KR920000482B1 - Light emitting device - Google Patents

Abstract

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Description

Light emitting device

1 is a circuit diagram showing an embodiment of the present invention.

2 is a characteristic diagram of voltage variation.

3 is a frequency variation characteristic diagram.

4 is a voltage and current characteristic diagram of a starting device.

5 is a principle diagram of a lamp of another embodiment of the present invention.

TECHNICAL FIELD The present invention relates to a light emitting device, and more particularly, to a lighting device suitable for stabilizing electrical characteristics of a small lamp and for widening a frequency application range.

In the conventional apparatus, as described in Japanese Patent Application Laid-Open No. 57 (1982) -180967, a lamp having a power source of direct current (DC source) and a ballast are resistors. In Japanese Patent Application Laid-Open No. 63 (1988) -19750, in a low-pressure discharge lamp in which at least one pair of electrodes and a discharge gas are enclosed in a gas tightly formed discharge vessel, when one of the electrodes operates as an anode, The electrode structure arranged such that the electrode acting as the anode is located in the negative glow results in a small anode high voltage low voltage discharge lamp with a low anode drop voltage of 0, resulting in a low lamp voltage and a discharge start voltage, and an increase in luminous efficiency. What is obtained is described.

In the above prior art, when lighting using a DC power source, the ballast for controlling the lamp current, that is, the ballast, is composed of a resistor, so that the power consumption and heat generation in the ballast are large, and the efficiency of the entire device is very low. There was a flaw. In addition, when lit with an AC power source, the following drawbacks were present. That is, first, since there are two hot cathodes, the scattering amount of the hot electron emission material is about twice that of one case, and the operation process characteristics of the lamp are deteriorated. Secondly, since the two hot cathodes alternately operate as anodes, they are heated with power corresponding to the product of the lamp current and the work function of the electrode during the anode cycle. Therefore, if the lamp current fluctuates due to fluctuations in the power supply voltage, fluctuations in the frequency of the power supply, or fluctuations in the characteristics of the ballast, the heating state of the electrode is remarkably fluctuated, and as a result, the scattering of the hot-electron radiating material is increased. For example, it was not possible to share Barast at 50Hz and 60Hz.

An object of the present invention is to provide a compact light emitting device which can use an AC power supply pressure, which has good circuit efficiency, is stable against fluctuations in power supply voltage, and which can be used in common for 50 Hz and 60 Hz.

The above object is achieved by providing a rectifier circuit for making a ballast as a capacitor and a direct current for alternating voltage as a lamp lighting circuit, and for combining a combination of one anode and one hot cathode as an electrode configuration.

That is, the light emitting device according to the present invention includes a discharge vessel in which rare gas is enclosed, and a negative glow region formed between the hot cathode coated with a hot electron radiating material and the discharge container and formed between the hot cathode. A rectifier connected to each of the hot cathode and the anode for supplying direct current power to the discharge vessel, an anode disposed therein, and an AC power supply connection terminal for controlling a discharge current in the discharge vessel. It consists of a capacitor bar connected between the AC input terminal of the rectifier.

As described above, according to the present description, a circuit having a ballast as a capacitor is much more efficient in circuit efficiency than a conventional resistor ballast, has better voltage fluctuation characteristics than a choke coil ballast, and a rectifier circuit. Since it can be used, operation process characteristics do not deteriorate according to the change of lamp current, and a small, high efficiency light emitting device for 50-60 Hz is obtained.

Further, according to the embodiment of the present invention, the starter also uses a nonlinear semiconductor switch, whereby it can be built into the lamp to produce and provide a very compact lamp.

First, the principle of this invention is demonstrated.

In a low-pressure discharge in which at least one pair of electrodes and a discharge gas are enclosed in a gas tightly formed discharge vessel, when one of the electrodes acts as an anode, the electrode acting as the anode is in the negative glow. In low-voltage discharge and the like, which have an electrode structure arranged so as to be positioned, the lamp voltage is about the metastable excitation voltage of the rare gas, and is significantly lower than lamp voltages of ordinary fluorescent lamps. In addition, the change in the lamp voltage caused by the lamp current also shows a so-called negative characteristic in a normal fluorescent lamp. When the lamp current increases, the lamp voltage decreases. However, in the low-voltage discharge lamp used in the present invention, the lamp voltage changes with the lamp current. Almost unchanged

By using the low voltage discharge lamp having the characteristics described above and configuring the ballast which is a lamp current control part as a condenser, even if the power supply voltage fluctuates greatly with alternating current, the voltage pressure across the lamp, i.e., the lamp voltage is relatively small at about 9V, Since the voltage is almost negligible with respect to the voltage of 100 V, the lamp current is almost determined by this value when the size of the ballast is determined, and the lamp voltage-lamp current characteristics are generally flat even when the power supply voltage fluctuates. Only the ratio is proportional to the variation of the lamp current. Therefore, as in the case of a combination of a conventional choke coil ballast and a fluorescent lamp, the variation in the current voltage characteristic of the ballast itself and the current voltage characteristic variation of the lamp itself are eliminated due to the change in the power supply voltage, and thus a very stable current characteristic. It is possible to make a device with.

In addition, by installing a rectifier in the lighting power supply circuit and converting it into a DC power supply, an electrode configuration of a low-voltage discharge lamp can be made into one hot cathode and one anode, and since the anode simply collects electrons, it is necessary to use a hot electron radiating material. Since the shape is also free, metal plates, wires and the like with small scattering can be used. Therefore, even if the temperature of the cathode changes due to fluctuating lamp current, the anode material is less scattered and the operation of the lamp is excellent.

In addition, when a capacitor is used as the ballast, there is no electric loss and a high efficiency light emitting device is obtained. In addition, since there is no saturation characteristic such as choke coil, even if the power supply voltage fluctuates, the fluctuation of the lamp current is small.

By providing a rectifier and using an AC power source as a DC power source, an electrode configuration such as low voltage discharge can be formed by a combination of an anode and a hot cathode. Since the anode can be freely selected in material and shape, even if the lamp current changes, the scattering of the anode material can be reduced.

Next, embodiments of the present invention will be described with reference to the drawings. 1 shows a light emitting device of the present invention, (1) a capacitor as a ballast, (2) a rectifier, (3) a starting device, (4) a lamp, and a hot cathode having a filament or the like ( 6) has an anode 7 composed of a metal rod or plate, and the lamp light emitting portion 5 is made of glass or the like, and the inner surface of the glass transmits ultraviolet rays, for example, with no phosphor or nothing applied thereon. It is made using glass. The light emitting unit 5 has a structure in which airtightness is maintained, rare gas such as argon, and mercury are encapsulated to generate appropriate ultraviolet rays, and the distance A between the anode 7 and the cathode 6 is determined by the anode ( 7) is made less than 10 mm, i.e. 0 < A <

In Fig. 1, the discharge vessel of the light emitting portion 5 is made of ultraviolet-transparent glass having a diameter of 15 mm and a length of 45 mm, and the hot cathode 6 is made of a tungsten coil (Ba, Sr, Ca) which mainly uses a hot electron radiating material. It was set as the apply | coated structure, the anode 7 was made into the nickel plate, and distance A between the anode 7 and the hot cathode 6 was 3 mm. Incidentally, the entrained gases were 5 Torr and mercury. The capacitor | condenser 1 uses 10 micro F and the rectifier 2 as a full wave rectifier, and uses an AC power supply of 50 Hz 100V.

In the light emitting device configured as described above, the result of measuring the lamp fluctuation characteristic, that is, the voltage fluctuation characteristic with respect to the fluctuation of the power source voltage is shown in FIG. 2, and the curve 8a shows the lamp current characteristic of the present invention. If this increase is about 10%, the lamp current increases, but it is very small at about 10% and does not cause any trouble in practical use. On the other hand, when a resistor, which is a conventional ballast, is used instead of the capacitor ballast 1 of the present invention, the heat generation and power consumption by the resistor are large as described above, and when the power supply is 100V AC voltage, the voltage applied to the resistor is It becomes about 90V, its luminous efficiency, i.e., its luminous amount / input power, is very bad, and its application value is scarce (see Table 1). On the other hand, when the conventional choke coil ballast is used instead of the capacitor ballast 1, the variation rate of the lamp current becomes the curve 9a of FIG. 2, which is very large compared with the present invention. This is due to the fact that the voltage and current characteristics of the choke coils themselves have a non-linear performance in which current increases rapidly at high voltages.

In addition, as shown in FIG. 1, in the case of the choke ballast, the power consumption due to the resistance in the ballast is large, so that the input power of the device is increased and the luminous efficiency is also lowered.

Also, when the capacitor ballast 1 is used for the frequency fluctuation of the power supply, the lamp current fluctuation characteristics in the case of changing from 50 Hz to 60 Hz are shown as curve 10 in FIG. The fluctuation rate is about 20%, and it is the range which can endure enough practically, and the desired performance can also be obtained. On the other hand, by changing from 50 Hz to 60 Hz in combination with the choke coil, the ramp current variation rate is reduced by 30% or more, as shown by the curve 11, and it is difficult to obtain the performance of sharing 50 Hz and 60 Hz in practical use. In particular, since the lamp 4 uses a hot cathode such as a fluorescent lamp, the reduction of the lamp current causes a significant reduction in the service life, which significantly reduces the value of the product.

According to the present invention, the condenser 1 acts as a ballast, and the rectifier 2 is provided and converted into a direct current power source, whereby the configuration of the electrode can be the positive electrode 7 and the hot cathode 6. Since the anode 7 is made of a metal such as a nickel plate which is much less scattered than a thermal electron radiating material such as (Ba, Sr, Ca) 0, the anode 7 may change even if the lamp current changes depending on the power voltage or the frequency of the power source. There was little scattering of, and the operation process characteristics were good.

As for the lamp starting device 3 of the apparatus of the present invention, as shown in FIG. 4, a voltage is applied to the non-linear semiconductor switch through which a high current flows by significantly lowering the resistance at both ends by a predetermined voltage or more, as shown in FIG. Since the components are small in size, they can be fabricated in particular in the detention part of the lamp component, so the lamp 4 is very small.

In addition, when the power supply voltage is 100V in the lamp 4 of the present invention, the capacitor 1 is about 10μF, the lamp voltage is 9V, the lamp current is 0.35A, the device input power is about 3.5W, the ballast consumption The power is 0.5W and it can be a small high efficiency lamp.

[Table 1]

5 shows a lamp 4 of another embodiment. The anode is electrically connected to one end of the hot cathode 6 and is generally provided in equilibrium with the hot cathode 6. No discharge starter is necessary. When a voltage is applied to the light emitting portion 5 of the lamp 4 through the condenser ballast rectifier 2, the hot cathode 6 is heated. As the temperature of the hot cathode 6 increases, the electrical resistance of the hot cathode 6 also increases, so that the voltage difference between the anode 70 and the end 71 of the hot cathode 6 becomes large, and thus the end of the anode 70 and the hot cathode 6. A discharge occurs between 71 and. This embodiment has the advantage that the discharge starter is unnecessary and can be further miniaturized.

Claims (7)

A discharge vessel filled with at least rare gas, a hot cathode provided in the discharge vessel and coated with a hot electron radiating material, an anode disposed in a negative glow region formed between the discharge vessel and the hot cathode, and A rectifier having a direct current output connected to the hot cathode and the positive electrode respectively for supplying direct current power to a discharge vessel, and an AC power supply connection terminal and an AC input terminal of the rectifier for controlling a discharge current in the discharge vessel. A light emitting device having a condenser ballast connected to a light source. The light emitting device according to claim 1, further comprising a starter connected between the hot cathode and the anode to generate a discharge in the discharge vessel. A light emitting device according to claim 1, wherein said anode is made of Ni plate. 3. A light emitting device according to claim 2, wherein a detention is provided at an end of said discharge vessel, and said detention includes said starting device. A light emitting device according to claim 4, wherein said starting device is made of a nonlinear semiconductor switch. The light emitting device of claim 1, wherein the discharge vessel is filled with rare gas and mercury, and the discharge vessel is made of UV-transmissive glass. The light emitting device according to claim 1, wherein the discharge vessel is filled with rare gas and mercury, and the discharge vessel has a phosphor film on an inner wall thereof.

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