KR200221611Y1 - Refillable electronic bulb type fluorescent lighting equipment having automatic turn-on/ off function by light dependent sensor - Google Patents

Abstract

The present invention relates to an electronic light bulb fluorescent lamp for refilling with automatic flashing function according to the ambient light and darkness, and has a structure that can separate the body part containing the electronic parts for lighting control and the fluorescent glass tube emitting light. To provide a way to:

To this end, a) A plug-type socket 10 having a structure in which the fluorescent glass tube 20 can be inserted or removed can be mounted in the body 30, and b) the existing electric electric bulb type to suppress the bulkiness of the body while doing so. Instead of removing the components for heating the filament 22 in the fluorescent lamp circuit, use a fluorescent lamp with a built-in glow starter 23, and c) use a cds as an illuminance sensor to brighten the ambient light of the switching transistor 1a. The fluorescent lamp is turned off by dropping the base voltage to stop the operation, and when it is dark, the fluorescent lamp is turned on by normalizing the base voltage of the transistor to enable operation.

With the above configuration, it is possible to install a plug-type socket in the center of the body by not using a capacitor and a thermistor which is a large volume of the existing circuit. The body can be recycled and it will automatically turn on and off according to the light and dark surroundings.

Description

Refillable electronic bulb type fluorescent lighting equipment having automatic turn-on / off function by light dependent sensor

The present invention relates to an electronic bulb type fluorescent lamp for refill having a function of automatically turning on and off according to contrast, and more specifically, an electronic component for lighting control is built so that only fluorescent glass tubes which have reached the end of their life can be replaced and reused. The socket 10 is mounted on the center of the body 30 so that the plug-in fluorescent glass tube 20 can be inserted and removed, and the refilling electronic appliance has a function of automatically turning off or turning on according to the surrounding light and dark. The structure and lighting control circuit of an old fluorescent lamp.

In general, the electronic bulb-type fluorescent lamp circuit is centered on the inverter circuit to generate a high frequency by alternately high-speed switching the transistor (1a) and transistor (1b) by alternating the AC power to direct current as shown in FIG.

This requires a process for preheating the filament 22 when it is turned on due to the characteristics of the fluorescent lamp. However, if this process is omitted and artificial discharge is started by applying a high voltage, the life of the fluorescent lamp is shortened. The filament is heated via the condenser 5b and the thermistor 6.

In particular, thermistor has a small resistance value at initial lighting, which contributes to rapid light-up due to a large amount of current flowing through the filament. It is a factor that shortens the lifetime of the entire circuit.

In the conventional method, when the input AC voltage is 220V, the condenser 5a having a breakdown voltage of 400V or higher, the condenser 5b having a breakdown voltage of 600V or higher, and a spare space around the thermistor which is a heat generating element are used while the body is completely used. Mounting the detachable socket 10 having a large volume in the middle of (30) had a structural problem to grow the body deformed, so the user discards the body with the still life remaining with the fluorescent glass tube which has reached the end of its life to be.

In addition, the day and night automatic flashing function has a problem in that the energy is wasted by turning on the lamp even when the surroundings are bright by a light source other than sunlight because it is a spectral spectrum method based on sunlight.

Therefore, the present invention has the function of automatically turning on and off according to the surrounding bright and dark regardless of the light source to solve the above problems, and can be easily replaced by recycling only the fluorescent glass tube of the end of life refill electronic bulb-type fluorescent lamp To provide a method for producing a.

1 is a circuit diagram of a general electronic bulb fluorescent lamp.

Figure 2 is a circuit diagram of the electronic bulb fluorescent lamp for refill according to the present invention.

Figure 3 is a front state diagram showing a fixed connection portion of the body of a conventional electric bulb fluorescent lamp and fluorescent glass tube.

Figure 4 is a perspective view of the electronic bulb fluorescent lamp fixture for refill according to the present invention.

5 is a view showing a refill electronic bulb fluorescent lamp fixture according to the present invention.

6 is a perspective view of a plug-type socket and a fluorescent glass tube of the structure of detachable fluorescent glass tube.

Figure 7 is a block diagram of an automatic flashing function according to the present invention.

8 is a view showing the correlation of the automatic flashing light signal according to the present invention.

<Explanation of symbols for main parts of the drawings>

1a, 1b: switching transistor

5a, 5b: fluorescent lamp filament heating capacitor

6: Thermistor for heating fluorescent lamp filament

7: Bonding part of body and fluorescent glass tube

10: Removable socket for body and fluorescent glass tube

20: Plug type fluorescent glass tube with built-in glow starter

40: printed circuit board

50: timer 51: illuminance sensor 52: Schmid trigger

The present invention has a function of automatically turning on and off according to the surrounding light and dark, and the plug-type socket to insert or pull out the plug-type fluorescent glass tube 20 as shown in Figure 6 (before type approval 1-3-1910 ) Is mounted on the center of the body (30) is simply a method for manufacturing a refillable electronic bulb-type fluorescent light fixture that can be recycled by replacing only the end of the fluorescent glass tube.

First, by changing the heating method of the fluorescent lamp filament, as shown in Figure 6 using a plug-type fluorescent glass tube with a built-in glow starter commercially available as a component for heating filament in the circuit of a conventional electronic bulb fluorescent lamp It is not necessary to use condenser (5a), condenser (5b) and thermistor (6), thus reducing the number of parts. Especially, the reliability of the circuit is eliminated by removing the thermistor, which is a heating element that accounts for about 20% of failures, among existing products. Is increased.

The fluorescent lamp starting method by the glow starter 23 has a disadvantage that it takes 2 to 3 seconds to turn on after switching to the method which has been used for a long time, but here, it is not necessary to use a bulky filament heating part, but also a body and a fluorescent lamp. There are two advantages that can make the glass tube detachable.

In addition, the choke coil 4 is used to induce the discharge voltage, and since it is the bulkiest in the entire circuit, the choke coil is provided between the socket 10 and the base 11 as shown in FIG. .

Next, as shown in FIG. 2, the overall circuit according to an embodiment of the present invention is shown as a function of automatically lighting when it is dark and automatically turning off when it is bright. In FIG. 2, the upper circuit corresponds to an electronic ballast for turning on a fluorescent lamp centering on the switching transistors 1a and 1b, and the lower circuit is an automatic centering around a timer 50 and a CDS 51 which is an illuminance sensor. It is the signal generating part of the lighting lamp and controls the ballast circuit of the upper part through the transistor 1c. Hereinafter, the operation of each part will be described in detail individually, and finally, the interface of the two parts will be described. The ballast section is described. The electronic ballast circuit is the same except for replacing the filament heating parts 5a, 5b, 6 of the fluorescent lamp with the glow starter 23 in the existing product circuit of FIG. When AC220V power is supplied, direct current is made by rectifying diode (D1-4) and smoothing capacitor (C1), and the charge charged in capacitor (C2) through resistor (R3) of transistor (1a) through diac (D6). Transistor 1a is turned on while being applied to the base. When the transistor 1a is turned on, the charging current of the capacitor C4 increases through the pulse transcoil 3a, the choke coil 4 and the lamp, and at the same time, the forward organic electromotive force (5V PEAK) is applied to the pulse transcoil 3c. This occurs, and the transistor 1a is kept in the ON state. When the charging voltage of the capacitor C4 increases and the charging current decreases, the reverse organic electromotive force of opposite polarity is generated in the pulse coil 3c, so that the transistor 1a is turned off and the transistor 1b is provided to the pulse coil 3b. Forward organic electromotive force is generated. This time, the transistor 1b is turned on, and the discharge current of the capacitor C4 in the opposite direction of the current flows. However, due to the inductance of the choke coil 4, a large counter electromotive force is generated that the current direction does not change suddenly, and the lamp is turned on, and the diode D8 becomes a path of the counter electromotive force. As the discharge current of the capacitor C4 through the transistor 1b decreases, the organic electromotive force of the pulse coil 3c turns on the transistor 1a again, and the transistor 1b is turned off, and the above operation is repeated. Switching is performed. Next, a description will be given of the auto-lighting signal generation portion in accordance with the contrast of the lower circuit of FIG. The power supply of this circuit is supplied with 7.5V through the resistor R9, the smoothing capacitor C5 and the zener diode ZD, and is detailed in the signal correlation diagram of FIG. 8 for a detailed understanding of the signal level. The peripheral circuit of the timer 50 is a typical pulse generating circuit, and a pulse (HIGH: 6.5V LOW: 0V) of about 200 ms in width is output from the terminal 3 at intervals of about 10 minutes. The pulse voltage is converted into the OP AMP 53. The signal is converted into HIGH: 5.4V LOW: 2.2V by the voltage distribution by the resistors R12, R13, and R14, and is input to the inverting terminal of the Schmid trigger 52.

When the ambient light gradually darkens, when the resistance value of the illuminance sensor CDS increases and the voltage of the non-inverting terminal of the Schmid trigger 52 becomes larger than 2.2 V, the output voltage becomes HIGH (5.2 V) and the transistor through the resistor R16. (TR1) is turned ON and the non-inverting terminal is fed back to the non-inverting terminal with the resistor R19 so that the non-inverting terminal voltage is increased to 3.5V so that the lamp does not turn off even if the CDS resistance value is reduced by its lamp light. However, if this condition persists, the lamp will not turn off even if the ambient light becomes bright. Therefore, the Schmid trigger is applied to the inverting terminal of the Schmid trigger 52 by applying a 5.4 V voltage of 200 mS pulse width greater than 3.5 V of the non-inverting terminal voltage every 10 minutes. The lamp is turned off while the output voltage of (52) is set to LOW (0 V). By doing so, the contrast of pure ambient light without lamp light is determined, and if it is bright, the output voltage of the Schmid trigger 52 becomes LOW and the lamp is turned off. In this case, the output voltage becomes HIGH and the lamp is turned on. Finally, the interface with the electronic ballast which is turned on when the output signal of the Schmid trigger 52 is HIGH and turned off when it is LOW will be described. When the output signal of the Schmid trigger 52 is LOW (0V), the transistor TR1 is in an OFF state, and at this time, the 7.5V voltage is forward biased to the base of the transistor 1c through the resistor R1, and thus the transistor 1c. Is turned on. As a result, the base voltage of the switching transistor 1a is bypassed to the collector-emitter of the transistor 1c so that the operation of the transistor 1a is stopped and the lamp cannot be turned on. On the contrary, when the Schmid trigger 52 output voltage is HIGH (5.2V), the transistor TR1 is turned on so that the base voltage of the transistor 1c becomes 0V and the transistor 1c is turned off. As a result, the base of the switching transistor 1a is triggered by the diaak D6, and the normal switching operation is started and the lamp is turned on.

As described above, it has a function of automatically turning on and off according to the surrounding light and dark regardless of the spectral spectrum of the light source.It is equipped with a socket that has reached the end of its life by installing a socket (1-3-1910 before type approval) By replacing only the fluorescent glass tube of the body can be recycled, since the plug-type fluorescent glass tube is already commercialized in various ways, there is a side effect of creating a new atmosphere by selecting a lamp according to the user's taste when replacing.

Claims (2)

In the electric bulb type fluorescent light fixture, a socket having a structure in which a plug type fluorescent glass tube can be inserted or removed in the center of the body so as to separate the body in which the lighting control circuit is built and the fluorescent glass tube emitting light. Rechargeable electronic bulb fluorescent light fixture. The refillable electric light-emitting fluorescent lamp of claim 1, wherein the socket is made of an equivalent product of type approval (formerly 1-3-1910) and a choke coil is installed between the socket and the base.