KR820001971Y1 - Flourescent lamp switching device - Google Patents

Abstract

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Description

Lighting device of preheat start type fluorescent discharge tube

1 is a characteristic diagram of voltage and current of a fluorescent tube lighting circuit in a choke bellows system.

2 is a characteristic diagram of a voltage current in a resistance ballast system.

3 is a circuit diagram of the present invention.

4 is a voltage characteristic diagram in the circuit configuration of the FIG. 3 display.

5 is another basic circuit diagram of the present invention.

6 to 9 are circuit diagrams showing the main parts of the embodiments of the present invention, respectively.

FIG. 10 is a diagram of voltage characteristics of the circuit configuration shown in FIG.

11 to 12 are main circuit diagrams each showing yet another embodiment of the present invention.

FIG. 13 is a voltage characteristic diagram of the circuit configuration shown in FIG.

The present invention is a lighting device of a preheat start type fluorescent discharge tube, in particular a resistive teller current control means using an incandescent lamp, a stationary semiconductor switch, a pulse transformer for generating a high voltage, and an auxiliary electrode receiving the secondary output thereof. Relates to a lighting device.

As a lighting device of this type of preheat start type fluorescent discharge tube, a typical means is to use a choke ballast to limit the preheat current (fluorescent filament current) and the lighting current (fluorescent tube inter-polar discharge lamp current) and start the lighting. In the city, a kick voltage is generated, and in view of the recent tendency of sex energy, there is a tendency to use fluorescent lighting apparatuses in place of existing incandescent lighting apparatuses in consideration of the utility of fluorescent lighting apparatuses in lighting facilities.

Therefore, the applicant of the present invention first developed a fluorescent lamp mechanism with a detention, which can be directly attached to an existing installation of an incandescent lamp, especially an incandescent lamp socket.

This detained fluorescent lamp device is configured as a lighting circuit device equipped with a glow starter and a choke ballast, and the fluorescent discharge tube and the lighting device part are housed in a synthetic resin glow that transmits light, and the exterior of the device is the appearance of a conventional incandescent lamp device. In the case of using in place of incandescent lamps by close to, the less the different sense, the less compatibility with the existing incandescent lamp fixtures.

However, the conventional choke ballast used in the conventional fluorescent lamp is heavy, and in the case of a fluorescent apparatus with a detaining device therein, the metal part of the existing socket is received through the detention of the ballast load and the fluorescent discharge tube or other load. Considering the safety of the fall prevention, there is a restriction on the overall weight of the device, especially the weight of the choke ballast occupying the placenta of the device, i.e. a small one with a small number of applied watts, and a large wattage choke ballast. When the lamp is turned on with the fluorescent lamp, the heat generated increases and the temperature in the glove increases, resulting in a decrease in the efficiency of the fluorescent lamp. Therefore, the fluorescent lamp device of the present invention is practical for its low-watt fluorescent lamp device (20 W or less). This will be exercised.

In the fluorescent discharge tube, a resistance bellows method is widely known as a current control means. However, in the start-up of the fluorescent discharge tube of this type, a discharge initiating discharge of several times the amount of the fluorescent discharge tube and the lighting voltage between the cathodes at the end of the preheating operation. Since it requires a voltage (kick voltage), via the resistance belt rest system, this discharge start voltage generator must be separately installed.

The voltage generating circuit detects the return of the supply voltage of the cathode-to-cathode voltage at the end of the preheating operation, and at this point, the high voltage is applied between the discharge poles to initiate the inter-pole discharge, and at the same time, the operation of the generating circuit In order to satisfy the operational conditions such as the generation operation must be stopped in order to prevent power consumption and to stabilize the lighting current, the lighting device of the conventional preheat start type fluorescent discharge tube had to be composed of a complicated electronic circuit.

On the other hand, the present invention is intended to solve the problem in the starting device by developing a circuit device for extremely simple discharge initiation, and to apply a high voltage to the auxiliary electrode provided on the outer wall of the fluorescent discharge tube of the present invention. In addition, since the secondary electrode and the discharge cathode have high impedance floating capacitance coupling, the current is rarely needed. Therefore, the surge coil receives the surge voltage in the primary coil when operating the glow starter. By using a small pulse transformer and applying a high voltage generated in the secondary coil to the auxiliary electrode applied voltage, a simplified and effective circuit device that is used as an auxiliary electrode and an ultra-small pulse transformer that replaces the conventional discharge start voltage generation circuit is provided. I could get it.

In order to stably light this type of fluorescent discharge tube, it is necessary to ensure that the re-ignition operation for every half cycle of the AC power supply is good after the lighting is started.

However, in this type of fluorescent discharge tube, considering the stable lighting state after the start-up, in the lighting device using the choke ballast, the lamp voltage vd applied between the poles of the fluorescent discharge tube with respect to the voltage V of the AC power supply in FIG. When the lamp current I has a phase difference due to inductance in the ballast, and when the lamp current I of the phase difference becomes zero, the counter electromotive force in the ballast occurs in a direction opposite to the direction of current flow so far, and the generated voltage is fluorescence. Since the voltage is sufficient for the firing of the next half cycle to be applied to the discharge tube, the fluorescent discharge tube immediately re-ignites so that the lamp current I becomes approximately sinusoidal and flows almost all over each half cycle.

On the other hand, in the resistance bellows system, as shown in FIG. 2, since the lamp voltage vd is in the same phase as the power supply voltage V, the instantaneous value of the power supply voltage V gradually rises in the lighting state of the fluorescent discharge tube, so that the lamp required for the start of discharge of the discharge tube is increased. in the arc reignition in it reaches a voltage (t ₁ time), the power supply voltage V, the discharging state at the end portion of the half cycle can not be obtained for the lamp current to the discharge duration by the instantaneous lowering value (t ₂ group) Stop it.

Therefore, in this resistance bellows system, the lamp is turned on only in the time period of t ₁ -t ₂ between half cycles of the power supply voltage V, and a short discharge pause period occurs before and after.

Therefore, this kind of low pressure fluorescent discharge tube is designed to show the best characteristic at the ambient temperature of 20 ° C-25 ° C as its property, and its property is deteriorated by the increase or decrease of the ambient temperature. The increase in the lamp voltage of the fluorescent lamp tube was observed at the ambient temperature in the region of.

In other words, the lamp voltage (shown in dashed lines in Figs. 1 and 2) required for re-emergence also increased in each cycle of the alternating voltage at the time of start-up as well as during the start-up.

Therefore, even in the lighting circuit using the choke ballast, it is difficult to re-ignite when the ambient temperature is above 40 ° C or below 0 ° C, and it is difficult to see the phenomenon in the lighting state. It was accompanied by a drawback of not re-invoking until the instantaneous rise of the voltage reached the ramp voltage.

This means that the discharge pause period is extended, and it is not only a lingering phenomenon in the lighting state but also a significant defect in the lighting apparatus without the kick voltage generating means.

In addition, the 30W class having 90% of the utilization rate in the annular fluorescent discharge tube was constructed based on the design of the tube close to the limit function that can be used without boosting power under commercial AC power supply in Korea. Is 0.62A, which is very large compared to 20W class lamp current (0.375A), whereby the tube wall temperature at the time of lighting tends to be high, and as a result, the lamp voltage (58V) tends to rise again.

Therefore, the 30W class is strongly affected by the ambient temperature compared to other low-watt class.

That is, the glow discharge start voltage (94V or less and 63V or more) of the starter when the preheating circuit is configured as a glow starter is set higher than the normal lamp voltage (58V), but the lamp voltage increases due to the change of the ambient temperature and the voltage By being close to or above this glow discharge start voltage, the glow-start re-operation phenomenon occurred at the time of lighting, resulting in the unlit state of the fluorescent discharge tube.

In particular, in the case of a glow bulb for a glow starter, there is a large unstable factor due to unbalance of product characteristics and changes over time, and thus it is very unreasonable when the temperature range of a practical lamp of a fluorescent lamp is widened. This phenomenon is a lighting circuit using a choke ballast. The same applies to the above, but in this case, the counter-voltage generated by the ballast is alleviated, and in the lighting circuit of the resistance bellows type, especially in the absence of the counter-voltage generator in the circuit, it is remarkable. This was necessary.

Therefore, the present invention uses a stationary semiconductor switch element in place of the glow starter as a method of this solution, and the configuration of the lighting circuit by the semiconductor switch element induces the endurance against the aging change of the conventional glow starter. In particular, Glow Start has been developed with the aim of shortening the preheating time and initiating a Kick Start fluorescent lamp lighting device.

In this case, the semiconductor element used in this case is composed of various devices such as a bidirectional two-terminal thyristor, for example, using an SSS element (Specifications 44-18155, 49-275, and 53-24149, etc.). In addition, many of these have been limited, including those using reverse stop three-terminal thyristors (Sec. 47-39334, others) and those using triacs (Sec. 53-47627, etc.). .

However, in the conventional lighting device using this kind of semiconductor switch element, the operation of the element is mainly performed to control the opening and closing of the preheating circuit, and the start-up voltage (kick) is another condition necessary for lighting. As a means of obtaining voltage, a choke or ballast or a counter electromotive force generating coil was used.

Therefore, having such an inductance series circuit such as a choke ballast, the above lighting start and re-ignition operation are good, and the rise of the lamp voltage is relatively small due to the change of ambient temperature. In the case of relatively easy ones, but the resistance bellows method, the start-up and re-ignition voltage of the 30W Fcl-30 type fluorescent discharge tube is about 80V, the maximum of the lamp voltage at room temperature (20 ° C). It is very difficult to construct a semiconductor switch element circuit that compensates for the fluctuation range of this lamp voltage and makes constant contact operation since it rises to about 120V).

This is because, in reality, a bidirectional two-terminal die Lister (SSS) has no commercially available characteristic element having a Vd of which the break-over voltage (Vd) is higher than the highest in the 120V class. The lighting device was not able to easily convert the lighting circuit of the resistance bellows system as it is.

Thus, in the resistive ballast system, a circuit configuration using a semiconductor switch element is used, which uses a lot of three-terminal thyristors such as SCR or triacs that can be turned on by gate current control.

Therefore, in the present invention, as a lighting device for the preheated fluorescent discharge tube, the device adopts a resistive bellows patented electric bulb bellows method to reduce the weight of the mechanism and other effects described below, and applies a high-frequency high-pressure induction pulse to the outer wall of the tube. The present invention has been shown to propose a lighting device using an extremely good semiconductor switch element such as a re-ignition operation for further improving the practical protection of the apparatus by further improving the improved ignition apparatus to simplify and reduce the cost of the apparatus. According to the embodiment of the following.

FIG. 3 is a circuit diagram showing the basic circuit device according to the present invention, in which the incandescent lamp L is used as a resistance bellow in the circuit for supplying the power source E used for the preheated fluorescent discharge tube F (hereinafter abbreviated as fluorescent tube). Inserted in series.

In addition, among the preheating circuits connecting the gaps (p, q) between the other ends of the power connection side of the filament poles of the fluorescent tube F, dozens of starters (S) and pulse transformers (T), which are also semiconductor switch elements and their turn-on control circuits, are included. The primary coils to be turned were connected in series with each other.

Secondary coils, which are hundreds of turns of pulse transformer T, commonly connect one pole to one pole of the primary coil, while the other pole j of the secondary coils closely or close to the outer wall of the fluorescent tube F. It was connected to the auxiliary electrode G which was arrange | positioned. C is a capacitor for flowing a discharge current to the transformer T and a function for preventing other unnecessary things.

In this configuration, when the power source E is turned on, the starter S becomes conductive when the instantaneous value of the first half cycle of the AC voltage reaches a value for turning on the semiconductor switch element of the starter S. .

Due to the conduction of the starter S, a relatively large preheating current (1.5 times the lamp current at the time of lighting) flows to both filament poles of the fluorescent tube F under the regulation by the incandescent lamp L in the circuit. Each cycle is repeated (every half cycle when the switch element is unidirectional), and both filament poles are heated. During the preheating operation of the fluorescent tube F, the capacitor C is charged at the beginning of each cycle of the high current voltage and discharged when the starter S is turned on.

The preheating current due to the conduction of the starter S and the discharge current of the capacitor C flow through the primary coil of the pulse transformer T inserted in series in this preheating circuit. The secondary coil of the transformer T The high voltage corresponding to the pulsed primary current having a high rate of change due to the discharge current of the capacitor C is generated.

This state is shown in FIG.

In the figure, V denotes a power supply voltage, Vd lamp voltage, and Vt denotes a high voltage pulse generated in the secondary coil.

The high-voltage pulse Vt is applied to the outer wall of the fluorescent tube F through the auxiliary electrode G. However, the high-pressure pulse Vt is applied at the beginning (several cycles) of the preheating operation in which the fluorescent tube filament pole has not yet been sufficiently heated. If it does not appear or the preheating operation is progressed and the filament pole is sufficiently preheated, and the release of hot electrons from the pole is active, the released hot electrons are attracted to the auxiliary electrode G applied to the high voltage pulse Vt, and both filaments The pole shows the glow discharge state between the pipe walls close to the auxiliary electrode (G).

In the half cycle of AC power, when the high voltage pulse (Vt) is generated, the starter (S) is in a conducting state. Therefore, the lamp voltage (Vd) is lowered and the kitchen is turned on when the filament pole and the auxiliary electrode (G) are adjacent to each other. When the starter (S) does not conduct in the next half cycle, that is, when the starter (S) conducts, the response voltage is set to a voltage higher than the onset voltage of the fluorescent tube, so the power supply voltage (V When the instantaneous value of) reaches the start-up voltage in the state before reaching the response voltage, the glow discharge caused by the high voltage pulse (Vt) induces the ionized electrons remaining on the inner wall surface of the fluorescent tube (F) during the half cycle. Thus, the transition of the lighting of the electric discharge between the two filament poles proceeds gradually to repeat the several cycles of the glow discharge to reach the lighting device.

In the lighting, the lamp voltage Vd is reduced to the state shown in FIG. 2, and the fluorescent lamp F is turned on until the sustaining current is secured in the half cycle at the time of lighting, and then the power supply voltage V The above operation is repeated for each half cycle to reach a stable lighting state.

In the start-up operation, the pulse transformer T is connected in series with the starter S in the preheating circuit. Thus, during the preheating operation, the preheating current flows to the primary coil. Therefore, the coil does not take the preheating current and the allowable amount. Otherwise, it is disadvantageous in the design of the transformer and its operation is mainly caused by the discharge current of the capacitor C having a high current change rate. Therefore, as shown in FIG. 5, a circuit in which the transformer T is connected to the capacitor C in series is used as a starter. The circuit connected in parallel to (S) allows the primary coil of the transformer T to flow only the charge / discharge current of the capacitor C, and its operation and function are the same as those of FIG. 3 shown above.

In the basic circuit configuration shown in FIGS. 3 and 5, the starter S does not set the conduction time at the time after the discharge start voltage with respect to the change of the instantaneous value in the half cycle of the voltage V. FIG. However, when considering the increase of the discharge start voltage due to the change in the ambient temperature of the fluorescent tube, the time should be placed at the peak value of the half cycle. Thus, FIG. 6 shows an embodiment of the present invention in which the starter S is constructed by using the reverse stop three-terminal thyristors (hereinafter referred to as SCR) having freedom in setting the conduction timing.

In the figure, j, p, and q represent the common connection positions in the FIG. 3 display circuit, respectively, and the same symbols are shown for circuit elements having a common function in the circuit shown in FIG. do.

SCR 1 constituting the starter S is provided with a firing circuit in which a zener diode 2 is connected in series between the gate electrode and the anode pole, that is, the power supply circuit.

For the stable operation of this firing circuit, a resistor 3 for regulating firing current was inserted in series with the circuit, and a protective resistor 4 was connected between the gate electrode and the cathode electrode.

According to this configuration, when the magnitude of the power supply voltage reaches the breakover voltage of the zener diode 2 in the half cycle of the power supply voltage V, the zener diode 2 is in the conduction state from the non-conduction state until now. In order to make the gate current flow, SCR 1 is turned on.

In this operation, a high-pressure pulse is generated on the secondary coil of the pulse transformer T that receives the discharge current of the condenser C at the same time as the preheating current flows and is applied to the outer wall of the fluorescent tube, but at this time, the lamp of the fluorescent tube F The tube F is not turned on because the voltage Vd is lowered to the state of FIG. 4.

In this circuit, in which the starter S is composed of SCR 1, the above operation is performed every half cycle of the AC voltage V as the reverse stop characteristic of the SCR 1, and the preheating operation is stopped in the other half cycle. In F), a high lamp voltage Vd corresponding to the power supply voltage V is applied during the half cycle of preheating stop, so that the lighting startability is good.

However, in the circuit display configuration of FIG. 6, the number of circuit elements to be used is small and the circuit configuration is simple, so that the whole device can be configured at low cost. However, the start time of the starter S, that is, the turn-on time of SCR 1 Is determined by the break-over voltage of the zener diode 2 with respect to the power supply voltage V, so that fine control of the conduction time is difficult.

Thus, by adopting the circuit configuration shown in Fig. 7, the degree of freedom of timing determination can be increased. That is, the display circuit of FIG. 7 constitutes a bleeder circuit for the power supply voltage with resistors 5 and 6, and a zener diode 2 is inserted in series between the bleeder voltage output terminal and the gate pole of SCR 1.

According to this configuration, the zener diode 2 can be operated at a partial voltage of the power supply voltage V by subtracting the resistance values of the resistors 5 and 6 with respect to the zener diode 2 having the breakover voltage predetermined in advance. As a result, the turn-on time of SCR 1 can be determined at any time in the first half of the half cycle of the supply voltage (V). In this case, since the zener diode 2 has a function as a trigger element of the SCR 1, other trigger elements, in particular, two-terminal thyristors, which oppose the zener diode 2 can be dedicated.

FIG. 8 is a circuit diagram showing a misunderstanding of another embodiment of the present invention, in which a firing circuit of SCR 1 is applied to a bleeder circuit consisting of resistors 5 and 6, and a capacitor for correction in parallel with the resistance 5 of the circuit. (7) was connected.

Then, a two-terminal die thruster (diac) 8 was inserted in series between the bleeder voltage output terminal and the gate electrode of SCR 1 as a trigger element.

According to this configuration, as the instantaneous value of the half cycle of the alternating voltage (V) increases, the correction capacitor (7) is charged with the bleeder voltage regulated by the resistors (5) and (6), and the voltage between the terminals thereof is diac ( When SCR 1 is triggered and turned on when the breakover voltage (vb) of 8) is reached, or when the resistance of the bleeder circuit is selected and the capacity of the correction capacitor 7 is set, the SCR 1 turns on when the power supply voltage (V) is reached. It is also possible to operate in the region beyond the highest instant in the half cycle of (the latter region of the supply voltage V which does not lower the bleed voltage than the vb of the Diak 8).

This is because the turn-on timing of SCR 1 in the circuit configuration shown in Fig. 7 is strongly affected by the fluctuation of the power supply voltage (V), so that the turn-on timing of SCR 1 is considered in consideration of the increase in the lamp voltage (vd) caused by the change in ambient temperature of the fluorescent lamp. Is set near the maximum instantaneous value of the half cycle, there is a concern that the turn-on control of SCR1 may not be performed due to the change in the power supply voltage (V), but according to the circuit configuration shown in FIG. Since it is possible to control the turn-on of SCR 1 in the second half region of the half cycle beyond the highest instant where charging is performed, a circuit device resistant to the fluctuation of the power supply voltage V can be obtained.

The circuit means constituting the starter S as the SCR 1 shows the same embodiment in the configuration of the basic circuit shown in FIG. 3 as the circuit insertion position of the pulse transformer T. In the basic circuit configuration of the display, the in-circuit insertion position of the transformer T can be taken.

However, in any arrangement of the pulse transformer T, the operation time of the transformer T is the turn-on time of the SCR 1, and at this time, the fluorescent lamp voltage (vd) is lowered. Is a step in which the ionization electrons remain on the inner wall of the fluorescent tube as a high-voltage pulse, and thus the function of the transformer T cannot be fully utilized even in the case of lighting start-up.

Thus, the transformer T is operated at half cycle of the power supply voltage V at which the SCR 1 is not turned on, that is, at a time when the fluorescent tube lamp voltage vd is sufficiently applied, so that the transformer T can be utilized. An embodiment of the inventive device is illustrated next.

That is, the circuit configuration shown in FIG. 9 is connected to SCR 1 in parallel with the SCR 1 in addition to the circuit configuration of FIG. 8 in the reverse polarity direction. ) Is connected under the parallel laying of the discharge resistor 10, and the structure of the zener diode 2 which is the simplest in the circuit of FIG. 6 as the ignition circuit of the other SCR 9 is provided. In this circuit configuration, the operation by the half cycle of the AC power supply is the same as that of the circuit shown in FIG. 8, but the SCR 9 is turned on in the next half cycle of the AC power supply.

The current of the preheating circuit due to the turn-on of the SCR 9 is controlled, and the charge voltage of the capacitor C or the lamp voltage vd at the turn-on of the SCR 9 decreases instantaneously, but the power supply voltage is immediately reduced. While returning to (V), the instantaneous current flows through the primary coil of the pulse transformer T, so that a high voltage pulse (vt) is generated in the secondary coil at this time. This state is shown in FIG.

That is, in the configuration of FIG. 9, the high voltage of the recovery direct-current power supply is applied under the application of a sufficient lamp voltage v d that is instantaneously recovered and the occurrence of the high-voltage pulse is recognized in the half-cycle area where the preheating operation is increased in the configuration of FIG. Very good lighting operation is performed by the pulse action.

In this case, since the capacity of the lamp voltage due to the turn-on of SCR 9 is small, the turn-on operating voltage of the SCR 9 is set below the start-up voltage at room temperature without considering the increase of the lamp voltage due to the change of the ambient temperature. Is good.

When the operation timing of the pulse transformer T is deactivated so as to be operated only when the SCR 9 is turned on, the circuit configuration shown in FIG. 9 is replaced with the insertion position in the circuit, and the transformer is connected to the series circuit between the SCR 9 and the condenser 10. What is necessary is to connect (T) in series.

The circuit configuration of FIG. 11 showing another embodiment of the present invention is a series connection configuration of the bidirectional three-terminal thyristors (triacs) 12 and the diodes 13 to the starter (S) and FIG. The switch configuration corresponding to SCR 9 in the circuit is shared, and in addition to connecting the current limiting capacitor 10 of the diode 13 and its discharge limiting resistor 11 in parallel, the circuit configuration shown in FIG. Is the same as

In the circuit configuration shown in FIG. 11, charging is performed to the correcting capacitor 7 under the regulation of the bleeder circuit which becomes the resistors 5 and 6 by turning on the power supply. (8) is turned on to give the triac 12 a gate current to conduct it.

At this time, the half-cycle zone surface in which the forward voltage is applied to the diode 13 connected to the triac 12 in series is used as the forward current for shaking the triac 12 and the diode 13, respectively. As in the above, the pulse transformer T also operates as a discharge current of the capacitor C while passing through the preheating current of the abnormal control type.

In the next half cycle of the AC power supply of this operation, in the conduction of the triac 12 by the correcting capacitor 7, the reverse voltage is applied to the diode 13, so that the diode 13 While a small amount of pulsed current flows through the current limiting capacitor 10, and the current control according to the completion of charging of the capacitor 10 causes the triac 12 to maintain its conduction holding current. Immediately transition to a state of failure without gaining.

In this operation, the discharge current of the capacitor C flows through the pulse transformer T, and high voltage pulses are generated in the secondary coil. That is, the circuit operation similar to the characteristic of FIG. 10 in the circuit configuration of FIG. 9 is performed, and the effective lighting start is performed in the circuit configuration of FIG.

Therefore, since the three-terminal thyristor controllable by the gate current has a good time characteristic of the current change in the turn-on transition and an excellent reverse blocking characteristic, the secondary output of the pulse transformer T controlled thereby is As shown in Fig. 10, a short pulse state with good operation start characteristics is shown, and the pulse width is narrow.

However, as a trigger high pressure for fluorescent tube lighting start, a wide pulse width is preferable.

On the other hand, the two-terminal thyristors have a small degree of freedom in selecting the brake overvoltage, and thus, as described above, they cannot be applied to the apparatus of the present invention. However, the brake ow when the element and the pulse transformer T are combined. It is confirmed that the scattering of the overcurrent, which is considered to be caused by the tilting of the vertise, causes the secondary output of the transformer T to be generated as a high-frequency oscillating high-pressure pulse.

Next, using the characteristics of this two-terminal thyristoter, the circuit is shown in FIG.

That is, basically, the SSS element 14 is connected in series with SCR 1 in the circuit configuration shown in FIG.

As a result, the circuit operation is the same as the circuit shown in FIG. 8, but the high-pressure pulse (vt) from the secondary coil of the pulse transformer T is generated as a high frequency vibration pulse as shown in FIG. Function is effectively exhibited by lighting start.

Since the control timing of the preheating circuit current in this case is determined by the turn-on operation of SCR 1, if the element having a relatively high (vb) is used as the SSS element 14 without having to consider the brake overvoltage vb in particular. do.

Therefore, a two-terminal thyristor of this kind may be dedicated to each of the illustrated embodiments of the device of the present invention, but in particular, two-terminal as a switch component replaced by one SCR 9 in the circuit configuration of FIG. It is effective to use the thyristor alone or in series with the diode.

In addition, the device of the present invention can be configured by exchanging a part of each circuit configuration in accordance with the intention of the device configuration.

In the present invention having such a configuration, as a lighting device of the FcL-30 type fluorescent lamp, the capacity of the capacitor (C) is 0.2F and the capacity of the visibility capacitor using 100 W type at the rated voltage of the power source using the incandescent lamp. 1 sec at room temperature using a transformer with a ferrite core of primary coil 10 to 20 turns secondary coil 300 to 500 turns as pulse transformer T, using a predetermined resistance to obtain 0.1F and a circuit constant. The lamp is turned on by the following preheating operation, and the lamp is turned on 2 seconds before and after the preheating time in the ambient temperature range of 0 ° C and 40 ° C, and the power supply voltage fluctuation can be sufficiently provided for practical use with ± 10%.

Particularly, in the present invention, since the lighting means of the resistance bellows type is used, the weight of the mechanical load can be reduced compared to the inductance series circuit type such as the ballast, and the heat of lighting of the resistance bellows, for example, incandescent bulbs, can be obtained. As the fluorescent tube can be heated, it is possible to accelerate the luminous flux recovery power of the fluorescent lamp in cold places, and when the incandescent bulb is used as the resistance bellows, the lighting becomes a light source with excellent color rendering properties by the mixing effect of the fluorescent tube lighting. By incandescent lamp light to catch the flickering when the fluorescent tube is turned on, it is possible to obtain a light source close to the upper light with little flickering visually.In addition, the lighting of the light bulb with incandescent light bulbs contributes to increasing the luminous intensity of the whole apparatus. Incandescent light bulbs have the effect of energy saving mechanism with good luminous efficiency It will have secondary effects, such as filaments exert Hugh Woods function for an abnormal current in the circuit device.

The lighting device of the present invention, which has the specificity of such a resistance bellows system, compensates for the shortcomings in the resistance bellows system by means of circuit constituting means, so that a lighting device that operates properly in a wide range of ambient temperature can be obtained. Therefore, the practical effect is extremely remarkable.

Claims (1)

As shown in the figure, the incandescent lamp L is connected to the discharge tube F which is started through the preheating operation, and is configured to be applied to the auxiliary electrode G from the secondary side of the pulse transformer T. A lighting device for a fluorescent discharge tube in which a semiconductor switch (S) and a pulse transformer (T) are connected in parallel with a capacitor (C) between anodes of a discharge tube.