While maintaining the discharge state, the filament preheating current flows through the capacitor C2 to preheat the filaments FL1a and FL1b. After that, when the filaments FL1a and FL1b are sufficiently preheated, the voltage of the reference power supply E1 is increased by a timer or the like, the output of the inverter circuit 11 is increased, and the fluorescent lamp FL1 is started and turned on. On the basis of the reference power supply E1 of the voltage which has risen after the lighting, the end of the life of the fluorescent lamp FL1 is detected. In this way, by sufficiently preheating the filaments FL1a and FL1b while maintaining the glow discharge, it is not necessary to consider the preheat voltage gap and the like, thus eliminating the need for a power supply compensating circuit or a circuit for correcting the gap. Simultaneously, the gap between preheating conditions can be eliminated, the deterioration of the filaments FL1a and FL1b is reduced, and the life of the fluorescent lamp FL1 can be extended. In addition, since the filaments FL1a and FLlb are preheated in a glow discharge state or the like, some brightness can be obtained by the glow discharge, so that even if the preheating time is a little longer, it is difficult to feel uncomfortable that the startup is slow.

In addition, when the filament is preheated, the filament is red because it is glowing, but the red light is alleviated by radiation caused by glow discharge, thereby reducing the discomfort.

On the other hand, in the state where the fluorescent lamp FL1 is not attached, as shown in the equivalent circuit of FIG. 5, the discharge detection circuit 12 is closed by DC by the capacitor C1 and the capacitor C2. Since it is not formed, a direct current component is not applied to the capacitor C3, and the capacitor C3 is not charged. When this state continues for a predetermined time or longer, the fluorescent lamp FL1 is not connected, and the output of the inverter circuit 11 is stopped.

In order to detect the end of the lifetime of the fluorescent lamp FL1, for example, when a half-wave discharge is performed from the filament FL1a of the fluorescent lamp FL1 toward the filament FL1b, a charge is applied to the capacitor C3 in the same manner. When the voltage of the capacitor C3 becomes higher than the voltage of the reference power supply E1, the output of the inverter circuit 11 is reduced or stopped as the end of the lifetime of the fluorescent lamp FL1.

On the other hand, when half-wave discharge is performed from the filament FL1b of the fluorescent lamp FL1 toward the filament FLla, the voltage of the capacitor C3 is reversed, and the voltage of the capacitor C3 is the voltage of the reference power supply E1. Since the output is not higher than the voltage, the output of the inverter circuit 11 does not decrease depending on the output of the comparator 15. However, when the voltage of the fluorescent lamp FL1 rises, the inverter ends the life of the fluorescent lamp FL1. The circuit 11 lowers or stops the output.

In addition, another embodiment will be described with reference to FIG. 6.

FIG. 6 is a circuit diagram showing a discharge lamp lighting apparatus according to another embodiment. In the embodiment shown in FIG. 6, in the embodiment shown in FIG. 1, one inverter circuit 11 includes two fluorescent lamps FL1, The FL2 is connected, and the discharge detection circuit 12 is connected to each of the fluorescent lamps FL1 and FL2.

As the control method of the inverter circuit 11, in the preheating, the two fluorescent lamps FL1 and FL2 may be controlled at the same time, but a state such as the end of a lifetime has occurred in any one of the fluorescent lamps FL1 and FL2. In this case, the control may be performed to stop the output of only the corresponding fluorescent lamps FL1 and FL2. Also, the preheating may be set differently in correspondence with the respective fluorescent lamps FL1 and FL2.

Also in any of the embodiments, as a method of detecting discharge, the filament preheating current may be canceled by a transformer or the like, or may be detected by a portion where the filament preheating current does not flow. In this case, since the detected value becomes the discharge amount, it is effective to detect by peak detection or the like.

In addition, the method of reducing the output of the inverter circuit 11 is not limited to changing the frequency, and the output may be controlled by switching the duty ratio.

In either of the discharge lamp lighting devices 5, the discharge detection circuit 12 detects the discharge of the fluorescent lamps FL1 and FL2, and when the discharge of the fluorescent lamps FL1 and FL2 is detected, the comparator 15 Since the output of the inverter circuit 11 is lowered, it is possible to discharge the fluorescent lamps FL1 and FL2 before they are sufficiently preheated, to prevent starting-up and prevent the preheating, and thus the fluorescent lamps FL1 and FL2 Long life can be achieved.

In addition, since the discharge detection circuit 12 is not directly connected to the inverter circuit 11, the direct current component is cut out of the current flowing through the discharge detection circuit 12, so that the fluorescent lamps FL1 and FL2 can be accurately and accurately. The discharge of can be detected.

In addition, the inverter circuit 11 preheats the filaments FL1a, FLlb, FL2a, and FL2b while keeping the fluorescent lamps FL1 and FL2 in an undischarged state, so that some brightness can be obtained and at the same time a stable preheating condition is achieved. The lamps FLl and FL2 can be preheated.

In addition, since the discharge detection circuit 12 has a low pass filter 14 for removing the lighting frequencies of the fluorescent lamps FL1 and FL2, the fluorescent lamps FL1 and FL2 are turned on by the low pass filter 14. By removing the frequency, it is possible to remove the influence of the pulsation of the lighting frequency and to accurately detect the discharge of the fluorescent lamps FL1 and FL2 with a simple configuration.

Next, another embodiment will be described with reference to the drawings.

Fig. 7 is an exploded perspective view showing an illuminating device. The illuminating device shown in Fig. 7 is a hot cathode discharge lamp in the illuminating device shown in Fig. 2. The other three rings, for example, 20W fluorescent lamp FL1, 27W fluorescent lamp FL2 and 34W fluorescent lamp FL3 are kept concentrically. In addition, these fluorescent lamps FL1, FL2, and FL3 are held as holders (not shown) because they require attention in handling with a thin tube type. In addition, a circular opening 22 is formed in the central portion of the instrument body 1, and the reflection cover 23 is mounted at a position corresponding to the opening 22. As shown in FIG. In addition, even if the diameter is 21 mm or less, if the diameter is thinner than 15 mm, it is weak in strength and imparts practical attention more than necessary, and it is preferable to have a diameter of 15 mm or more. Also, none of the fluorescent lamps FL1, FL2, FL3 have rings for preventing blackening.

Fig. 8 is a circuit diagram showing a discharge lamp lighting device. The discharge lamp lighting device 31 shown in Fig. 8 is a full-wave rectification circuit 32 for full-wave rectification to a commercial AC power source e having a frequency of 50 Hz or 60 Hz at a power supply voltage of 100V. ) Is connected to constitute a power input circuit 33. Further, a filter circuit may be connected to the commercial AC power supply e that becomes the input side of the full-wave rectifying circuit 32.

Then, in the power input circuit 33, an inverter device for a fluorescent lamp drive device (34 ₁₎ for (Fl1), a fluorescent lamp inverter apparatus (FL2) (34 ₂₎ and a fluorescent lamp (FL3) (34 ₃ Are connected in parallel with each other, and the power supply input circuit 33 is shared by these inverter devices 34 ₁ , 34 ₂ , and 34 ₃ .

In addition, these inverter device (34 _1, 34 _2, 34 _3), jeowae for reducing the high-frequency circuits (35 _1, 35 _2, 35 _3), and for example, an inverter circuit of the reactive power regenerative Dinner (36 ₁ , 36 ₂ , and 36 ₃ ), and each outputs at a frequency of 45 kHz.

These low distortion circuits 35 ₁ , 35 ₂ , 35 ₃ each have substantially the same circuit configuration, and among the output terminals of the full-wave rectifying circuit 32, the choke coil L11, which is an inductor element, and a diode for rectification ( The series circuit of the D11 and the first capacitor C11 is connected, and at the same time, the second capacitor C12 is connected to the input side from the first capacitor C11 via the choke coil L11, and to the first capacitor C11. In parallel, the choke coil L12 as the inductor element and the smoothing capacitor C13 are connected. In addition, the first capacitor C11 has a small capacity of substantially no smoothing effect on the low frequency which is the frequency of the commercial AC power supply e, and the second capacitor C12 functions as a power factor improvement. The capacitance of the two capacitors C12 is set to be sufficiently larger than that of the first capacitor C11.

Inverter circuits 36 ₁ , 36 ₂ , and 36 ₃ also have substantially the same configuration, but are not shown, but include transistor Q11 as a switching element, for example, by current transformer feedback. Discharge detection circuits are provided as detection means, and the fluorescent lamps FL1, FL2, and FL3 are turned on at the same frequency, respectively.

In addition, these inverter circuits 36 ₁ , 36 ₂ , 36 ₃ are each fluorescence through a DC output line 38 without a direct current cut and a DC cut line 39 through a capacitor for a DC cut not shown. It is connected to the filaments FLla, FL1b, FL2a, FL2b, FL3a, and FL3b of the lamps FL1, FL2, and FL3.

Next, installation of the discharge lamp lighting apparatus 31 is demonstrated with reference to FIG.

FIG. 9 is a plan view showing a circuit board on which a discharge lamp lighting device is mounted. As shown in FIG. 9, the upper surface side of the instrument body 1 corresponds to the instrument body 1 and the opening 21. The circuit board 41 formed in the shape of a magnet is attached. In addition, on the circuit board 41, circuit components constituting the power input circuit 33 and the inverter devices 34 ₁ , 34 ₂ , and 34 ₃ , respectively, are sequentially blocked as blocks B1, B2, B3, and B4. It is mounted separately.

Further, an aluminum heat sink as a heat sink that protrudes toward the opening 21 side of the mechanism body 1 at the boundary portion of the blocks B1, B2, B3, and B4 of the circuit board 41. (42, 43) are attached to the mechanism body 1 in a grounded state, and the heat sinks (44) and inverter devices (34 ₁ , 34 ₂ ) of the power input circuit (33) are attached to these heat sinks (42, 43). And transistor ₃ are each attached.

When the heat generating element 44 and the transistor Q1 generate heat, heat is radiated by the heat sinks 42 and 43.

In addition, in the mechanism body 1, since the temperature near the opening 21 is considered to be the lowest, the heat sinks 42 and 43 can dissipate heat efficiently, and the temperature of the heat generating element 44 and the transistor Q1 is reduced. A rise can be suppressed, and mutual interference by heat between the heat generating element 44 and each transistor Q1 can also be suppressed.

Further, as each drive device (34 _1, 34 _2, 34 ₃₎ has even easy circumstances and independently of the operation to mutual interference, and the circuit board 41. On the block is mounted on the dividing block as (B1, B2, B3, B4) Therefore, the influence of interference can be minimized. In addition, since the mounting positions of the heat generating element 44 and the transistor Ql1 are located in each of the blocks B1, B2, B3, and B4, the positions of the heating element 44 and the transistor Ql1 are inclined to one side from the center, respectively, but the pulling of the wiring is easy.

Next, operation | movement of the said embodiment is demonstrated.

First, when the AC voltage of the commercial AC power supply is full-wave rectified by the full-wave rectifying circuit 32, the low frequency circuits are reduced by the respective low distortion circuits 35 ₁ , 35 ₂ , and 35 ₃ .

That is, the high frequency ripple voltage is generated by the series resonance with the choke coil L12 in the first capacitor C11 by the high frequency current generated from the respective inverter circuits 36 ₁ , 36 ₂ , 36 ₃ . D11) is switched at a high frequency to improve the power factor, and at the same time, the capacitor C3 smoothes over the entire range of the input current.

When the voltage at both ends of the first capacitor C11 is set to VC11 and the voltage at both ends of the second capacitor C2 is set to VC12, the rectifying diode D11 switches by the high frequency ripple voltage of the voltage VC11. On the other hand, for the voltage VC12 of the second capacitor C12, when the capacity of the first capacitor C11 is CC11 and the capacity of the second capacitor C12 is CC12, the capacity relationship is CC11 &lt; Even if it is regarded as the voltage of the input circuit 33, there is no particular problem, so the voltage VC12 = the voltage of the power input circuit 33.

For example, electric current flows from the full-wave rectifier circuit 32 to the inverter circuits 36 ₁ , 36 ₂ , and 36 _{3 in} the section of the voltage VC12 = the voltage VC11, that is, the section in which the diode D11 is on. Even in the so-called valley portion where the input voltage is low in the rectified waveform, current flows when the diode D11 is turned on, thereby improving the power factor.

On the other hand, since the current does not flow from the full-wave rectifying circuit 32 to the inverter circuits 36 ₁ , 36 ₂ , 36 _{3 in} the section of the voltage VC12 <VC11, that is, the section in which the diode D1 is off, the waveform is full-wave rectified. If the on-time of the diode D11 is shortened in the so-called acid portion of the high input voltage, the peak current to the capacitor C13 is suppressed. That is, when the interval of the voltage VC12 &lt; voltage VC11 becomes long, deformation of the input current can be suppressed.

Then, the capacitance of the first capacitor C11 is reduced to resonate in series with the choke coil L12 to cause high frequency ripple, and the pressure rise and fall of the voltage VC11 are repeated, whereby the voltage VC12 &lt; the period of the voltage VC11 is formed, and the voltage VC11 is the inverter circuit and the step-up being a reactive power regenerated from the (36 _1, 36 _2, 36 _3), the drive circuit (36 _1, 36 _2, 36 ₃₎ on to the back power Forced down by In other words, when viewed at a high frequency, the impedance of the choke coil L12 is sufficiently larger than that of the first capacitor C1, so that the reactive power from the inverter circuits 36 ₁ , 36 ₂ , 36 ₃ is reduced to the first capacitor C11. Is regenerated, the voltage VC11 is stepped up. At the same time, there is also the charge of the first capacitor C1 from the capacitor C13 through the choke coil L12, and the voltage VC11 is boosted. On the other hand, when the current according to the charging charge of the voltage VC11 flows to the inverter circuits 36 ₁ , 36 ₂ , 36 ₃ as the load, the voltage VC11 is stepped down and when the voltage VC11 = voltage VC12 as the pressure drops, the diode D11 becomes On, current flows from the full-wave rectifier circuit 32 to the inverter circuits 36 ₁ , 36 ₂ , 36 ₃ .

In this way, the charging current flowing into the capacitor C3 as long as the interval of the voltage VC12 &lt; voltage VC11 in the place where the peak voltage of the input voltage of the power input circuit 33 is high, that is, the on-duty of the diode D11 is low. Therefore, the step-up of the first condenser C11 is reduced from the choke coil L12 and the condenser C13 to the first condenser C11 and from the inverter circuits 36 ₁ , 36 ₂ , 36 ₃ . Since the reactive power of one capacitor C11 is regenerated, it becomes important whether the off period of the diode D11 can be lengthened.

In addition, the inverter circuits 36 ₁ , 36 ₂ , and 36 ₃ change the on and off frequencies of the transistors Q11 to change the lighting frequencies of the fluorescent lamps FL1, FL2, and FL3, By increasing the on / off frequency, the voltage applied to the fluorescent lamps FL1, FL2, and FL3 decreases, and conversely, by lowering the frequency, the voltage applied to the fluorescent lamps FL1, FL2, and FL3 increases.

Furthermore, the power inverter circuit 33 is shared, and each of the low distortion circuits 35 ₁ , 35 ₂ , 35 ₃ is provided at the front end of each inverter circuit 36 ₁ , 36 ₂ , 36 ₃ . Each fluorescent lamp FL1, FL2, FL3 is turned on by using ₁ , 34 ₂ , 34 ₃ in parallel.

In addition, the circuit constants of the inverter circuits 36 ₁ , 36 ₂ , 36 ₃ are set such that the frequency difference of the inverter devices 34 ₁ , 34 ₂ , 34 ₃ is equal to O, that is, all the lighting frequencies are the same.

In this way is not a humming sound generated due to the frequency difference by the respective inverter circuits (36 _1, 36 _2, 36 ₃₎ at the same frequency, there is no il objectionable to the user. On the other hand, for example, when the lighting frequencies of the respective inverter circuits 36 ₁ , 36 ₂ , 36 ₃ are set to different frequencies, these frequency differences appear as the frequency differences of the respective diodes D1 that switch to the lighting frequency. Thus, in some diodes D11, a large amount of input current flows in any of the corresponding inverter circuits 36 ₁ , 36 ₂ , 36 ₃ , and in some other diodes D11, any of the inverter circuits 36 ₁ corresponding to the input currents. , 36 ₂ , 36 ₃ ) does not flow much, and there is a difference in the input current. Since the influence of this state difference, that is, the frequency difference causes the vibration through the power input circuit 33 common to all the low distortion circuits 35 ₁ , 35 ₂ , 35 ₃ , a buzzing sound is generated to the outside.

In the preheating step before the fluorescent lamps FL1, FL2, and FL3 are switched to the lighting state by arc discharge, the discharge breakdown voltage is such that the filaments FL1a, FL2a, FL3a, FLlb, FL2b, and FL3b are not damaged. Is continuously applied to obtain an undischarged glow discharge, whereby a preheating current caused by a glow current flows through the filaments FL1a, FL2a, FL3a, FLlb, FL2b, and FL3b so that the filaments FL1a, FL2a, FL3a, FLlb, and FL2b And FL3b) part to glow light, and it is made to transition to arc discharge.

Here, the fluorescent lamps FLl, FL2, and FL3 maintain the glow discharge state when the voltage applied between the filaments FL1a, FL2a, FL3a, FLlb, FL2b, and FL3b is a predetermined voltage, but when the voltage is too high, an arc discharge occurs. Transitions to the lit state. In addition, if the filament (FL1a, FL2a, FL3a, FLlb, FL2b, FL3b) is not sufficiently warm, transition to arc discharge will damage the filament (FL1a, FL2a, FL3a, FLlb, FL2b, FL3b) and conversely, glow discharge If the glow current flowing through the filament (FL1a, FL2a, FL3a, FLlb, FL2b, FL3b) is too small, the amount of light emitted from the phosphor is too small to remove the red light of the filament (FL1a, FL2a, FL3a, FLlb, FL2b, FL3b). No effect is obtained. Therefore, it is important to maintain the undischarged properly at the current level of the glow discharge before the transition to the arc discharge, and to apply an applied voltage value that maintains the glow discharge at the time of preheating, that is, the discharge breakdown voltage value or the time, that is, the preheating time. This sequence is preset.

Therefore, even if the fluorescent lamps FL1, FL2, and FL3 are thin tube types having no rings around the filaments FL1a, FL1b, FL2a, FL2b, FL3a, and FL3b, the filaments FL1a, FL1b, When the filaments FL1a, FL1b, FL2a, FL2b, FL3a, and FL3b are heated to generate heat during the preheating operation of FL2a, FL2b, FL3a, and FL3b, red light becomes difficult to see from the outside.

Next, another embodiment will be described with reference to FIG. 10.

Figure 10 is a circuit diagram of one inverter device as a subject, three of the drive of Figure 8 device (34 _1, 34 _2, 34 ₃₎ only represents one of the drive device (34 _1), the drive devices (34 _2, 34 ₃ ) are omitted, and portions corresponding to those shown in FIG. 8 are given the same reference numerals as in FIG. 8.

The filter circuit 52 is connected to the commercial AC power supply e through the terminal blocks 50 and 51 and the fuse F. As shown in FIG. The filter circuit 52 has a constant voltage element Z1, a capacitor C21, and a transformer Tr11. An input terminal of the full-wave rectification circuit 32 is connected to the filter circuit 52, and the full-wave rectification is performed. In the circuit 32, four diodes D21, D22, D23, and D24 are formed in a bridge shape, and a constant voltage element Z2 and a capacitor C22 are connected between the output terminals of the full-wave rectifier circuit 32. . The power supply input circuit 33 is constituted by the commercial AC power supply e, the filter circuit 52, the full-wave rectifying circuit 32, and the like.

In addition, the inverter device (34 ₁₎ connected to the power input circuit 33, the drive device (34 ₁₎ is, for jeowae circuit (35 ₁₎ and the example of the prior smoothing method of the high-frequency measures one Dinner of the reactive power a hybrid having an inverter circuit (36 ₁₎ of the regenerative type.

The low distortion circuit 35 ₁ is connected between the output terminal of the full-wave rectifying circuit 32 by a choke coil L11 serving as an inductor element, a series circuit of a diode D11 for rectification, and a first capacitor C11. At the same time, the second capacitor C12 is connected to the input side of the first capacitor C11 via the choke coil L11, and the choke coil L12 as the inductor element in parallel to the first capacitor C11, and smoothing. Capacitor C13 is connected. In addition, the first capacitor C11 has a small capacity such that substantially no smoothing action occurs at the low frequency, which is the frequency of the commercial AC power supply, and the second capacitor C12 functions to improve the power factor. The capacitance of the two capacitors C12 is set to be sufficiently larger than that of the first capacitor C11.

In addition, having an inverter circuit (36 _1), the first capacitor (C11) in series resonant circuit 53 consisting of a series circuit of a resonance inductor (L21) and the resonance capacitor (C25) for for in parallel, the capacitor ( In parallel to C25, a transistor Q11 as a switching element and a diode D25 for reflux are connected. In addition, a series circuit of the diode D26 and the capacitor C26 is connected between the connection point of the inductor L21 and the transistor Q11 and the connection point of the choke coil L12 and the capacitor C13 to form a capacitor ( In series with C26, a series circuit of a resistor R21, a resistor R22 and a resistor R23 is connected.

In addition, a series circuit of the resistor R24, the capacitor C27, and the resistor R25 is connected in parallel with the capacitor C12, and the connection point of the resistor R24 and the capacitor C27 is the trigger element Q21. It is connected to the base of the transistor Q11 through.

One end of the inductor L21 is connected to the resistor R24 and the trigger element Q21 via the DC output line 38. The diode D27 and the current transformer CT11 of the DC cut line 39 are connected to each other. Is connected to a terminal 54 through an input coil CT11a, a capacitor C28 for direct current cutting, and a burst choke L25, and the terminal 54 has a filament FL1a and a filament of a fluorescent lamp FL1. One end of each of the FL1b is connected, and the other end of the filament FL1a and the filament FL1b are connected to the starting capacitor C29 via the terminal 54.

In addition, a series circuit of the diode D31 and the resistor R26 is connected between the base and the emitter of the transistor Q11, and at the same time, the output coil CT11b, the capacitor C32, and the electric field effect of the current transformer CT11. The series circuit of the transistor Q22 is connected. In addition, a series circuit of the capacitor C33 and the capacitor C34 is connected between the collector and the emitter of the transistor Q11, and the connection point of these capacitors C33 and C34 is the base of the transistor Q23. The diode D35 is connected between the base and the emitter of the transistor Q23, and the collector is connected to the transistor Q11 via the diode D36. Further, the drain and the source of the field effect transistor Q24 are connected to the collector and emitter of the transistor Q23, and a series circuit of the resistor R27 and the zener diode ZD11 is connected in parallel to the capacitor C13. The gate of the field effect transistor Q24 is connected to the connection point of the resistor R27 and the zener diode ZD11.

In addition, a series circuit of the capacitor C36 and the diode D36 is connected to the DC cut line 39 through a resistor R31 and a resistor R32, and the diode D37 and the capacitor are connected to the diode D36. A series circuit of (C37) is connected to constitute an AC voltage detector 55.

In addition, a series circuit of the resistor R34 and the resistor R35 is connected, and the capacitor C38 is connected in parallel with the resistor R35 to form the first DC voltage detector 56.

In addition, a series circuit of a resistor R36, a resistor R37, a variable resistor R38 and a resistor R39 is connected, and these resistors R36, a resistor R37, a variable resistor R38 and a resistor R39 are connected. Condenser C39 is connected in parallel to each other to form a DC voltage detection unit 57 for dimming.

In addition, a series circuit of the Zener wire ZD12 as a switching means for switching the level between the resistor R41, the resistor R42, the resistor R43, the resistor R44 and dimming and all-optical light is connected. The DC voltage detector 58 is configured.

In addition, the direct current output line 38 having the filament FL1a of the fluorescent lamp FL1 is connected through a series circuit of the resistor R45, the resistor R46, and the resistor R47, so that the resistor R48 and the resistor ( A series circuit of R49 is connected, and a capacitor C40 is connected in parallel to the resistor R49 to form a second DC voltage detection unit 59.

Moreover, it has a terminal 61, and this terminal 61 is connected to the commercial alternating current power supply e which interposed the fuse F via the jumbo wire 62 and the night light 63. As shown in FIG.

In addition, the terminal 64 for mode switching has a dimming terminal portion DIM, an on / off terminal portion (on / off) and a ground terminal portion GND, and the dimming terminal portion has a resistor R41. And the capacitor C42 are connected between the on / off terminal portion and the ground terminal portion, and the capacitor C42 and the capacitor C43 are connected between the dimming terminal portion and the ground terminal portion. It is connected in parallel, and the series circuit of the resistor R52 and the resistor R53 is connected in parallel with this capacitor C43, and the base of the transistor Q26 is connected to the connection point of the resistor R52 and the resistor R53. The emitter of the transistor C26 is connected to the ground terminal of the terminal 64, the collector of which is connected to the base of the transistor Q27, and the base of the transistor Q27 is connected to the resistor R54 and the resistor. Is connected to the connection point of R55, and the resistor R54 is connected via the resistor R56 and the diode D41. It is connected to the dimming terminal of the ruler 64.

In addition, a series circuit of a programmable non-transaction transistor Q28 and a resistor R57 is connected between the on / off terminal portion and the grand terminal portion of the terminal 64 with the diode D41 interposed therebetween. The parallel circuit of the capacitor C44 and the resistor R58 is connected between the cathode and the gate of the operation transistor Q28, and the gate of the programmable transistor Q28 connects the resistor R59. Connected to the collector of transistor Q29, the emitter of transistor Q29 is connected to the ground terminal of terminal 64, and between the base and emitter of transistor Q29, capacitor C45 and a resistor ( The parallel circuit of R61 is connected, and the base of the transistor Q29 is connected to the series circuit of the resistor R62 and the Zener diode ZD13, and the Zena diode ZD13, the resistor R62 and the resistor R61 are connected. The capacitor C46 is connected in parallel with the series circuit. In addition, the connection point of the zener diode ZD13 and the capacitor C46 is connected to the connection point of the resistor R34 and the resistor R35 via the diode D42, and the connection point of the zener diode ZD13 and the diode D42 is connected. The silver is connected to the collector of transistor Q31, and the base is connected to the connection point of resistor R34 and resistor R35 via diode D43 to constitute end-of-life detection circuit 65. have.

The capacitor C47 is connected between the connection point of the diode D41 and the resistor R56 and the ground terminal portion of the terminal 64. In addition, the connection point of the diode D41 and the resistor R56 is connected to the gate of the field effect transistor Q22 via the resistor R65 and to the cathode of the full-wave rectifying circuit 32 via the capacitor C48. It is. In addition, the connection point of the diode D41 and the resistor R56 is connected to the base of the transistor Q31 via the resistor R66, and the resistor R67 and the capacitor C51 are connected to the base and emitter of the transistor Q31. Parallel circuits are connected.

The series circuit of the Zener diode ZD15 and Zener diode ZD16 serving as the reference voltage source and the capacitor C52 are connected in parallel to the capacitor C47 via the resistor R56, and the resistor R56 is connected in parallel. ) And the Zener Diet ZD13 are connected with a resistor R71.

In addition, a series circuit of the resistor R72 and the resistor R73 is connected in parallel with the capacitor C47, the capacitor C53 is connected in parallel with the resistor R73, and the capacitor C52 is connected in parallel. The series circuit of the resistor R74 and the capacitor C54 is connected, and the base of the transistor Q32 is connected to the connection point of the resistor R72 and the resistor R73, and the collector of the transistor Q32 is connected to the resistor ( It is connected to the connection point of R74) and the capacitor | condenser C54, and an emitter is connected to the ground terminal part of the terminal 64. As shown in FIG.

In addition, a series circuit of the capacitor C55 and the capacitor C56 is connected in parallel with the capacitor C52, the diode D41 is connected in parallel with the capacitor C56, and in parallel with the capacitor C56. The resistor R76 is connected. The base of the transistor Q33 is connected to the connection point of the capacitor C55 and the capacitor C56, and the emitter of the transistor Q33 is connected to the resistor R56 via the resistor R77. Is connected to the connection point of the resistor R47 and the resistor R48, and the collector is connected to the ground terminal of the terminal 64 via the resistor R78 and the diode D42.

In addition, the base of the transistor Q33 is connected to the connection point of the diode D37 and the capacitor C37 through the diode D43 and the zener diode ZD17, and in parallel with the resistor R76, the diode D44. And a series circuit of the capacitor C57 are connected. The capacitor C58 is connected in parallel with the capacitor C57, and is connected to the collector of the variable resistor R38 and the transistor Q27.

It is also connected to the variable resistor R42 via the diode D45. In addition, the diodes D43, D44, and D45 constitute an OR circuit, and detect the detection level for dimming, the detection level for all-optical light, and the detection level for pre-heating. The detection level is lowered in the order of the level, the detection level for dimming, and the detection level for all light, the detection level for the highest preheating is given the highest priority, and the detection level is given priority in order of the highest detection level.

In addition, the start voltage control unit 55 constitutes the AC voltage detector 55, the DC voltage detector 57 for dimming, and the DC voltage detector 58 for all light.

Next, the operation of the embodiment shown in FIG. 10 will be described. In addition, basic operation | movement is substantially the same as embodiment shown in FIG.

First, in the all-optical mode, the dimming terminal is connected from the ground terminal to the terminal 64 for mode switching, and the base current is supplied to the transistor Q27 without supplying the base current to the base of the transistor Q26. Q27) turns on and bypasses the diode D44 to invalidate the detection level of the diode D44.

When the power is turned on, the capacitor C44 is charged, and as the preheating time when the capacitor C44 reaches a predetermined voltage, the transistor Q33 is turned off, and as the direct current voltage detection unit 58 for all light, Zener is used. ZD12 becomes effective, and the detection level of the variable resistor R32 becomes the detection level for preheating.

In this state, and the inverter circuit (36 _1), a predetermined oscillation operation, applies a voltage to a high frequency voltage through a DC output line 38 and the direct-current cutting line (39) with respect to the fluorescent lamp (FL1). In addition, since no voltage is applied to the gate of the field effect transistor Q22, the impedance between the source and the drain of the field effect transistor Q22 becomes very high, and the capacitor C32 is not electrically connected. filaments of only the connection is reduced, the combined capacitance on the surface, and an inverter circuit (36 ₁₎ increases the frequency output voltage is lowered, a voltage is applied such that the discharge breakdown voltage to the fluorescent lamp (FL1), a fluorescent lamp (FL1) ( Glow discharges between FL1a and FL1b). This glow discharge causes a glow discharge in the fluorescent lamp FL1, and a preheat current by the glow current flows between the filaments FL1a and FL1b through the condenser C39 for preheating. The preheating current causes the filaments FL1a and FL1b of the fluorescent lamp FL1 to be preheated to give a reddish color. However, since the phosphor of the fluorescent lamp FL1 also emits light by glow discharge, the red light is relatively erased. Not very noticeable from the outside, the red light of the filament (FLla, FL1b) is not noticeable, do not give anxiety to the user.

In addition, the inverter circuit (36 _1), by the gate voltage of the field effect transistor (Q22) decreases, increasing the impedance between drain and source of the field effect transistor (Q22), the synthesis of the capacitor (C31) and the capacitor (C32) capacity is reduced to, and the saturation time of a current transformer (CT11) quickly, the lighting frequency of the transistor (Q11) is put the high-frequency output of the inverter circuit (36 ₁₎ is reduced. On the contrary, as the gate voltage of the field effect transistor Q22 is increased, the impedance between the drain and the source of the field effect transistor Q22 is lowered, and the combined capacitance of the capacitors C31 and C32 is increased, resulting in a current transformer. the saturation time is delayed a time (CT11), and to the lighting frequency of the transistor (Q11) reduced increase in the high frequency output of the inverter circuit (36 _1).

Thereafter, when the potential of the capacitor C34 reaches a predetermined potential and the preheating time ends, a base current is supplied to the base of the transistor Q33 to turn on the transistor Q33, and the zener diode ZD12 is short-circuited. The detection level of the DC voltage detector 58 is changed to a detection level for all-optical light at a low level. In addition, as the base current of the transistor Q33 increases, the gate voltage of the field effect transistor Q22 is increased, and conversely, the gate current of the field effect transistor Q22 is lowered by decreasing the base current of the transistor Q33. do. In addition, before the fluorescent lamp FL1 starts arc discharge, since no direct current flows on the DC cut line 39 and the detection level does not rise, the base of the transistor Q33 is based on the AC voltage detector 55. Is controlled. Then, based on the detection level, the output of the inverter circuit (36 ₁₎ is controlled to be applied between the secondary voltage fluorescent lamp filament (FL1a, FLlb) of (FL1).

When the voltage is applied and the fluorescent lamp FL1 transitions to an arc discharge and is turned on, the fluorescent lamp FL1 is equivalent to the resistance and no AC component is lost. Therefore, the detection is performed by the AC voltage detector 55. do. That is, the control based on the detection level is released, the lamp voltage is controlled by the detection level for all the lights, the base is controlled in the transistor Q33 based on the detection level, and the gate of the field effect transistor Q22 is controlled. controlling the voltage, by changing the combined capacitance on the surface of the condenser (C21) and the capacitor (C32), and controls the output of the inverter circuit (36 _1).

On the other hand, in the dimming mode, the transistor Q27 is turned off and the detection level for dimming becomes effective, and since this detection level is higher than the detection level for all-illumination, it preferentially controls the base of the transistor Q33. do. Therefore, on the basis of the detected level by the transistor (Q33) to control the gate voltage of the field effect transistor (Q22) and controls the inverter circuit (36 _1). In addition, since the rise of the detection level is delayed in time by the charging of the condenser C39 at the time of starting in the dimming mode, even in the dimming mode, the output can be started with a high output through the glow discharge.

Next, the state in which the fluorescent lamp FL1 has reached the end of its life will be described.

Since the current flows in the bidirectional direction in the fluorescent lamp FL1 in the state where the fluorescent lamp FL1 is normally lit, there is almost no potential difference between the first DC voltage detector 56 and the second DC voltage detector 59. Since Q31 remains in the off state and the Zener diode ZD13 is also in the off state, no base current flows through the transistor Q29, and the programmable non-transistor transistor Q28 is in the off state. Keep it.

At the end of the lifetime of the fluorescent lamp FL1, the electron emission from any one of the filaments FL1a and FL1b is lowered to generate half-wave discharge. When the half-wave discharge occurs in this manner, a potential difference occurs between the first DC voltage detector 56 and the second DC voltage detector 59, and the transistor Q31 is turned on and the zener diode ZD13 is turned on. The base current flows through the transistor, and the programable operation transistor Q28 turns on, the base current of the transistor Q31 disappears, the transistor Q31 turns off, and the zener diode ZD11 turns on, so that the field effect transistor ( Q11) is turned on, and by bypassing the base current of the transistor (Q11) to forcibly stop the inverter circuit (36 ₁₎ to prevent a stress such as a transistor (Q11).

In any of the above embodiments, an annular fluorescent lamp is used as the discharge lamp, but may be a straight tube type, and the lamp power is arbitrary. In addition, the instrument body can also be applied to ceiling mounted ceiling lights, pendants, or any other type.

In addition, the inverter circuit is for making each fluorescent lamp turn on at high frequency. If the high frequency output is variable, the inverter circuit is not limited to one-seat half bridge type, four-seat full bridge type or other methods. In particular, what is necessary is just to be able to discharge | discharge the fluorescent lamp glow-discharged at the start-up.

The detection level may be set arbitrarily by connecting resistors or zener diodes in series or in parallel.

As mentioned above, this invention is suitable for the discharge lamp lighting apparatus which turns on the discharge lamp which has the filament which needs preheating.

Claims (13)

Discharge lamp lighting means for preheating the filament and lighting the discharge lamp having the filament in the state of undischarged in the discharge lamp; Discharge detection means having a filter for removing the lighting frequency of said discharge lamp and detecting the discharge of said discharge lamp without being connected to the discharge lamp lighting means DC directly; And a control means for preheating the filament by lowering the output of the discharge lamp lighting means when discharge is detected by the discharge detecting means. An output variable inverter circuit having a switching element for switching and having a pair of filaments and applying a voltage between the filaments and the filaments of a discharge lamp having a diameter of 21 mm or less having a fluorescent substance installed thereon; An inverter control circuit for controlling a switching operation of the switching element to vary an output of the inverter circuit; Discharge detection means for detecting the discharge of the discharge lamp, and the set preheating time is applied to the discharge breakdown voltage between the filament of the discharge lamp to glow discharge, and after the preheating time elapsed arc between the filament of the discharge lamp And a start control circuit for applying a lamp secondary voltage for transition to discharge and for operating the inverter control circuit to lower the voltage between the filaments of the discharge lamp when the discharge is detected by the discharge detection means. Lighting device. 3. The inverter circuit according to claim 2, wherein the inverter circuit has a DC cut line connected to either of the filaments in which the discharge lamps are paired and interposed with a capacitor for DC cut so that the DC portion is cut, and a DC output line without the DC portion cut. A discharge lamp lighting device comprising: a discharge detection means having a direct current voltage detection unit for detecting a direct current voltage of a direct current cut line, and outputting in accordance with the voltage value of the direct current cut line detected by the direct current voltage detection unit. 4. The inverter circuit according to claim 3, wherein the inverter circuit has a DC cut line connected to either of the filaments in which the discharge lamps are paired and interposed with a capacitor for DC cut so that the DC portion is cut, and a DC output line without the DC portion cut, The discharge detecting means has a first DC voltage detector for detecting the DC voltage of the DC cut line and a second DC voltage detector for detecting the DC voltage of the DC output line, and the first DC voltage detector and the second DC voltage detector Discharge lamp lighting device, characterized in that output in accordance with the difference in voltage. 5. The inverter circuit according to claim 4, wherein the inverter circuit has a DC cut line connected to either of the filaments in which the discharge lamps are paired and interposed with a capacitor for a DC cut so that the DC portion is cut, and a DC output line in which the DC portion is not cut, And a discharge detection means having an AC voltage detection unit for detecting an AC voltage of a DC cut line, and outputting a detection amount of the AC voltage detection unit according to the voltage on the DC cut line by secondary voltage control of the lamp. 6. The discharge lamp lighting device according to claim 5, wherein the DC voltage detection unit of the discharge detection unit includes a DC voltage detection unit for all-lighting and a DC voltage detection unit for dimming, which is set at different detection levels. 7. The DC voltage detecting part for electric light is provided with detection level switching means in which the detection level is different from the time of preheating and electric light lighting, A discharge lamp lighting device characterized in that the relationship is a detection level for preheating> detection level for dimming> detection level for electric lighting. 8. The discharge lamp lighting device according to claim 7, wherein the discharge detecting means has a current detecting unit for detecting a lamp current, and outputs a signal from the current detecting unit to the start control circuit at the time when the lamp current is detected. 3. The inverter circuit according to claim 2, wherein the inverter circuit has a DC cut line connected to either of the filaments in which the discharge lamps are paired and interposed with a capacitor for DC cut so that the DC portion is cut, and a DC output line in which the DC portion is not cut, And a first DC voltage detector connected to the DC cut line and a second DC voltage detector connected to the DC output line, and outputting a detection amount corresponding to a difference between the voltages of the first DC voltage detector and the second DC voltage detector. End of life detection circuit, And an oscillation stop circuit for stopping the switching operation of the switching element of the inverter circuit by the stop signal output by the end-of-life detection circuit. 3. The inverter circuit according to claim 2, wherein a plurality of inverter circuits are provided corresponding to a plurality of discharge lamps having the same lighting frequency and different lamp powers, A power input circuit having a full-wave rectification circuit for full-wave rectifying a low frequency AC power supply voltage, the power input circuit being connected to a plurality of inverter circuits installed in correspondence with the other lamp power; A first capacitor having a capacitance that does not exhibit a smoothing action against a low frequency voltage, a second capacitor connected to the power supply input circuit than the first capacitor, and having a larger capacitance than the first capacitor, and a connection between the first capacitor and the second capacitor And a rectifier diode in which the cathode of the first capacitor is switched by a high frequency current based on reactive power regenerated on the input side, a smoothing capacitor connected in parallel to the first capacitor, and a series circuit of the inductor element. A discharge lamp lighting device comprising: a plurality of low distortion circuits each connected to a front end thereof. 3. The inverter circuit according to claim 2, wherein a plurality of inverter circuits are provided corresponding to a plurality of discharge lamps having the same lighting frequency and different lamp powers, A power input circuit having a full-wave rectification circuit for full-wave rectifying a low frequency AC power supply voltage, the power input circuit being connected to a plurality of inverter circuits installed in correspondence with the other lamp power; A first capacitor having a capacitance that does not exhibit a smoothing action against a low frequency voltage, a second capacitor having a larger capacitance than the first capacitor, connected between the first capacitor and a second capacitor having a larger capacitance than the first capacitor At the front end of the inverter circuit including a rectifier diode in which the cathode of the first capacitor is switched by a high frequency current caused by reactive power that is regenerated toward the input, a smoothing capacitor connected in parallel to the first capacitor, and a series circuit of the inductor element. A plurality of low distortion circuits connected to each other, A circuit board in which each inverter circuit is divided into blocks for each block; And a heat dissipation plate provided on a circuit board together with switching elements in the inverter circuit at positions skipping the blocks, respectively. The discharge lamp lighting device according to any one of claims 1 and 2 to 11, An illuminating device comprising a mechanism body to which this discharging lamp lighting device is installed. 13. The discharge lamp lighting device according to claim 12, wherein the discharge lamp lighting device expected from any one of claims 1 and 2 to 11; The discharge lamps are a plurality of annular fluorescent lamps having different outer diameters of 21 mm or less in diameter from which the force is applied by each inverter circuit. The apparatus body is a disk shape which holds these fluorescent lamps concentrically.