JP3150493B2 - Light bulb type fluorescent lamp - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compact fluorescent lamp.

[0002]

2. Description of the Related Art A conventional bulb-type fluorescent lamp has an envelope formed by attaching a translucent glove to the other end of a case having a base attached to one end, and a double U-shaped fluorescent lamp is provided in the envelope. tube,
A cap-shaped holder for holding the fluorescent tube and a lighting circuit are provided.

[0003] In such a bulb-type fluorescent lamp, the fluorescent tube is integrated with a lighting circuit via a holder and housed in a compact envelope. Is significantly increased, and the luminous efficiency is significantly reduced. To improve this, amalgam is usually sealed in a small tube at one end of the fluorescent tube, and the vapor pressure of mercury in the tube is controlled to an appropriate value. Further, the cross-sectional shape of the bent portion close to the holder of the fluorescent tube is a circle having the same inner diameter as the straight portion which is a non-bent portion in order to facilitate discharge. Further, the bent portion of the fluorescent tube close to the holder is configured not to heat the lighting circuit, for example, is fixedly held to the holder with an appropriate distance between the holder and the bent portion (Japanese Patent Application Laid-Open No. H10-163873). Showa 6
1-1107603).

[0004]

In the conventional bulb-type fluorescent lamp, the starting and lighting characteristics of the double U-type fluorescent tube are determined by the electric characteristics of the double U-type fluorescent tube, the temperatures at both ends of the fluorescent tube, and the characteristics of the lighting circuit. ing. At the time of startup immediately after startup, the luminous flux increases with the rise of mercury vapor pressure in the fluorescent tube and reaches an optimum point, but when ambient temperature or power supply voltage is high, the luminous flux rises. There is a problem that the luminous flux is reduced beyond the optimum point, and the temperature of the lighting circuit is locally increased (particularly, a semiconductor element), thereby destroying the lighting circuit. Such a problem is often observed particularly in a fluorescent tube using amalgam. Further, there is also a problem that the lamp current temporarily becomes extremely high and the lamp life is shortened.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a bulb-type fluorescent lamp capable of preventing an overload of a fluorescent tube and destruction of a lighting circuit.

[0006]

According to the present invention, there is provided a bulb-type fluorescent lamp in which both ends are fixed to a holder, and a bent portion close to the holder is fixed to the holder by a heat conductive adhesive. A U-shaped fluorescent tube, a lighting circuit for lighting the fluorescent tube, a case containing the lighting circuit,
A glove that houses the fluorescent tube and forms an envelope with the case, wherein the inner diameter of the bent portion of the fluorescent tube that is close to the holder is larger than the inner diameter of the non-bent portion of the fluorescent tube. And the lighting circuit is the fluorescent tube.
Has the characteristic that the input power to the fluorescent tube decreases as the temperature rises.

[0007]

With this configuration, the lighting circuit and the bent portion near the holder of the double U-type fluorescent tube are thermally conductively connected via the heat conductive adhesive and the holder. Also,
Since the inside diameter of the bent portion close to the holder of the double U-shaped fluorescent tube is smaller than the inside diameter of the non-bent portion of the fluorescent tube, the discharge current (plasma) density flowing through the fluorescent tube is reduced at this bent portion. As the temperature rises, the tube wall load at the bent portion increases, and the temperature of this portion becomes higher than the temperature of other portions of the fluorescent tube. Then, the heat of the bent portion is more sensitively fed back to the lighting circuit via the heat conductive adhesive. Further, since the lighting circuit has a characteristic that the input power decreases as the temperature rises, the lighting circuit and the fluorescent tube are stabilized at a predetermined input power and temperature.

[0008]

An embodiment of the present invention will be described below with reference to the drawings.

As shown in FIG. 1 (a), a bulb-type fluorescent lamp according to an embodiment of the present invention has a double U-type fluorescent tube 1 in which amalgam 3 is sealed in a small tube 2 at one end and a lighting device for lighting the same. And a circuit 4. The fluorescent tube 1 has a holder 5 at both ends.
And the bent portion 6 is arranged so as to be close to the holder 5.

A case 7 containing the lighting circuit 4 is provided.
And the globe 8 containing the fluorescent tube 1 constitutes an envelope 9. The bent portion 6 of the fluorescent tube 1 is as shown in FIG. That is, the outer periphery of the bent portion 6 is formed in an arc shape, but the inner periphery of the bent portion 6 is formed so as to approach the outer periphery so as to be smaller in diameter than the inner diameter of the straight portion.
Silicone resin 10 which is a thermally conductive adhesive is injected into the portion 5a of the holder 5 where the bent portion 6 is close to fix the bent portion 6 and the portion 5a of the holder 5 together.
The lighting circuit 4 housed inside is mounted on a holder 5,
It is provided close to the bent portion 6 via the holder 5.
A base 11 is provided at a protruding portion of the globe 8.

As shown in FIG. 2, the lighting circuit 4 includes a closed circuit including a capacitor 12, a fluorescent tube 1, a choke coil 13 as an inductance, a current transformer 14, and a transistor 15 as a switch element. A smoothing capacitor 17 is connected in parallel with these transistors, and an output side of a rectifier circuit 19 connected to an AC power supply 18 is connected in parallel with the smoothing capacitor 17. The fluorescent tube 1 is turned on by the on / off operation of 16. One of the two secondary windings of the current transformer 14 is connected between the base and the emitter of the transistor 15 via a resistor 20 to supply a base current to the base, and the other is connected via a resistor 21. It is connected between the base and the emitter of the transistor 16 and supplies a base current to the base. The resistor 22, the capacitor 23, and the trigger element 24 form a starting circuit of the lighting circuit 4. Here, the core of the current transformer 14 is
It has a characteristic that the saturation magnetic flux density decreases with an increase in the _core temperature T _core , that is, a characteristic that the input power decreases.
The number of primary windings and the number of secondary windings of the current transformer 14 are controlled by the transistors 1 and 2 via the resistors 20 and 21, respectively.
This circuit is connected to the bases of the transistors 5 and 16 so that the transistors 15 and 16 perform a saturation operation until the current transformer 14 is magnetically saturated, and the input power, the oscillation frequency and the starting voltage are appropriate. Is set to

Generally, the luminous efficiency of a fluorescent lamp depends on the mercury vapor pressure in the fluorescent tube, and there is a mercury vapor pressure at which the luminous efficiency is maximized. The mercury vapor pressure is the coldest temperature of the fluorescent tube,
Those using amalgam are determined by the amalgam temperature. When the amalgam composition is Bi-In-Hg, the luminous efficiency of the bulb-type fluorescent lamp is maximized when the temperature around the amalgam is about 90 ° C and 120 ° C at room temperature.

When an AC power supply 18 is applied to the lighting circuit 4, a preheating current and a starting voltage are applied to the fluorescent tube 1 by the lighting circuit 4, and the fluorescent tube 1 is started and turned on. Immediately after the start of the fluorescent tube 1, since the temperatures of the fluorescent tube 1 and the amalgam 3 are low, the mercury vapor pressure in the fluorescent tube 1 is low, and the luminous efficiency is low. When the discharge current continues to flow through the fluorescent tube 1 by the lighting circuit 4, the fluorescent tube 1 and the amalgam 3 are heated by this current, and this temperature gradually increases. Accordingly, the mercury vapor pressure of the fluorescent tube 1 also increases, and the luminous efficiency also increases.

The bent portion 6 of the double U-shaped fluorescent tube 1 is formed so that the outer periphery of the bent portion 6 is arc-shaped and the inner periphery of the bent portion 6 approaches the outer periphery so as to be smaller than the inner diameter of the straight portion. As a result, the discharge current (plasma) density flowing through the bent portion 6 of the fluorescent tube 1 increases at the bent portion 6, and
The tube wall load of the bent portion 6 increases. Therefore, the temperature of the bent portion 6 becomes higher than the temperature of other portions of the fluorescent tube 1. That is, the state of the mercury vapor pressure, the discharge current, and the like of the fluorescent tube 1 is amplified by the bent portion 6 and appears remarkably. The temperature of the bent portion 6 of the fluorescent tube 1 heats the lighting circuit 4 more sensitively through the silicone resin 10 which is a heat conductive adhesive, and is fed back to the lighting circuit 4.

The lighting circuit 4 operates as follows. Before starting the fluorescent tube 1, the AC voltage is rectified from the AC power supply 18 via the rectifier circuit 19 to charge the smoothing capacitor 17, and the capacitor 17 is charged via the resistor 22. When the breakdown voltage is reached, the charge of the capacitor 23 is supplied to the base of the transistor 16, and the transistor 16 is turned on. When the transistor 16 is turned on, the capacitor 12 from the AC power supply 18 via the rectifier circuit 19 → the one electrode 2 of the fluorescent tube 1
5 → the capacitor 26 → the other electrode 25 of the fluorescent tube 1 → the choke coil 13 → the current transformer 14 → the current flows to the transistor 16 while increasing. Next, when the core of the current transformer 14 is magnetically saturated by the current flowing through the primary winding of the current transformer 14, the output of the secondary winding is no longer generated, and the base current supplied to the transistor 16 cannot be supplied. Turns off. At the same time, the current due to the energy stored in the choke coil 13 flowing to the capacitor 12 via the current transformer 14 and the transistor 15 decreases with time, so that the output polarity of the secondary winding is inverted, and the transistor 15 is turned on. Turn 16 off. This current is supplied to the choke coil 13 and the capacitor 1
When the current reverses and the core of the current transformer 14 is magnetically saturated, the output of the secondary winding is lost and the base current supplied to the transistor 15 cannot be supplied. It turns off and then transistor 16 turns on again. Thereafter, this operation is repeated.

The current flows through the electrode 25 of the fluorescent tube 1 to heat the electrode. At the same time, a large voltage is applied to the fluorescent tube 1 by resonance, and the electrode temperature of the fluorescent tube 1 rises and the fluorescent tube 1 is turned on.

Next, when the fluorescent tube 1 is lit, the transistor 16 is turned on.
7 and the rectifier circuit 19, the capacitor 12 → the one electrode 25 of the fluorescent tube 1 → the capacitor 26 → the other electrode 25 of the fluorescent tube 1 → the choke coil 13 → the current transformer 14
A current flows through the next winding → the transistor 16. This current becomes a resonance current between the capacitor 12 and the choke coil 13. The capacitor 12 is charged by this current, a voltage is generated in the secondary winding of the current transformer 14, and the base current of the transistor 16 flows through the resistor 21 to keep the transistor 16 on.
At the same time, the output of the secondary winding is applied in the opposite direction between the base and the emitter of the transistor 15 to maintain the transistor 15 in the off state. Here, 2 of the current transformer 14
The output voltage of the secondary winding changes in proportion to the resonance state, and is a voltage that is reduced by the output current of the secondary winding from the voltage division with the inductance of the choke coil 13 by the amount of the magnetic flux reduction of the core. To increase. This voltage is
When increased to a voltage corresponding to a predetermined effective saturation density at the temperature T _1, the current transformer 14 by magnetic saturation at a predetermined current value, the output voltage of the secondary winding becomes zero, predetermined ON time transistor 16 Turn off with

Next, when the magnetic saturation of the current transformer 14 is eliminated, the transistor 15 is turned on by the choke coil 13 and the current which continues to flow while decreasing from the base-emitter of the transistor 15 to the collector. Reference numeral 16 maintains the off state.
This current is supplied to the choke coil 13 and the capacitor 1
When the current reverses and the core of the current transformer 14 is magnetically saturated again, the output of the secondary winding disappears and the base current supplied to the transistor 15 cannot be supplied. Turns off, and then transistor 16 turns on again.
Thereafter, this operation is repeated. At this time, the input power Ws is mainly determined by the ON period of the transistor 16.

Immediately after the start, the temperatures of the lighting circuit 4 and the fluorescent tube 1 are generally low, and the temperatures of the respective portions rise due to the heat generated by the bent portion 6 of the fluorescent tube 1 and other components. At this time, since the temperature of the amalgam 3 is low, the mercury vapor pressure of the fluorescent tube 1 is low,
Low luminous efficiency. However, since the core temperature of the current transformer 14 is low, the magnetic flux saturation density of the core is high, and the input power of the lighting circuit 4 and the fluorescent tube 1 is higher than the rated power, the luminous flux can be increased. Further, at this time, the discharge current of the fluorescent tube 1 is large, the heat generation of the fluorescent tube 1 can be increased, the temperature of the amalgam 3 can be rapidly increased, the mercury vapor pressure in the fluorescent tube 1 can be rapidly increased, and light emission can be achieved. Efficiency can increase rapidly. At the same time, since the voltage of the fluorescent tube 1 increases, the power consumption of the fluorescent tube 1 further increases, and the heat generation of the fluorescent tube 1, particularly the bent portion 6 having a large voltage drop, also increases. Heated rapidly. Therefore, the temperature T _core of the core of the current transformer 14 is rapidly increased, the saturation magnetic flux density of the core is rapidly decreased, and the input power Ws is also rapidly decreased. As a result, the discharge current of the fluorescent tube 1 is also rapidly reduced, and it is possible to quickly shift to the thermal equilibrium point at the time of rated lighting. At this time, the core temperature of the current transformer 3 becomes thermal equilibrium at T _1, this time, a predetermined input power (Ws ₁ in FIG. 3). Also, at this time, the mercury vapor pressure of the fluorescent tube 1 becomes an appropriate value, the luminous efficiency can be maximized, and even if the input power Ws is small, the output luminous flux can be almost equal to the initial lighting, and immediately after the start-up. An almost constant output light flux can be obtained until the temperature is stabilized. That is, overshooting of the output light flux and the temperature of the lighting circuit 4 can be eliminated, and the rise can be made faster.

By the above operation, the discharge of the fluorescent tube 1 can be maintained, and the fluorescent tube 1 can be kept on at a constant level.

Next, when the operating point of the lamp voltage-lamp current moves due to power supply voltage fluctuation or deterioration of the lighting environment, and the temperature of the whole bulb-type fluorescent lamp rises, the temperature of the amalgam 3 rises and the mercury vapor pressure rises. If the output luminous flux rises to exceed the optimum point of the luminous efficiency and decreases, the discharge current of the fluorescent tube 1 increases, so that the heat generated at the bent portion 6 of the fluorescent tube 1 increases, and The lighting circuit 4 is heated, the core temperature T _core of the current transformer 14 also rises,
The effective saturation density decreases. Therefore, the peak value of the secondary winding voltage of the current transformer 14 also decreases. Along with this,
The ON period of the transistor 16 decreases and the peak value of the collector current also decreases, and accordingly the oscillation frequency increases, the impedance of the resonance system increases, and the lamp current of the fluorescent tube 1 decreases. Therefore, the input power Ws also decreases as shown in FIG. As a result, the discharge current of the fluorescent tube 1 is reduced, and the calorific value of the whole bulb-type fluorescent lamp is reduced, so that the reduction in luminous efficiency and the output light flux can be reduced. When the temperature decreases, the reverse is true. That is, the output light flux and the temperature fluctuation of the lighting circuit 4 can be reduced with respect to the change of the surrounding environment. Therefore, the temperature rise of the electronic components used in the lighting circuit 4 is also suppressed, so that an inexpensive and small element can be obtained, and the reliability of the element can be improved and the safety can be improved. At the same time, since the overshoot of the discharge current can be eliminated, the life of the fluorescent tube 1 can be improved.

For example, in the circuit configuration shown in FIG. 2, the inductance of the choke coil 13 is 1.4 m.
H, capacitor 12 is 0.068 μF, capacitor 26
The lighting circuit 4 using the current transformer 14 and the fluorescent tube using amalgam are integrated as a bulb-shaped fluorescent lamp with a constant of 8200 pF, a smoothing capacitor 17 of 47 μF, and an AC power supply voltage of 120 V, and are started and lit at a rated input power of 18 W. did. As a result, the rise of the output light beam becomes faster than before and the time until stabilization can be shortened.
Even if the AC power supply voltage was increased and the ambient temperature was increased by putting the lamp in a small appliance, the rated lighting 18 W bulb-type fluorescent lamp could be safely maintained and good results were obtained.

In this embodiment, the bent portion 6 of the fluorescent tube 1 is used.
As shown in FIG. 1 (b), the bent portion 6 approaches the outer periphery such that the outer periphery of the bent portion 6 has an arc shape and the inner periphery of the bent portion 6 is smaller in diameter than the inner diameter of the straight portion. As a result, the discharge current of the fluorescent tube 1 is pushed toward the outer periphery of the bent portion 6, and the portion 5a of the holder 5 is further heated, so that the above effect can be further increased. further,
In the present embodiment, the bent portion 6 has the above-described shape. However, another shape may be used as long as the inner diameter of the bent portion 6 is smaller than the inner diameter of the non-bent portion of the fluorescent tube 1. The fluorescent tube 1
Is a fluorescent lamp having the electrode 25, but may have an electrodeless structure. The effect can be obtained even if the amalgam 3 is not used for the fluorescent tube 1, but a particularly large effect can be obtained in the case of the fluorescent tube 1 using the amalgam 3. The lighting circuit 4 may have another configuration as long as the lighting circuit 4 has a temperature characteristic in which the input power decreases as the temperature rises.

[0024]

As described above, according to the present invention, the overload of the arc tube and the destruction of the lighting circuit are prevented under any circumstances, and the output light flux rises quickly and has high security. A bulb-shaped fluorescent lamp can be obtained.

[Brief description of the drawings]

FIG. 1A is a partially cutaway front view of a light bulb-shaped fluorescent lamp according to an embodiment of the present invention. FIG.

FIG. 2 is also a lighting circuit diagram

FIG. 3 is a characteristic diagram of the core temperature Tcore of the current transformer and the input power Ws of the lighting circuit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Double U-shaped fluorescent tube 4 Lighting circuit 5 Holder 5a Holder part 6 Bending part 7 Case 8 Globe 10 Heat conductive adhesive 14 Current transformer

────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoji Tashiro 1006 Kazuma Kadoma, Kadoma City, Osaka Inside Matsushita Electronics Corporation (56) References JP-A-64-63201 (JP, A) JP-A-5-205 347139 (JP, A) JP-A-58-181262 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H01J 61/30 H01J 61/32 H01J 61/34 H05B 41/00

Claims (1)

(57) [Claims] 1. A double U-shaped fluorescent tube having both ends fixed to a holder, and a bent portion close to the holder fixed to the holder by a heat conductive adhesive, and a lamp for lighting the fluorescent tube. A lighting circuit, a case accommodating the lighting circuit, and a glove accommodating the fluorescent tube, and forming an envelope with the case, wherein the bending is close to the holder of the fluorescent tube. The inner diameter of the part is smaller than the inner diameter of the non-bent part of the fluorescent tube, and the lighting circuit is
A bulb-type fluorescent lamp characterized in that the input power to the fluorescent tube decreases as the temperature of the fluorescent tube increases.