KR101375867B1 - Ultraviolet lamp of long life - Google Patents

Abstract

The present invention relates to a long-life ultraviolet lamp, comprising: a glass tube having an opening portion; A horizontal electrode and a vertical member are integrally formed so as to be coupled to the opening of the glass tube, and an electrode socket made of a metal material having an inner space formed by the horizontal member and the vertical member connected to a filling space of the glass tube; It is composed of a dielectric applied to the space portion of the electrode socket, so as to improve the capacitance at a low voltage while improving the light efficiency and ultraviolet output during the plasma discharge of the gas filled in the glass tube, coupled to the opening of the glass tube By adopting the electrode socket method coated with the dielectric, the contact area between the electrode socket and the gas filled in the glass tube is widened to improve the UV emission efficiency, and the size and shape of the glass tube and the electrode socket are different. By increasing the area in contact with the discharge gas, it is possible to meet the capacitance required by the user while preventing the generation of dark zones, and because a negative resistance characteristic is not generated by forming a dielectric on the electrode socket, one inverter In addition to driving a large number of lamps, the glass tube formed on the electrode socket While improving the fixing force of the glass tube through the government, by applying the dielectric only to the position where the glass tube fixing portion is formed, it is possible to prevent the phenomenon of the dielectric damage by the glass tube when the glass tube and the electrode socket is combined, as well as the glass tube and the electrode socket through the sealing member It provides a long-life UV lamp that can improve the efficiency by sealing the.

Description

Long life ultraviolet lamps {Ultraviolet lamp of long life}

The present invention relates to a long-life UV lamp, and more particularly, by adopting an electrode socket method in which a dielectric is bonded to the opening of the glass tube, the contact area between the electrode socket and the gas filled in the glass tube is widened. The UV emission efficiency can be improved, and the size of the glass tube and the size or shape of the electrode socket can be increased to increase the area in contact with the discharge gas, thereby preventing the occurrence of dark zones and satisfying the capacitance required by the user. In addition, since the negative resistance characteristic is not generated by forming a dielectric in the electrode socket, not only a single inverter can drive a plurality of lamps, but also the glass tube fixing part formed on the electrode socket improves the fixing force of the glass tube. , Apply dielectric only up to the position where the glass tube fixing part is formed. It can be prevented from being damaged by a dielectric tube, as well as to seal the glass tube with an electrode socket through the sealing member relates to a long-life UV lamp which can improve efficiency.

In general, a fluorescent lamp is classified into an internal electrode fluorescent lamp in which an electrode is positioned inside the lamp, and an external electrode fluorescent lamp (EEFL) in which the electrode is positioned outside the lamp.

Examples of the internal electrode fluorescent lamps include Hot Cathode Fluorescent Lamps (HCFLs) and Cold Cathode Fluorescent Lamps (CCFLs).

The electrode fluorescent lamp is configured by forming an electrode 120 including the dielectric 121 in the glass tube 110 as shown in FIG.

In addition, as shown in FIG. 2, the external electrode fluorescent lamp (EEFL) has a glass tube 210 under the external electrode 220 serving as a dielectric as shown in FIG. 2. The same effect as the connection of C1 and C2) can be obtained, which allows a plurality of lamps to be driven in parallel. In other words, unlike HCFL and CCFL, EEFL can achieve the effect of multiple simultaneous driving through a single driving circuit, which can reduce the cost of circuit configuration, simplify the structure of the mechanism, and provide the advantages of long life. You can get it.

However, the internal electrode fluorescent lamp 100 as shown in FIG. 1 can emit high capacitance and high brightness accordingly, but the electrode 120 is formed therein, and the electrode is sputtered during plasma discharge. There was a problem that the wear of the (121) is severe and difficult to use for a long time.

In particular, when it is desired to emit high brightness light, the amount of contact with the discharge gas must be increased. In order to do so, the size of the electrode 121 must be increased. In this case, when the size of the electrode 121 is enlarged, In addition to the stuttering phenomenon, a problem has been pointed out that a dark zone (a blind spot where light does not emanate) is formed in a space in which the electrode 121 is enlarged.

In addition, the external electrode lamp 200 is configured such that the glass tube 210 inside the external electrode 220 serves as a dielectric. Most glass tubes 210 have a dielectric constant of only about 6 to 7 and a dielectric breakdown voltage. Since it is very low at 2 kV / mm, the design of high efficiency and high power lamps was not possible.

That is, the conventional EEFL uses a glass tube in consideration of optical characteristics, but the glass tube has a problem in that the capacitance value is lowered due to poor electrical characteristics as a dielectric.

In addition, in order to overcome this problem, although the optical characteristics are partially improved when the applied voltage is increased, a problem in which a pinhole, which is an insulation breakdown phenomenon of the glass tube, is generated, causes a shortening of the service life.

Long life ultraviolet lamp of the present invention for solving the above problems forms a filling space in which gas is filled inward and both sides of the glass tube formed an opening; A horizontal electrode and a vertical member are integrally formed so as to be coupled to the opening of the glass tube, and an electrode socket made of a metal material having an inner space formed by the horizontal member and the vertical member connected to a filling space of the glass tube; Characterized in that the dielectric is applied to the space portion of the electrode socket so as to improve the capacitance at a low voltage while improving the light efficiency and ultraviolet output during the plasma discharge of the gas filled in the glass tube.

In the present invention, the space portion in which the horizontal member is formed in the space portion where the dielectric is applied to the inner side of the electrode socket is further configured to include a glass tube fixing part of the protruding jaw shape or double tube shape to fix the glass tube when combined with the glass tube. It is characterized by.

In the present invention, the dielectric formed in the space portion of the electrode socket is applied to the entire space portion, when the glass tube fixing portion of the protrusion jaw configuration is characterized in that the dielectric is formed only up to the position where the glass tube fixing portion is formed.

In the present invention, a protective film is further included on the outside of the dielectric formed in the space portion of the electrode socket.

In the present invention, between the glass tube outer side and the electrode socket is characterized in that the sealing member for forming the inside of the glass tube in a vacuum state is further included.

In the present invention, the sealing member is composed of any one of a vacuum ceramic paste or glass in the form of a paste, and is characterized in that the glass tube and the electrode socket are bonded to the outside after the heat treatment to fix and bond.

The present invention adopts an electrode socket method coated with a dielectric coupled to the open portion of the glass tube, thereby increasing the contact area between the electrode socket and the gas filled in the glass tube, thereby improving the ultraviolet emission efficiency.

In addition, by increasing the area in contact with the discharge gas by varying the size of the glass tube and the size or shape of the electrode socket, it is possible to meet the capacitance required by the user while preventing the generation of dark zones.

In addition, since a negative resistance characteristic is not generated by forming a dielectric in the electrode socket, a plurality of lamps can be driven using one inverter.

In addition, while improving the fixing force of the glass tube through the glass tube fixing portion formed on the electrode socket, the dielectric can be prevented from being damaged by the glass tube when the glass tube and the electrode socket are combined by applying the dielectric to the position where the glass tube fixing portion is formed.

In addition, the sealing member is a useful invention that can improve the efficiency by sealing the glass tube and the electrode socket.

1 is a side view showing a conventional internal electrode lamp.
Figure 2 is a side view showing a conventional external electrode lamp.
3 is a circuit conceptual diagram of a conventional external electrode lamp.
4 is a cross-sectional view of a long life ultraviolet lamp according to the present invention.
Figure 5 is a state diagram showing a state in which the glass tube fixing portion is formed on the metal socket.
6 is a state diagram showing another embodiment of FIG.
7 is a state diagram showing another embodiment of FIG.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIG. 4, the glass tube 10 includes a filling space 11 filled with discharge gas such as Ne, Ar, and He, and opening portions 12 on both sides of the filling space 11. ) Is configured.

Such a glass tube 10 may be formed of various materials, and preferably, a quartz tube may be used.

The quartz tube has advantages of high light transmittance, in particular, ultraviolet light as well as ultraviolet light transmittance, and high electrical insulation and low coefficient of thermal expansion, compared to general glass, to withstand rapid cooling and rapid heat.

In addition, it is preferable that the glass tube 10 in this invention produces a diameter of Φ10-50.

Next, the electrode socket 20 is configured to be coupled to the opening 12 formed on both sides of the glass tube 10 to apply power.

The electrode socket 20 has a shape such as a cap in which the horizontal member 21 and the vertical member 22 are integrally formed, and the space 23 therein by the horizontal member 21 and the vertical member 22. It consists of a formed structure.

At this time, the electrode socket 20 is preferably composed of a metal material to enable the power supply.

In addition, the glass tube fixing part 40 may be further configured in the space 23 formed by the horizontal member 21 of the space 23 of the electrode socket 20.

The glass tube fixing part 40 may be configured to protrude as shown in FIG. 5, or the glass tube fixing part 40 may be formed in a double tube shape as shown in FIGS. 6 to 7.

Next, the dielectric D is evenly applied to the space 23 of the electrode socket 20.

The dielectric (D) may be composed of any one selected from among barium titanate (BaTiO ₃ ) and aluminum oxide (Al ₂ O ₃ ) having a high dielectric constant.

In particular, the dielectric D may be applied to the entire space 23 of the electrode socket 20 as shown in FIGS. 5 and 6 to 7, and protrudes in the space 23 as shown in FIG. 5. When the glass tube fixing portion 40 is formed, it is preferable to apply the horizontal member 21 and the vertical member 22 to the position where the glass tube fixing portion 40 is formed.

In addition, in the present invention, the protective film P may be further formed on the outer side of the dielectric D.

The passivation layer P is formed to increase the dielectric constant and increase the dielectric breakdown voltage while protecting the dielectric D so as to prolong the life of the lamp. The protective film P may be any one selected from magnesium oxide (MgO) and zinc oxide (ZnO). It is available.

Next, in the present invention, the sealing member 30 may be further applied to the coupling portion of the glass tube 10 and the electrode socket 20.

The sealing member 30 may be formed between the glass tube 10 and the electrode socket 20 to secure the sealing property, and may be fixedly coupled through heat treatment after applying a vacuum paste or glass in the form of a paste. .

Looking at the effect of the present invention made of a configuration as described above are as follows.

The long-life UV lamp 50 of the present invention combines the electrode socket 20 to which power is applied to the opening 12 in a state in which openings 12 are formed on both sides of the glass tube 10, thereby providing a glass tube ( 10) By expanding the contact surface with the discharge gas filled inside, the capacitance can be improved than the conventional internal electrode method.

That is, in the present invention, since the electrode socket 20 is not formed inside the glass tube 10 but is coupled to the openings 12 on both sides of the glass tube 10, the capacitance is expanded as described above. If there is a need to do so, the diameter of the glass tube 10 and the electrode socket 20 can be easily solved through the enlargement or deformation of the shape.

In particular, since the electrode socket 20 is not configured to be coupled to the inside of the glass tube 10, dark zones (blind spots that do not emit light) do not occur, thereby further improving efficiency.

On the other hand, in the present invention by applying a dielectric (D) in the electrode socket 20 it is possible to drive the long-life ultraviolet lamp 50 of the present invention through one inverter (not shown in the figure).

That is, when a direct contact between the power source and the discharge gas occurs, a problem arises in that the negative resistance characteristic is generated. In the present invention, a dielectric D is applied to the electrode socket 20 to prevent the negative resistance characteristic. It will act to drive a plurality of lamps through.

In addition, in the present invention, as well as the effect of improving the bonding force between the glass tube 10 and the electrode socket 20, the glass tube fixing portion 40 is formed on the electrode socket 20 to form the open portion 12 on both sides, When the glass tube 10 and the electrode socket 20 are combined, the defect rate of the dielectric D applied to the electrode socket 20 by the glass tube 10 opening 12 may be prevented, thereby reducing the defective rate. Will be.

On the other hand, after the combination of the glass tube 10 and the electrode socket 20, the discharge gas is inserted into the filling space 11 of the glass tube 10, in this case, in the present invention, the sealing member to prevent the discharge gas leakage 30 can be formed to ensure the reliability of the product.

Particularly, after the glass tube 10 and the electrode socket 20 are combined, the glass tube 10 and the electrode socket 20 are coupled to the sealing member 30 made of any one of vacuum ceramic paste or glass in the form of a paste. It is applied to the outer side and fixed by heat treatment, thereby improving the sealing property of the filling space 11 formed in the glass tube 10, as well as a fixing force that can be combined with the glass tube 10 and the electrode socket 20 once again. Forming action will be able to be parallel.

10: Glass tube
11: filling space 12: opening
20: electrode socket
21: horizontal member 22: vertical member 23: space part
30: sealing member
D: Dielectric P: Protective Film
40: glass tube fixing part
50: Long Life UV Lamp

Claims (6)

A glass tube 10 having a filling space 11 filled with gas inward and both sides having an opening 12;
The horizontal member 21 and the vertical member 22 are integrally formed so as to be coupled to the opening 12 of the glass tube 10, the inner side formed by the horizontal member 21 and the vertical member 22. A space electrode 23 of the metal electrode socket 20 connected to the filling space 11 of the glass tube 10;
A sealing member 30 for forming the inside of the glass tube 10 in a vacuum state between the glass tube 10 and the electrode socket 20;
The glass tube 10 is fixed when combined with the glass tube 10 to the space 23 of the space 23 where the horizontal member 21 is formed among the space 23 to which the dielectric D is applied to the inside of the electrode socket 20. Glass tube fixing portion 40 in the form of a protruding jaw, or a double tube to make;
The glass tube 10 is applied to the space portion of the electrode socket 20 so as to improve the capacitance at a low voltage while improving the light efficiency and ultraviolet output during plasma discharge of the gas, the glass tube fixing portion 40 A dielectric (D) applied only up to the position where it is formed;
A protective film (P) using any one selected from magnesium oxide (MgO) or zinc oxide (ZnO) outside the dielectric (D) formed in the space portion 23 of the electrode socket 20;
The sealing member 30 is composed of any one of a vacuum ceramic paste or a glass in the form of a paste, long life UV lamp characterized in that the glass tube and the electrode socket is bonded to the outside after the heat treatment is fixed by bonding. delete delete delete delete delete

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