KR20080002628A - Dielectric barrier discharge lamp - Google Patents

Abstract

A dielectric barrier discharge lamp is provided to improve a light emitting efficiency of the discharge lamp by generating a plurality of discharge filaments when a bias is applied between a first electrode plate and a second electrode plate by orderly arranging first transparent openings on a first electrode plate. A dielectric barrier discharge lamp includes a lamp member(110), a first electrode plate(120), a second electrode plate(130), and a discharge gas(140). The first electrode plate is arranged on the lamp and includes first transparent openings, which are apart from each other by a constant distance. The second electrode plate is arranged on the lamp and electrically insulated from the first electrode plate. The discharge gas is arranged in the lamp member between the first and second electrode plates. When a bias is applied between the first and second electrode plates, plural discharge filaments are generated in the lamp member. A position of the discharge filament is coated by the first electrode plate.

Description

Dielectric barrier discharge lamp

1 is a cross-sectional view in the axial direction of a dielectric barrier discharge lamp according to Embodiment 1 of the present invention.

2 is a cross-sectional view in the radial direction of the dielectric barrier discharge lamp according to the first embodiment of the present invention.

3 is a plan view of a first electrode plate according to Embodiment 1 of the present invention.

4 is an enlarged view illustrating main parts of the dielectric barrier discharge lamp according to the first exemplary embodiment of the present invention.

5 is a plan view of another first electrode plate according to Embodiment 1 of the present invention.

6 to 10 are plan views of different types of first electrode plates.

11 is a plan view of a first electrode plate of another embodiment according to the first embodiment of the present invention.

12A to 12C are explanatory diagrams showing the relationship between the three types of discharge filaments and the spacing when the first light transmitting opening is a regular hexagon according to the first embodiment of the present invention.

Fig. 13 is a relationship diagram of light emission intensity with respect to the light emission intensity of the dielectric barrier discharge lamp having the line width and aperture ratio of the first electrode plate when the first light transmitting opening is a regular hexagon according to the first embodiment of the present invention.

14 is a side view of a dielectric barrier discharge lamp according to Embodiment 2 of the present invention.

15 is a side view of a dielectric barrier discharge lamp according to Embodiment 3 of the present invention.

<Explanation of symbols for the main parts of the drawings>

101, 102, 103 ： Dielectric barrier discharge lamp

110, 110 ', 110 ": Lamp body

112: outside pipe 114: inside pipe

116: outer surface of the outer tube 118: outer surface of the inner tube

120, 120a-120g: First electrode plate 122: First light transmitting aperture

124: second light transmission opening 130: second electrode plate

140: discharge gas 150: first bending assistance hole

160: wire rod 162: through hole

170: Engagement 172: Projection part

180: discharge filament 190: lamp tube

192: Outside surface of lamp tube 194: Flat lamp body

194a: upper substrate 194b: lower substrate

194c: side wall 196: upper surface of the upper substrate

198: Lower surface D1 of the lower substrate: First light transmission aperture width

D2: 1st light transmission aperture gap D2 ': 1st light transmission aperture gap 2

D3: Second light transmission aperture spacing λ: Discharge filament spacing

d: line width A-Z, a-e: light transmission aperture center

| V ₁ -V ₂ |: Bias

FIELD OF THE INVENTION The present invention relates to lamps and, more particularly, to dielectric barrier discharge lamps.

US Patent No. 4,837,484 of the known art discloses a concentric cylindrical dielectric barrier discharge lamp tube, which includes an inner tube, an outer tube, an outer electrode, an inner electrode, and a discharge gas. Among them, the inner tube is disposed inside the outer tube, and the inner tube and the outer tube are arranged in a common axis. The outer electrode is located on an outer surface of the outer tube, the inner electrode is located on an inner surface of the inner tube, and the discharge gas is disposed between the inner tube and the outer tube. In the dielectric barrier discharge lamp tube disclosed in U.S. Patent No. 4,837,484, the discharge gas is excited to generate light rays by applying an alternating voltage between the inner electrode and the outer electrode. The discharge gas is an inert gas (rare gas) such as xenon (Xe), argon (Ar) or krypton (Kr), or a halogen gas such as fluorine (F ₂ ) or chlorine (Cl ₂ ). Is generally in the range of about 143-480 Torr. The dielectric barrier discharge lamp tube generates light rays of different wavelengths (for example, about 172 nm, about 222 nm, or about 308 nm) as the type of the gas to be injected varies. These wavelengths can be applied to a variety of other uses for different light rays. For example, in order to decompose an organic compound attached to an electronic part, light having a wavelength of about 172 nm is required, and in this case, the organic compound is used by using a dielectric barrier discharge lamp filled with xenon. It is possible to achieve the purpose of performing the decomposition of and cleaning the electronic component.

The external electrodes of the dielectric barrier discharge lamp tube disclosed in the above-mentioned US Pat. No. 4,837,484 can have most different designs, and the following designs are also possible. Japanese Patent Laid-Open No. 7-14554 discloses an external electrode of a dielectric barrier discharge lamp tube, which can improve spatial uniformity of light output, temporal stability and luminous efficiency. have. Specifically, the external electrode is formed of a cylindrical network weave structure using a metal wire, the external electrode of such a cylindrical network weave structure can have elasticity along the axial direction, and at the same time A mesh-shaped external electrode can closely cover the outer surface of the outer tube of the dielectric barrier discharge lamp.

An external electrode structure woven into a mesh shape of the same metal wire as that disclosed in Japanese Patent Laid-Open No. 7-14554 is disclosed in US Pat. No. 5,581,152. In US Pat. No. 5,581,152, what is particularly mentioned is that the diameter of the mesh holes is generally not large (about 1 to 2 mm) in order to have desirable stretch and uniform network structure in the mesh-shaped woven external electrode. . However, such an external electrode generally reduces the aperture ratio of the dielectric barrier discharge lamp tube (i.e., the area through which light in the first electrode can pass) as the network structure is excessively fine (for example, about 1 to 2 mm). Dividing into all areas through which light in one electrode can transmit and light cannot be transmitted). Under the following circumstances, most of the light rays generated in the dielectric barrier discharge lamp tube are interrupted by the fine network structure and cannot be effectively transmitted out of the outer tube, causing a decrease in the emission intensity of the dielectric barrier discharge lamp tube.

In addition to the problem of lowering the aperture ratio, there are other problems with the external electrodes of the cylindrical network structure, for example, the overlapping portions of metal wires and generally as the height of the electrode increases, the light injection in the dielectric barrier discharge lamp tube In addition, the luminous output efficiency of the dielectric barrier discharge lamp tube also decreases, and the luminous intensity of the lamp tube decreases. In order to increase the opening ratio of the dielectric barrier discharge lamp tube among the known electrode technologies woven in the shape of a wire, an external electrode is generally manufactured using a metal wire having a small diameter of about 0.1 mm in diameter. As a result, the resistance of the external electrode is increased, and the power consumption of the dielectric barrier discharge lamp tube is required for operation. In addition, since the overlapping portions intersecting the metal wires necessary to weave among the external electrodes of the cylindrical network structure are not metal-bonded, they have a considerably high contact resistance, and the electric power when operating the dielectric barrier discharge lamp tube. Causes an increase in consumption. Moreover, the external electrodes of the cylindrical network structure easily form needle-like or protruding points at both ends thereof, whereby the ends are likely to cause concentration or uneven phenomenon of the electric field, This results in the generation of microplasma. This makes it impossible to generate stable discharge filaments at equal or equal intervals, and also affects the light emission uniformity of the dielectric barrier lamp tube.

Japanese Laid-Open Patent Publication No. 2003-168394 also discloses an external electrode of a dielectric barrier discharge lamp tube, the characteristic of which is wound around the outer surface of the dielectric barrier discharge lamp tube spirally by one metal wire. The advantage of this method is that the aperture ratio is larger than the external electrode of the cylindrical woven structure, the number of lattice points at which the metal lines intersect is relatively small, and the external electrode can be completely adhered by the outer surface of the outer tube. The discharge filament phenomenon may be prevented from occurring between the outer electrode and the outer surface of the outer tube, the power consumption may be reduced, and the life of the outer electrode may be increased. However, as the outer tube of the dielectric barrier discharge lamp tube is generally a quartz tube, the wound spiral metal wire is not easy to fix because the surface of such a quartz tube is quite slippery, and thus the spiral spacing is not uniform. When discharging, it causes unstable electric field and flow of discharge filament. Accordingly, the uniformity of light emission of the dielectric barrier discharge lamp tube is undesirable.

Further, the concentric cylindrical dielectric barrier discharge lamp tube according to the prior art can use a metal plate having no light transmitting aperture as an external electrode. These prior art plate-shaped outer electrodes generally have a semicircular arc shape and are disposed outside of the outer tube while covering most of the outer surface area of the outer tube. That is, the outer surface of the outer tube is divided into a light output zone and a non-light output zone, and a metal plate without such a light transmission opening is disposed in the non-light output zone, and the light output surface does not cover all of the external electrodes. . Since the electrode which covers the area of a part of this outer side pipe | tube has little discharge space compared with the electrode which completely covered the said outer side tube, the light emission intensity of a discharge tube becomes comparatively weak. In addition, the ultraviolet light rays generated by the discharge in the non-light output area can reach the outer field only when propagated to the light output area. As such, the distance through which the ultraviolet rays propagate increases and is always absorbed and attenuated by a spatial material in the process of propagating the ultraviolet rays, so that the external electrode without the light transmitting aperture of the prior art also has low light output efficiency. The emission intensity is low.

In addition to the production method of the external electrode (external electrode of a cylindrical network structure, a spiral type external electrode of the wound type or a plate-shaped external electrode), the production method of the external electrode may be printed, electroplating, deposition plating or sputtering A method can be employed, and Japanese Patent Laid-Open No. 2004-127781 and Japanese Laid-Open Patent Publication No. 2002-100324 have already been disclosed.

However, among the above-described methods, the deposition plating and sputtering methods are complicated to operate and expensive, and the external electrode formed by these methods is a metal film, and the thickness of the external electrode is generally only a few micrometers (µm). The resistance value of is excessively high, the resistance in the lamp tube during discharge increases power consumption, and affects the luminous efficiency of the dielectric barrier discharge lamp tube. In addition, since the difference in thermal expansion coefficients of the metal film and the outer tube is large (for example, the thermal expansion coefficients of aluminum and quartz are about 20 ppm / K and 5 ppm / K, respectively), the metal film is easily peeled off the surface of the outer tube. In addition, when carrying out the manufacture of a metal film employing a printing method, an organic or inorganic adhesive is generally added. However, these adhesives deteriorate very easily due to minute cracks after passing through the generated light irradiation of the dielectric barrier discharge lamp tube. As a result, the lifetime of the coating type external electrode is shortened.

Accordingly, there is a need for a dielectric barrier discharge lamp tube having good luminous efficiency, uniformity, stability, and service life.

In view of the above-mentioned problems of the prior art, one object of the present invention is to provide a dielectric barrier discharge lamp tube having high opening ratio and good light uniformity.

Another object of the present invention is to provide an electrode plate capable of improving the aperture ratio and uniformity of light emission of a dielectric barrier discharge lamp.

In order to achieve the above object or other object of the present invention, the dielectric barrier discharge lamp according to the embodiments of the present invention includes a lamp body, a first electrode plate, a second electrode plate and a discharge gas. While the first electrode plate is disposed on the lamp body, the first electrode plate has a plurality of first light transmitting openings arranged at regular and equidistant intervals. The second electrode plate is disposed on the lamp body, and the second electrode plate is electrically insulated from the first electrode plate. The discharge gas is disposed in the lamp body and located between the first electrode plate and the second electrode plate. When a bias is applied between the first electrode plate and the second electrode plate, a plurality of equally spaced discharge filaments are generated in the lamp body, and at the same time, a position where all the discharge filaments exist is located in the first electrode plate. It is covered by an electrode plate.

In order to achieve the above object or other object of the present invention, the electrode plate according to the embodiments of the present invention has a plurality of first light transmitting openings arranged at regular intervals.

In an embodiment of the present invention, when the spacing of the discharge filament is λ, and the arrangement spacing of the first light transmitting openings is D2, D2 = λ / n, and n is a positive integer.

In an embodiment of the present invention, the lamp body includes an outer tube and an inner tube. The first electrode plate is disposed on an outer surface of the outer tube, and the inner tube is disposed in the outer tube and connected to the outer tube at the same time. The discharge gas is disposed between the inner tube and the outer tube, and the second electrode plate is disposed on an inner surface of the inner tube.

In the embodiment of the present invention, the axis of the outer tube and the axis of the inner tube overlap each other.

In the embodiment of the present invention, the interval between the shaft center of the outer tube and the shaft center of the inner tube has one offset amount.

In an embodiment of the present invention, the first electrode plate has a plurality of first bend aid holes, and the first bend aid holes are distributed around the first electrode plate and at the same time, Wrap the outsourcing.

In an embodiment of the present invention, the dielectric barrier discharge lamp further includes a wire rod, wherein the first electrode plate has a plurality of through holes penetrating through the wire rod, and the wire rod is disposed outside the first electrode plate. Make sure it is fully adhered to the outer surface of the tube.

In an embodiment of the present invention, the wire rod is a single core wire or a multi-core wire rod.

In an embodiment of the invention, the wire is conductive or non-conductive.

In an embodiment of the present invention, the first electrode plate has a plurality of engagement holes and a plurality of protrusions, the plurality of engagement holes are located on one side of the first electrode plate, and the plurality of protrusions are the first At the same time as protruding from the other side of the electrode plate, the protrusions are engaged with the engagement holes to completely adhere the first electrode plate on the outer surface of the outer tube.

In an embodiment of the present invention, the first electrode plate has a plurality of second light transmitting openings arranged at regular intervals and at the same time the second light transmitting openings are at least one side or both sides of the first light transmitting opening. Distributed in.

In an embodiment of the present invention, the outer periphery of the first electrode plate is wound by a metal wire and completely adhered to the outer surface of the outer tube.

In an embodiment of the present invention, one side and the other side of the first electrode plate is welded and completely adhered to the outer surface of the outer tube.

In an embodiment of the present invention, the first light transmission openings and the second light transmission openings are similar to each other.

In an embodiment of the present invention, when the arrangement interval of the first light transmission openings is D2 and the arrangement interval of the second light transmission openings is D3, D3 = D2 / n, and n is a positive integer.

In the embodiment of the present invention, the second electrode plate has a plurality of third light transmitting openings arranged at regular intervals and at the same time the position where all the discharge filaments are present is coated by the second electrode plate.

In an embodiment of the present invention, the lamp body is a lamp tube, the first electrode plate is disposed on an outer surface of the lamp body, and the second electrode plate is disposed inside the lamp body.

In an embodiment of the present invention, the first electrode plate has a plurality of first bend aid holes, which are distributed around the first electrode plate and at the same time as the first light transmission openings. Wrap the outsourcing.

In an embodiment of the present invention, the first bending auxiliary holes are distributed around the first electrode plate and at the same time surround both sides in the axial direction of the first light transmitting openings.

In the embodiment of the present invention, the first bending auxiliary holes are distributed around the first electrode plate and simultaneously surround both sides of the first light transmitting openings in the radial direction.

In an embodiment of the present invention, the dielectric barrier discharge lamp further comprises a wire rod, wherein the first electrode plate has a plurality of through holes penetrating through the wire rod, and the wire rod connects the first electrode plate to the lamp. It will be completely adhered to the outer surface of the tube.

In an embodiment of the present invention, the wire rod is a single core wire or a multi-core wire rod.

In an embodiment of the invention, the wire is conductive or non-conductive.

In an embodiment of the present invention, the first electrode plate has a plurality of engagement holes and a plurality of protrusions, the plurality of engagement holes are located on one side of the first electrode plate, and the plurality of protrusions are the first The protrusions are engaged with the engagement holes at the same time as protruding to the other side of the electrode plate, and the first electrode plate is completely in contact with the outer surface of the lamp tube.

In an embodiment of the present invention, one side and the other side of the first electrode plate is welded and completely adhered to the outer surface of the lamp tube.

In an embodiment of the present invention, the first electrode plate has a first light transmitting opening and a second light transmitting opening arranged at equal intervals along the axial direction of the lamp body.

In the embodiment of the present invention, the lamp body is a flat lamp body.

In the embodiment of the present invention, the flat lamp body includes an upper substrate, a lower substrate and a plurality of sidewalls. The lower substrate is positioned below the upper substrate, and the sidewalls are connected between the upper substrate and the lower substrate. The first electrode plate is disposed on an upper surface of the upper substrate, and the second electrode plate is disposed on a lower surface of the lower substrate.

In an embodiment of the invention, the first light transmissive opening is a polygonal opening.

In an embodiment of the present invention, the first light transmitting opening of the first substrate is formed by etching or pressing.

In an embodiment of the invention, the first light transmissive opening is an equilateral triangle opening, a square opening, a regular hexagon opening, a rhombic opening or a trapezoidal opening.

In an embodiment of the present invention, the material of the first electrode plate and the second electrode plate is copper, aluminum, nickel, chromium, gold, molybdenum, silver, platinum, iron, titanium, tungsten, cobalt or an alloy of the metal. It includes.

In an embodiment of the present invention, the discharge gas is mixed with the mercury, helium, neon, xenon, argon, krypton, nitrogen, hydrogen selenide, deuterium, fluorine or chlorine, bromine, iodine or two or more of these gases. Mixed gas.

In order to achieve the above object or other object of the present invention, the electrode plate according to the embodiments of the present invention has a first light transmitting opening arranged at regular intervals.

In an embodiment of the present invention, the electrode plate has a plurality of first bend aid holes, which are distributed around the electrode plate and at the same time surround the outer circumference of the first light transmitting opening. .

In an embodiment of the present invention, the electrode plate has a plurality of engagement holes and a plurality of protrusions, the plurality of engagement holes are located on one side of the electrode plate, the plurality of protrusions protrude from the other side of the electrode plate When the electrode plate is bent, the protrusions are engaged in the engagement holes.

In an embodiment of the invention, the electrode plate has a plurality of second light transmitting openings arranged at regular intervals and at the same time the second light transmitting openings are distributed on one side or both sides of the first light transmitting opening. .

In an embodiment of the present invention, the first light transmitting opening and the second light transmitting opening are similar to each other.

In an embodiment of the present invention, when the arrangement interval of the first light transmission openings is D2 and the arrangement interval of the second light transmission openings is D3, D3 = D2 / n, and n is a positive integer.

In an embodiment of the invention, the first and second light transmissive openings are polymorphic.

In an embodiment of the present invention, the first light transmitting openings and the second light transmitting openings of the electrode plate are formed by an etching process or a press working.

According to embodiments of the present invention, the first light transmissive openings on the first electrode plate are regularly arranged at equal intervals, whereby a bias is applied between the first electrode plate and the second electrode plate. In this case, a plurality of discharge filaments are generated which are arranged at equal intervals λ in the lamp body. When the relationship between the interval D2 and the equal interval λ is D2 = λ / n (n is a positive integer), the aperture ratio of the dielectric barrier discharge lamp tube according to the present invention is increased and light emission is made uniform.

According to the present invention, since the first light transmitting openings on the first electrode plate are regularly arranged with an equidistant, when the bias is applied between the first electrode plate and the second electrode plate, the lamp A plurality of discharge filaments are generated which are arranged at equal intervals λ in the sieve. When the relationship between the interval D2 of the first light transmitting openings and the equal interval λ is D2 = λ / n (n is a positive integer), the dielectric barrier discharge lamp according to the present invention has a high aperture ratio, light emission uniformity, and the like. Has good properties.

Hereinafter, a dielectric barrier discharge lamp according to embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited to the following embodiments.

Example  One

1 and 2 are cross-sectional views of different directions (axial direction and radial direction) of the dielectric barrier discharge lamp according to the first embodiment of the present invention, respectively.

1 and 2, the dielectric barrier discharge lamp 101 according to the first embodiment of the present invention includes a lamp body 110, a first electrode body 120, a second electrode body 130, and a discharge gas. 140. The lamp body 110 is composed of, for example, an inner tube 112 and an inner tube 114, and the first electrode plate 120 is disposed on the outer surface 116 of the outer tube 112. The two electrode plates 130 are disposed on the inner surface 118 of the inner tube 114. It should be noted that the first electrode plate 120 applied to the present invention has a plurality of first light transmitting openings 122 arranged at regular intervals. As shown in FIG. 1, the inner tube 114 and the outer tube 112 are connected to each other and a space for injecting the discharge gas 140 is formed between the inner tube 114 and the outer tube 112. . In other words, when the discharge gas 140 is injected into the lamp body 110, the discharge gas 140 is positioned between the first electrode plate 120 and the second electrode plate 130. In addition, the second electrode plate 130 and the first electrode plate 120 are electrically insulated from each other, and a bias (| V ₁ -V ₂ |) is applied to the first electrode plate 120 and the second electrode plate 130. When applied therebetween, the discharge gas 140 in the lamp body 110 generates a gas discharge phenomenon under the influence of an applied bias (| V ₁ -V ₂ |) and is arranged at equal intervals in the lamp body 110. Generates a plurality of discharge filaments. As the first electrode plate 120 according to the present invention has a plurality of first light transmitting openings 122 arranged regularly and at equal intervals, the position where all the discharge filaments exist is located in the first electrode plate 120. Is covered by. The detailed control mechanism of the position where the discharge filaments are generated and the detailed structure of the first electrode plate 120 will be described later.

The center of the outer tube 112 and the center of the inner tube 114 of the lamp body 110 may overlap each other. Of course, the present invention is not limited to the axis of the outer tube 112 should overlap with the axis of the inner tube (114). That is, an appropriate amount of deviation may be provided between the shaft center of the outer tube 112 and the shaft center of the inner tube 114.

3 is a plan view of a first electrode plate according to Embodiment 1 of the present invention.

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와 같은 연신 방향)으로 배열됨과 동시에 벌집 형상으로 배열된다. 도 3에 나타낸 바와 같이, 본 실시예에 있어서, 각 제1 광 투과 개구(122)의 어느 두 개의 서로 평행한 대변들이 이루는 거리(D1)를 제1 광 투과 개구 폭으로 정의한다. 또한, 본 발명에 있어서, 각 제1 광 투과 개구(122)의 광 투과 개구(A)와 가장 근접하는 각 제1 광 투과 개 구(122)(본 실시예에서는 6개)의 광 투과 개구 중심들(B, C, D, E, F 및 G)이 이루는 동일한 거리(D2)를 제1 광 투과 개구 간격으로 정의한다. 도 3에 나타낸 제1 전극판(120) 중 어느 두 개의 서로 인접하는 제1 광 투과 개구(122)들 사이의 제1 전극판(120)의 선폭을 d로 하고, 거리를 D1로 할 경우, 상기 제1 광 투과 개구 간격(D2), 선폭(d) 및 거리(D1)의 삼자 사이의 관계는 D2=D1+d이 된다.As shown in FIG. 3, the first light transmitting openings 122 according to the present invention are arranged in a matrix structure at equal intervals along a specific direction, and the first light transmitting opening 122 having a regular hexagon is taken as an example. Vertical direction of

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,

In the drawing direction) and at the same time arranged in a honeycomb shape. As shown in FIG. 3, in this embodiment, the distance D1 formed by any two parallel sides of each first light transmitting opening 122 is defined as the first light transmitting opening width. In addition, in the present invention, the light transmitting aperture centers of the first light transmitting openings 122 (six in this embodiment) closest to the light transmitting openings A of the respective first light transmitting openings 122. The same distance D2 that the fields B, C, D, E, F and G make is defined as the first light transmission aperture spacing. When the line width of the first electrode plate 120 between the two first light transmitting openings 122 which are adjacent to each other among the first electrode plate 120 shown in FIG. 3 is d, and the distance is D1, The relationship between the first light transmitting aperture spacing D2, the line width d, and the three parties of the distance D1 is D2 = D1 + d.

4 is an enlarged view illustrating main parts of the dielectric barrier discharge lamp according to the first exemplary embodiment of the present invention.

Referring to FIG. 4, the lamp tube 110 according to the present embodiment has a circumferential shape, and as the outer surface 116 of the outer tube 112 has an arc shape, the first electrode plate 120 has a roll shape. So that it can be completely adhered to the outer surface 116 of the outer tube (112). In order to be able to fully adhere the first electrode plate 120 on the outer surface 116 of the outer tube 112, in accordance with the present invention, a plurality of first bending aids on the first electrode plate 120. The holes 150 are formed to allow the first electrode plate 120 to be bent smoothly and to have proper elasticity. That is, the bending elasticity of the first electrode plate 120 may be appropriately adjusted by changing the size of the first bending auxiliary holes 150 or the number of distribution thereof. In the present embodiment, the first bending auxiliary holes 150 are distributed on four side surfaces of the first electrode plate 120. That is, the first light transmitting openings 122 (see FIG. 3) are distributed in the middle region of the first electrode plate 120, and the first bending auxiliary holes 150 are disposed around the first light transmitting openings 122. Distributed. It should be noted that the first electrode plate, except that the first bending auxiliary holes 150 are easily wound around the first electrode plate 120 to completely adhere to the outer surface 116 of the outer tube 112. Deformation can be avoided after the first light transmitting apertures 122 of 120 are rolled. Based on this, the first bending auxiliary holes 150 may be effectively blocked from generating an excessive change in the distance D2 of the first light transmitting openings 122.

In order to allow the first electrode plate 120 to be completely adhered to the outer surface 116 of the outer tube 112, in this embodiment, the first electrode plate is formed using a combination of the wire rod 160 and the through hole 162. After the 120 is bent, both sides are sealed to maintain the roll state of the first electrode plate 120. Specifically, in the present embodiment, the first electrode plate 120 may be formed to have a plurality of through holes 162 penetrating the wire rod 160 on both sides corresponding to the axial direction of the outer tube 112. have. After the wire rod 160 penetrates the through holes 162, the wire rod 160 provides an appropriate tension, and at the same time, the first electrode plate 120 is connected to the outer tube by the elasticity of the first electrode plate 120. It is completely adhered to the outer surface 116 of 112. In this embodiment, the wire rod 160 may be, for example, a single core wire or a multi-core wire rod, and the wire rod 160 may be conductive or non-conductive.

In addition, according to the present embodiment, the outer circumference of the first electrode plate 120 may be wound by the metal wire using a metal wire to completely adhere to the outer surface 116 of the outer tube 112.

In addition to the method of winding the wire 160 with the metal wire, according to the present embodiment, one side of the first electrode plate 120 is connected to the other side by employing a welding (for example, spot welding) method, and the first The electrode plate 120 may be completely in contact with the outer surface 116 of the outer tube 112. In other words, according to the welding method, the area of the first electrode plate 120 used when the one side of the first electrode plate 120 is connected to the other side needs to be slightly larger (compared to FIG. 4), After the first electrode plate 120 is disposed on the outer surface 116 of the outer tube 112, one side thereof may be coated on the other side, and such overlapping regions may be used for welding.

In addition to using the wire rod 160 and the above-described welding method, the method of fixing the first electrode plate 120 on the outer surface 116 of the outer tube 112 may have other shapes, and FIG. 5. It will be described in detail with reference to.

5 is a plan view of a first electrode plate of another embodiment according to the first embodiment of the present invention.

Referring to FIG. 5, the first electrode plate 120a has a plurality of engagement holes 170 and a plurality of protrusions 172, and these engagement holes 170 are positioned at one side of the first electrode plate 120a. The protrusions 172 protrude from the other side of the first electrode plate 120a. When the first electrode plate 120a is disposed on the outer surface 116 (see FIG. 4) of the outer tube 112, the protrusions 172 are engaged with the engagement holes 170, so that the first electrode plate ( 120 may be completely in contact with the outer surface 116 (see FIG. 4) of the outer tube 112. The shape of the engagement holes 170 is, for example, a rectangular, L-shaped or T-shaped hole, and the shape of the protrusions 172 is combined with the shape of the engagement holes 170 to form the first electrode plate 120a. Protrude to the other side. In other words, the shape of the protrusions 172 may be smoothly engaged with the engagement holes 170, but the present invention is not limited thereto. For example, when the engagement holes 170 are T-shaped, the shape to be combined with the protrusions 172 can be T-shaped (that is, the width of the front end is wider than the width of the rear end).

6 to 10 are plan views of first electrodes having different shapes. 6 to 10, in addition to the regular hexagonal opening illustrated in FIG. 3, the shapes of the first light transmitting openings 122 applied to the present exemplary embodiment may be other types of polygonal openings, for example, an equilateral triangle. (See FIG. 6), squares (see FIG. 7), rhombuses (see FIG. 8) and trapezoids (see FIGS. 9 and 10) and the like are regularly arranged openings. Hereinafter, the arrangement of the first light transmitting openings 122 having different shapes will be described in detail.

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)으로 정의한다.Referring to FIG. 6, taking the first triangular first light transmissive opening 122 as an example, in the present invention, each first first adjacent nearest to the center of the light transmissive opening H of each of the first light transmissive openings 122 is described. The distance D2 between the centers I, J, and K of the light transmissive openings 122 (three in this embodiment) is the first light transmissive opening interval (i.e.,

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Is defined as).

및

과 같은 연신 방향). 도 7에 나타낸 바와 같이, 본 발명에 따르면, 각 제1 광 투과 개구(122)의 어느 두 개의 서로 평행한 대변들이 이루는 거리(D1)를 제1 광 투과 개구 폭으로 정의한다. 또한, 본 발명에 있어서, 각 제1 광 투과 개구(122)의 광 투과 개구 중심(L) 및 가장 인접하는 각(본 실시예에서는 4개) 제1 광 투과 개구(122)들의 광 투과 개구 중심들(M, N, O 및 P)가 이루는 거리(D2)를 제1 광 투과 개구 간격으로 정의한다. 도 7에 나타낸 제1 전극판(120c) 가운데 어느 두 개의 인접하는 제2 광 투과 개 구(122)들 사이의 제1 전극판(120c)의 선폭이 d일 경우, 제1 광 투과 개구 폭(D1), 제1 광 투과 개구 간격(D2) 및 선폭(d)의 삼자 사이의 관계는 D2=D1+d가 된다.Referring to FIG. 7, for example, a square first light transmitting opening 122 is arranged at equal intervals in a vertical direction with any one side thereof (

And

Drawing direction). As shown in FIG. 7, according to the present invention, the distance D1 formed by any two parallel sides of each first light transmitting opening 122 is defined as the first light transmitting opening width. Further, in the present invention, the light transmitting opening center L of each first light transmitting opening 122 and the light transmitting opening center of the adjacent angles (four in this embodiment) of the first light transmitting openings 122 are shown. The distance D2 formed by the fields M, N, O, and P is defined as the first light transmission aperture spacing. When the line width of the first electrode plate 120c between two adjacent second light transmission openings 122 among the first electrode plate 120c shown in FIG. 7 is d, the first light transmission aperture width ( The relationship between D1), the first light transmitting aperture gap D2, and the three characters of the line width d becomes D2 = D1 + d.

및

과 같은 연신 방향). 도 8에 나타낸 바와 같이, 본 발명에 따르면, 각 제1 광 투과 개구(122)의 어느 두 개의 서로 평행한 대변들을 이루는 거리(D1)를 제1 광 투과 개구 폭으로 정의한다. 또한, 본 발명에 잇어서, 각 제1 광 투과 개구(122)의 광 투과 개구 중심(Q) 및 가장 인접하는 각 제1 광 투과 개구(122)들(본 실시예에서는 4개)의 광 투과 개구 중심들(R, S, T 및 U)가 이루는 거리(D2)를 제1 광 투과 개구 간격으로 정의한다. 도 8에 나타낸 제1 전극판(120d)에 있어서, 어느 두 개의 인접하는 제1 광 투과 개구(122)들 사이의 제1 전극판(120d)의 선폭이 d일 경우, 거리(D1), 제1 광 투과 개구 간격(D2) 및 선폭(d)의 삼자 간의 관계는 D2=D1+d이 된다.Referring to FIG. 8, for example, the rhombic first light transmitting opening 122 is arranged in a parallel direction along either side thereof (

And

Drawing direction). As shown in FIG. 8, according to the present invention, the distance D1 constituting any two parallel sides of each first light transmission opening 122 is defined as the first light transmission opening width. Further, according to the present invention, the light transmitting opening center Q of each first light transmitting opening 122 and the light transmitting opening of each of the adjacent first light transmitting openings 122 (four in this embodiment) are provided. The distance D2 between the centers R, S, T, and U is defined as the first light transmission aperture spacing. In the first electrode plate 120d illustrated in FIG. 8, when the line width of the first electrode plate 120d between any two adjacent first light transmission openings 122 is d, the distance D1, The relationship between the three light-transmitting aperture intervals D2 and the three widths d is D2 = D1 + d.

의 연신 방향) 또는 좌우 양측(예를 들면, 수평 방향, 즉

의 연신 방향)을 따라 등간격으로 배열된다. 보다 상세하게 설명하면, 수직 방향(즉

의 연신 방향)에서, 개구 중심(V)의 제1 광 투과 개구(122)의 형상 및 상하 양측의 제1 광 투과 개구(122)(즉, 개구 중심이 X 및 Z인 제1 광 투과 개구(122))의 형상이 반대가 되고, 개구 중심(V) 및 상하 양측의 제1 광 투과 개구(122)의 개구 중심들(X 및 Z)이 이루는 거리(D2)를 간 격(즉,

및

)로 정의한다. 수평 방향에서(즉,

의 연신 방향), 개구 중심(V)의 제1 광 투과 개구(122)의 형상 및 좌우 양측의 제1 광 투과 개구(122)(즉, 개구 중심이 W 및 Y인 제1 광 투과 개구(122)의 형상이 반대가 되고, 개구 중심(V) 및 좌우 양측의 제1 광 투과 개구(122)의 개구 중심(W 및 Y)이 이루는 거리(D2)를 간격(즉,

및

)으로 정의한다.Referring to FIG. 9, taking the trapezoidal first light transmitting opening 122 as an example, the upper and lower sides of the opening center V of the first light transmitting opening 122 (the vertical direction, that is,

Drawing direction) or both the left and right sides (for example, in the horizontal direction, ie

Along the direction of drawing). More specifically, the vertical direction (i.e.

In the stretching direction of the shape, the shape of the first light transmitting opening 122 of the opening center V and the first light transmitting opening 122 on both the upper and lower sides (that is, the first light transmitting opening whose opening centers are X and Z) 122) is reversed, and the distance D2 between the opening centers V and the opening centers X and Z of the first light transmitting openings 122 on both the upper and lower sides is spaced (that is,

And

To be defined). In the horizontal direction (i.e.

Drawing direction), the shape of the first light transmitting opening 122 of the opening center V and the first light transmitting opening 122 on both the right and left sides (that is, the first light transmitting opening 122 having the opening centers W and Y). ) Are reversed, and spaced apart (that is, the distance D2 between the opening center V and the opening centers W and Y of the first light transmitting openings 122 on both the right and left sides)

And

Is defined as).

및

과 같은 연신 방향). 도 10에 있어서, 그 중 사다리꼴의 제1 광 투과 개구(122)들은 수직 방향을 따라 D2의 등간격으로 배열되며, 사다리꼴의 제1 광 투과 개구(122)들은 수평 방향을 따라 간격(D2')을 가지고 등간격으로 배열된다. 또한, 상세하게 설명하면, 수직 방향(즉,

의 연신 방향)에 있어서, 광 투과 개구 중심(a)의 제1 광 투과 개구(122)의 형상 및 상하 양측의 제1 광 투과 개구(122)(즉, 개구 중심이 b 및 d 인 제1 광 투과 개구(122))의 형상이 반대가 되고, 개구 중심(a)과 상하 양측의 제1 광 투과 개구(122)의 개구 중심(b 및 d)들이 이루는 거리(D2)를 제1 간격(즉,

및

)으로 정의하고, 수평 방향에 있어서(즉,

의 연신 방향), 광 투과 개구 중심(a)의 제1 광 투과 개구(122)의 형상 및 좌우 양측의 제1 광 투과 개구(122)(즉, 개구 중심을 c 및 e로 하는 제1 광 투과 개구(122))의 형상이 반대가 되고, 광 투과 개구 중심(a) 및 좌우 양측의 제1 광 투과 개구(122)의 개구 중심(c 및 e)들이 이루는 거리(D2')를 제2 간격(즉,

및

)으로 정의한다.Referring to FIG. 10, in this embodiment, it is similar to the trapezoidal first light transmitting opening 122 of FIG. 9, and the trapezoidal first light transmitting opening 122 is parallel along the extending directions of the upper and lower sides thereof. And in the vertical direction (

And

Drawing direction). In FIG. 10, the trapezoidal first light transmitting openings 122 are arranged at equal intervals of D2 along the vertical direction, and the trapezoidal first light transmitting openings 122 are spaced D2 'along the horizontal direction. Are arranged at equal intervals. In addition, in detail, the vertical direction (that is,

In the drawing direction of the first light transmitting opening 122 of the light transmitting opening center a and the first light transmitting openings 122 (that is, the opening centers b and d on the upper and lower sides). The shape of the transmission opening 122 is reversed, and the distance D2 between the opening center a and the opening centers b and d of the first light transmitting openings 122 on both the upper and lower sides is set at a first interval (ie, ,

And

) And in the horizontal direction (i.e.

Drawing direction), the shape of the first light transmitting opening 122 of the light transmitting opening center a, and the first light transmitting opening 122 on both the right and left sides (that is, the first light transmitting having the opening centers as c and e). The shape of the opening 122 is reversed, and the distance D2 ′ between the light transmitting opening center a and the opening centers c and e of the first light transmitting openings 122 on both the right and left sides is formed at a second interval. (In other words,

And

Is defined as).

3 and 6 to 10, the positions where the stable discharge filament 180 exists among them are shown, but only a small part of the positions of the stable discharge filament 180 are shown in these figures, and these discharge filaments 180 are shown. A small portion of the position of) is arranged to extend in the circumferential direction by the same distribution method. That is, it may be distributed to fill the entire first electrode plate 120. It should be noted that the position of the discharge filament 180 in which all of these are stable appears in the position where the line width d on the drawing or the line width d intersects. This is because the distance between the line width d or the position where it intersects and the second electrode plate is short compared to the distance of the first light transmitting opening 122 (for example, the light transmitting opening in the second electrode plate). When there is no). In this manner, the electric field strength in the inside of these line widths d or in the line width d or in the vicinity of the positions where the line widths d intersect is high compared to the electric field strength in the vicinity of the first light transmitting opening 122. Thus, when the discharge filaments 180 appear on their positions and are arranged at equal intervals, the discharge filaments 180 are stable and not shifted. That is, in the present invention, as the first light transmitting openings 122 are arranged at equal intervals, the discharge filaments 180 generated when the lamp 101 is discharging are arranged at equal intervals and at the same time, the discharge filaments As all of the 180 layers are covered by the first electrode plate 120, the discharge filaments 180 may be stabilized and not shifted.

As shown in FIGS. 3 to 10, as the first light transmitting openings 122 are arranged at equal intervals along a specific direction, the first electrode plate 120, 120a to 120f of these first light transmitting openings 122. ) Also has sufficient regularity, and in this case, the dielectric barrier discharge lamp is generated only by controlling input of parameters such as bias of the dielectric barrier discharge lamp, frequency, and total gas pressure in the dielectric barrier discharge lamp. The discharge filament spacing λ can be adjusted, and the discharge filament spacing λ can be matched to the design of the first electrode plates 120, 120a to 120e. As such, as the first light transmitting openings 122 are regularly arranged, when the discharge lamp 101 discharges, the electric field strength between the first electrode plate 120 and the second electrode plate 130 is also regularly. It is distributed and can generate stable non-shifting filaments in the dielectric barrier discharge lamp 101. In addition, the discharge filament which the dielectric barrier discharge lamp 101 generate | occur | produces is fully covered by the 1st electrode plate 120,120a-120e disclosed by this invention, and this point is mentioned later again.

11 is a plan view of a first electrode plate of another embodiment according to the first embodiment of the present invention.

Referring to FIG. 11, the first electrode plate 120a according to the present exemplary embodiment is similar to the first electrode plate 120 illustrated in FIG. 3, but two other points are different from the first light transmitting openings 122. In addition, the first electrode plate 120g according to the present embodiment further includes a plurality of second light transmitting openings 124, and the second light transmitting openings 124 are formed in the outer tube 112 of the first electrode plate 120. Or on both sides of the first light transmitting openings 122 in the radial direction of the radial direction, or around both sides of the first light transmitting openings 122 in the axial direction of the outer tube 112 and around the first light transmitting openings 122. It is a point distributed in. As shown in FIG. 10, the first light transmitting openings 122 and the second light transmitting openings 124 are similar figures to each other, the interval at which the first light transmitting openings 122 are arranged is D2, When the interval at which the second light transmitting openings 124 are arranged is D3, D3 = D2 / n, and n is a positive integer. Since the array spacing D2 of the first light transmitting openings 122 is an integer multiple of the array spacing D3 of the second light transmitting openings 124, the discharge filament spacing λ generated by the dielectric barrier discharge lamp is adjusted. Just by doing so, it can be matched with the arrangement | interval spacing D2 of the 1st light transmission openings 122 in the 1st electrode plate 120a. More specifically, when the discharge filament spacing λ matches the array spacing D2 of the first light transmitting openings 122, the discharge filament spacing λ naturally matches the arrangement of the second light transmitting openings 124. Match with the interval D3.

The material of the first electrode plate 120 disclosed in this embodiment is, for example, copper (Cu), aluminum (Al), nickel (Ni), chromium (Cr), gold (Au), molybdenum (Mo), Silver (Ag), platinum (Pt), iron (Fe), titanium (Ti), tungsten (W), cobalt (Co) or the like, or an alloy of the above metal or other conductive material, and the thickness thereof is, for example, For example, it is in the range of about 0.05 to 0.15 mm. In addition, the method of forming the first light transmitting openings 122 on the first electrode plate 120 includes a press method or an etching method.

It should be noted that the ends of known external electrodes (e.g., cylindrical network structures, spirally wound metal wires, etc.) are always made by the disadvantages or folds of the woven metal wires. Because of the occurrence of the shape projecting point, the electric field concentration phenomenon occurs at the end of the discharge tube, and the electric field concentration at this end causes the discharge at both ends of the discharge tube to be more severe than the center of the lamp tube, and the discharge filaments at both ends of the discharge tube are constantly shifted. Therefore, the light emission intensity across the lamp tube has a phenomenon of nonuniformity. In contrast, according to the present invention, the first electrode plate 120 disclosed in the above-described embodiment not only does not generate needle-shaped protrusions (see FIGS. 3 and 5 to 10) but also the first electrode plate according to the present invention. Axial ends of 120 have flat ends). In addition, since the first electrode plate 120 according to the present invention is non-permanently bonded to the lamp body 110, the first electrode plate 120 is generated due to a different thermal expansion coefficient between the first electrode plate 120 and the lamp body 110. There is no peeling phenomenon and there is no problem of short life like a conventional coating electrode (produced by printing, electroplating, vapor deposition or sputtering).

In addition, the first electrode plate 120 according to the present invention has a low electrical resistance compared to the network electrode or the coating type electrode woven with a conventional metal wire, it is possible to prevent unnecessary power consumption, dielectric barrier discharge lamp ( 101) has the advantage of improving the luminous efficiency. Detailed description thereof is as follows.

There are two causes of low resistance of the first electrode plate 120 according to the present invention. One is that it is formed by the processing of the entire metal plate, and the mesh-shaped electrode is generally formed by weaving a single wire, and the contact resistance is high because the point at which the mesh interweaves is other than the diameter of the metal wire being relatively thin. In addition, since the thickness of the electrode of the coating type is generally only a few μm, the electrical resistance is also quite high. On the other hand, holes are not formed at both sides in the radial direction of the outer tube 112 of the first electrode plate 120 according to the present embodiment, or small holes are formed in comparison with the first light transmitting opening 122 in the intermediate region. At the same time as the formation (for example, the first bend auxiliary hole 150), the opening ratio is lower than that of the central region, and the electric resistance values on both sides of the first electrode plate 120 are lowered. As described above, the current input to the dielectric barrier discharge lamp 101 is rapidly sent to the middle region of the first electrode plate 120 by the assistance of both sides of the first electrode plate 120, so that the current is reliably dispersed and the first electrode plate is provided. The effect of reducing the electrical resistance from both sides of the 120 to the intermediate region and improving the luminous efficiency of the discharge lamp 101 can be achieved.

As described above, the design of the first electrode plate 120 is described, but the present invention does not limit the form of the second electrode plate 130. In the embodiments of the present invention, the second electrode plate 130 to be applied may have a plurality of third light transmitting openings (not shown) arranged regularly, and the arrangement interval of the third light transmitting openings may be It is determined by the location where the discharge filament is present. In principle, since the method of determining the arrangement interval of the third light transmitting openings is the same as the method of determining the arrangement interval of the first light transmitting openings 122, the description thereof will be omitted.

The dielectric barrier discharge lamp 101 according to the present invention has a feature that, when the lamp body 110 discharges, a position where all the discharge filaments exist is covered by the first electrode plate 120, and at the same time, such a feature Increasing the aperture ratio improves the light emission output efficiency, stabilizes the discharge filaments, and improves the light emission intensity of the lamp body 100.

In addition, an example in which the first light transmitting openings 122 according to the present embodiment are regular hexagons will be described. 12A to 12C are explanatory diagrams showing the relationship between the three types of discharge filaments and the intervals according to the first embodiment of the present invention.

12A to 12C, the relation between the interval λ of the discharge filament 180 and the interval D2 of the first light transmissive opening 122 is defined, for example, for the first hexagonal light transmissive opening 122. Is D2 = λ / n, and n is a positive integer. When n = 1, the spacing λ of the discharge filament 180 is equal to the spacing D2 of the first light transmission opening 122, as shown in FIG. 12A. When n = 2, the space | interval (lambda) of the discharge filament 180 is 2 times the space | interval D2 of the 1st light transmission opening 122, and it is as showing in FIG. 12B. When n = 3, the discharge filament 180 spacing lambda is three times the spacing D2 of the first light transmitting opening 122, and as shown in Fig. 12C, n = 4, 5... Also in this case, it can be inferred. When the spacing λ of the discharge filaments 180 is an integer multiple of the spacing D2 of the first light transmitting opening 122, the position of the discharge filament 180 generated when the dielectric barrier discharge lamp 101 discharges is It is stabilized and fixed on the black point shown in FIGS. 12A-12C. Compared to the common dielectric barrier discharge lamp, the discharge filament does not change position based on time. That is, that is, the discharge filament does not arbitrarily shift, is in a stable state, and the discharge lamp has a relatively strong luminous intensity. Therefore, the dielectric barrier discharge lamp 101 according to the present invention has the advantage of high light emission efficiency.

In the present embodiment, the discharge filament 180 appears at equal intervals λ, and is located near the position of the vertex of the polymorphism of the first light transmitting opening 122 as shown in Figs. 12A to 12C, that is, It is fixed at the center position of the dead point of the line width d near the vertex. This is because when a bias voltage is applied between the first electrode plate 120 and the second electrode plate 130, the space near the intersection point of their line width has the highest electric field. Therefore, when the characteristic interval λ of the discharge filament 180 of the discharge lamp is combined with the interval D2 of the first light transmitting opening 122, the discharge filament 180 naturally forms the first electrode plate 120. And the electric field between the second electrode plate 130 is the highest, that is, on the intersection of the line width d, for example, at the position of the discharge filament 180 shown in FIGS. 12A to 12C. Conversely, in the present embodiment, when the gap D2 of the first light transmitting opening 120 of the first electrode plate 120 does not match the gap λ of the discharge filament 180, the discharge filament 180 Steadily shifts unstable and causes a decrease in luminescence intensity and a poor luminescence uniformity. Therefore, in order for the dielectric barrier discharge lamp 101 to have a discharge filament which is stable and does not shift when discharging, the highest electric field between the first electrode plate 120 and the second electrode plate 130 is equally spaced. Since it is necessary to be arranged with a periodicity, since the first electrode plate 120 according to the present invention has an opening 112 is arranged at regular intervals, it is possible to achieve this object and effect.

In the present invention, the dielectric barrier discharge lamp has a specific discharge filament spacing [lambda] as follows.

According to the literature description, J Guikema et al., In Physical Review Letters, Vol. 85, No. 18, p. 3817-3820, discharge filaments in which a dielectric barrier discharge lamp is generated are arranged at equal intervals (λ), and the interval (λ). The magnitude of is described as being related to the discharge voltage. Also in this embodiment, it is understood that the magnitude of the interval λ is related to the frequency of the input current and the gas total pressure, in addition to the discharge voltage. For example, in this embodiment, the AC bias input to the discharge tube is about 5 Hz, the frequency of the AC bias is about 18 Hz, the discharge gas is xenon, the first electrode plate 120 and the second. When the electrode plate 130 has an interval of about 6.5 mm and the total gas pressure of the discharge gas is about 200 Torr, about 300 Torr, and about 400 Torr, respectively, the gap between the discharge filaments 180 generated in the dielectric barrier discharge lamp 101 (λ) is about 15 mm, about 12 mm, and about 10 mm, respectively.

In addition, after knowing the discharge filament interval λ, which is one of the characteristics of the dielectric barrier discharge lamp according to changing the applied periodic voltage (| V ₁ -V ₂ |), the frequency, or the magnitude of the total gas pressure of the discharge gas 140, According to the design of the electrode, the arrangement interval D2 of the first light transmitting openings 122 may be equal to the discharge filament interval λ. As described above, when discharging, the position of the discharge filament 180 of the lamp body 110 is the intersection of the line width d of the first electrode (for example, the position of the discharge filament 180 of FIGS. 12A to 12C). Can be stabilized and fixed, that is, the position of the discharge filament 180 is already covered by the first electrode plate 120.

In addition, the discharge filament spacing is thus wide (for example, about 10 mm even in the smallest case according to the present embodiment), and accordingly, the size of the hole of the external electrode is similar to that of the network structure of the actually woven mesh electrode. It does not need to be fine (for example, about 1-2 mm). However, when the network structure of the mesh electrode is squeezed largely, such as about 12 mm, the arrangement and spacing of such network holes are difficult to control with great precision. Experimental results according to the present embodiment, it is possible to achieve a stable effect of the discharge filament 180 only by precise control of the arrangement and spacing of the openings 122, and also to manufacture the first electrode plate 120 according to the present invention The method causes the use of the precise etching or press working of the metal plate. For example, the gas total pressure of the discharge gas 140 of the dielectric barrier discharge lamp 101 is about 300 Torr, and the spacing λ of the generated discharge filament 180 is about 12 mm. Under the conditions, the distance D2 of the first light transmitting opening 122 of the first electrode plate 120 is about 4 mm, about 6 mm, about 8 mm, about 10 mm and about 12 mm, respectively. Design. Thereafter, the same bias (| V ₁ -V ₂ |) is applied between the first electrode plate 120 and the second electrode plate 130, respectively, and the first electrode of the first electrode plate 120 is then applied. The dielectric barrier discharge lamp 101 is caused by the phenomenon that the generated discharge filament 180 reciprocates and shifts in the dielectric barrier discharge lamp 101 having a light transmission aperture gap D2 of about 8 mm and about 10 mm. It turns out that the fall of luminous efficiency of is caused. However, the first light transmission aperture gap D2 of the first electrode plate 120 is about 4 mm (ie, D2 = λ / 3), about 6 mm (ie, D2 = λ / 2) and about 12 When the thickness is about mm (i.e., D2 = λ), the position of the discharge filament 180 (see FIGS. 12A to 12C) where the dielectric barrier discharge lamp 101 is generated is sufficiently stable, and under such circumstances, the dielectric barrier discharge lamp The luminous efficiency of 101 becomes sufficiently good.

In a preferred embodiment of the present invention, the lengths of the outer tube 112 and the inner tube 114 of the dielectric barrier discharge lamp 101 are, for example, about 300 mm, respectively, and the outer tube 112 and the inner side thereof. The thickness of the tube 114 is, for example, about 1 mm, the diameter of the outer tube 112 is, for example, about 27 mm, and the diameter of the inner tube 114 is, for example, It is about 16 mm, and the axial center of the outer side pipe 112 and the inner side pipe 114 overlaps each other. Further, the discharge gas 140 may be, for example, gas mercury, helium, neon, xenon, argon, krypton, nitrogen, hydrogen selenide, deuterium, fluorine, or chlorine, bromine, iodine or two or more of the above gases. The mixed gas is mixed, and the bias applied (| V ₁ -V ₂ |) is an alternating bias, and the magnitude of the bias is, for example, about 5 Hz, and the frequency of the alternating bias is, for example, about 18 It is about.

The discharge gas 140 is xenon, the shape of the first light transmitting opening 122 is a regular hexagon, and the line width d is about 1.0 mm, and the distance D2 between the other first light transmitting openings 122 is taken as an example. ). Calculate the aperture ratio of the dielectric barrier discharge lamp 101 (the total area of the first light transmitting openings 122 divided by the sum of the total area of the first light transmitting openings 122 and the area covered by the line width d). The aperture ratio according to this embodiment is about (D (2-d) ² / D 2) ² . The measurement obtained when the ultraviolet light intensity of the measured value (172 nm) was measured (a measurement position is a distance of about 4 mm directly under the outer tube outer surface 116 of a discharge lamp toward a radial direction, and is measured in air.) The results are shown in Table 1 below.

First light transmission aperture distance D2 (mm) 4 6 8 10 12 % Aperture of dielectric barrier lamp 64 74 79 83 85 Light emission intensity (kW / cm 2) of the dielectric barrier discharge lamp, wavelength = 172 nm 2.8 3.3 3.5 3.8 4.9

As can be seen from Table 1, the aperture ratio of the dielectric barrier discharge lamp 101 and the first light transmitting aperture interval D2 are approximately in direct proportion. Moreover, in addition to being achieved by changing the 1st light transmissive opening width D1, it can also be achieved by changing the line width d. It should be noted that the line width d of the first light transmissive opening 122 should not be too small, and when the first line width d is excessively small, on the contrary, the emission intensity of the dielectric barrier discharge lamp 101 is lowered. . For example, in the above-described embodiment, when the first electrode plate 120 having the first light transmission aperture gap D2 of about 12 mm is taken as an example, the line width d is about 0.2 mm at about 1.0 mm. When descending to about mm, the aperture ratio increases from about 85% to about 97%, but the luminous intensity drops to about 4.1 dl / cm 2 from about 4.9 dl / cm 2.

In the above-described preferred embodiment of the present invention, when the first light transmitting opening 122 is a regular hexagon (see FIG. 3), the line width and the opening ratio of the first electrode affect the light emission intensity of the dielectric barrier discharge lamp. The three-way relationship is as shown in FIG. In Fig. 13, when the first light transmission aperture interval D2 is about 4 mm and the line width d is about 0.2 mm, the light emission intensity of the dielectric barrier discharge lamp 101 is the highest.

In addition to the fact that the lamp body according to the present invention described above has a place to improve the light emission intensity, the lamp body according to the present invention also has good light emission uniformity, and the following table 2 shows other measurement positions of the dielectric barrier discharge lamp 101 (measurement points are It indicates the distance from one end of the discharge lamp tube to the measurement position.) And the measured light emission intensity (the measurement position is about 2.0 mm in the direction immediately below the discharge lamp tube). It should be noted that, as the first electrode plate of the discharge lamp 101 applied to the experiment shown in Table 2 has a first hexagonal light transmission opening 122, the distance D2 is about 4 mm, The line width d is about 0.2 mm.

Distance (mm) from one end of the discharge lamp 70 140 210 280 Light emission intensity (kW / cm 2) of the dielectric barrier discharge lamp, wavelength = 172 nm 8.1-8.4 8.1-8.2 7.9 to 8.1 7.9-8.0

As shown in Table 2, when the distance from the dielectric barrier discharge lamp 101 to the end becomes further, the light intensity therefrom does not make a great change. In other words, the entire length of the dielectric barrier discharge lamp 101 has good light emission uniformity.

In order to confirm whether the discharge lamp according to the present invention has a higher light intensity than that of the conventional discharge lamp, the following experiment was conducted.

The discharge lamp tube used in the experiment was replaced with a conventional external seam-shaped external electrode, and the size of the network structure of the mesh electrode was about 1.5 mm, and the woven network structure was made of stainless steel metal wire. The diameter of the wire is about 0.1 mm. Using the discharge lamp tube of such a mesh-shaped external electrode, the ultraviolet light intensity at the position of about 3 mm below the discharge tube and the wavelength of about 172 nm measured in air is about 5.9 mW / cm 2. Subsequently, the discharge lamp tube in which the above experiment was used was replaced with an external electrode plate according to the present invention, and the intervals D2 (mm) / line width d of the holes of the plate were each about 4 / 0.2 mm, and the same Under the situation where the power efficiency is input, the light intensity value measured at the position of about 3 mm below the discharge tube is also about 7.2 kW / cm 2. As can be seen from the above experimental values, the light emission intensity of the discharge tube obtained by employing the external electrode according to the present invention is surely higher than the light emission intensity of the conventional metal mesh external electrode discharge tube. The reason for this is as described in the above description of the present invention, and the external electrode according to the present invention can effectively improve the aperture ratio and maintain the spacing, stability and strength of the discharge filament.

Example  2

14 is a side view of a dielectric barrier discharge lamp according to Embodiment 2 of the present invention.

In Fig. 14, the dielectric barrier discharge lamp 102 according to the present embodiment is different from the dielectric barrier discharge lamp 101 of the first embodiment described above, and the main difference is that of the lamp body 110 'according to the present embodiment. The lamp body 110 shown in FIG. 1 and FIG. 2 is different, and the lamp body 110 'which concerns on a present Example is comprised from the single lamp tube 190. FIG.

As shown in FIG. 14, when the lamp body 110 ′ to be applied is composed of a single lamp tube 190, the first electrode plate 120 of the dielectric barrier discharge lamp 102 is connected to the lamp tube 190. Disposed on the outer surface 192, the second electrode plate 130 is disposed inside the lamp tube 190, and the discharge gas 140 is disposed in the lamp tube 190 and at the same time, the first electrode plate 120 is disposed. ) And the second electrode plate 130.

Design of the first electrode plate 120 according to the present embodiment is substantially the same as the first electrode plate 120 of the first embodiment described above, the method of fixing to the lamp tube 190 also in the case of the first embodiment Is substantially the same as Therefore, the aperture ratio, emission intensity, and emission uniformity of the dielectric barrier discharge lamp 102 according to the present embodiment are all superior to those of the known dielectric barrier discharge lamp similarly to the dielectric barrier discharge lamp 101 according to the first embodiment.

Example  3

15 is a side view of a dielectric barrier discharge lamp according to Embodiment 3 of the present invention.

In Fig. 15, the dielectric barrier discharge lamp 103 according to the present embodiment is different from the dielectric barrier discharge lamp 101 according to the first embodiment and the dielectric barrier discharge lamp 102 according to the second embodiment, and the main differences thereof. Is different from the lamp body 110 ″ applied to the present embodiment and the lamp bodies 110 and 110 ′ shown in FIGS. 1, 2, and 13, and the lamp body 110 ″ according to the present embodiment is flat. This is the lamp body 194. In a preferred embodiment, the flat lamp body 194 includes an upper substrate 194a, a lower substrate 194b and a plurality of sidewalls 194c, and the lower substrate 194b is positioned below the upper substrate 194a. do. The sidewalls 194c are connected between the upper substrate 104a and the lower substrate 194b, the first electrode plate 120 is disposed on the upper surface 196 of the upper substrate 194a, and the second electrode plate ( 130 is disposed on the lower surface 198 of the lower substrate 194b. In addition, the discharge gas 140 is disposed in the lamp body 110 ″ formed by the upper substrate 194a, the lower substrate 194b, and the sidewall 194c, and at the same time, the first electrode plate 120 and the second electrode plate ( 130).

The first electrode plate 120 of the dielectric barrier discharge lamp 103 according to the present embodiment is fixed to the upper surface 196 of the upper substrate 194a by, for example, a welding method or a latch method. Similarly, the second electrode plate 130 is fixed to the lower surface 198 of the lower substrate 194b by, for example, a welding method or a latch method. In addition, the design of the first light transmitting opening 122 on the first electrode plate 120 is substantially the same as that of the first electrode plate 120 of the first embodiment described above. In addition, the second electrode plate 130 is also substantially the same as the first electrode plate 120 according to the first embodiment. Therefore, the aperture ratio, the light emission intensity and the light uniformity of the dielectric barrier discharge lamp 103 according to the present embodiment all become good.

According to the present invention, since the first light transmissive openings on the first electrode plate are regularly arranged at equal intervals, when applying a bias between the first electrode plate and the second electrode plate, the equal interval λ is provided in the lamp body. A plurality of discharge filaments are generated that are arranged in a space. When the relationship between the spacing D2 of the first light transmitting openings and the equal interval λ is D2 = λ / n (n is a positive integer), the dielectric barrier discharge lamp according to the present invention is good in terms of high aperture ratio, light emission uniformity, and the like. Has characteristics.

Although described above with reference to the embodiments of the present invention, those skilled in the art various modifications and changes to the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

Claims (25)

In a dielectric barrier discharge lamp, Lamp body; A first electrode plate disposed on the lamp body, the first electrode plate having a plurality of regular and equally spaced first light transmitting openings; A second electrode plate disposed on the lamp body and electrically insulated from the first electrode plate; And Disposed in the lamp body, positioned between the first electrode plate and the second electrode plate, and arranged in the lamp body at equal intervals when a bias is applied between the first electrode plate and the second electrode plate; Wherein a plurality of discharge filaments are generated, and a position where all the discharge filaments are present comprises a discharge gas covered by the first electrode plate. 2. The dielectric barrier discharge lamp of claim 1, wherein when the spacing of said discharge filaments is [lambda] and the spacing of said first light transmitting apertures is D2, D2 = [lambda] / n and n is a positive integer. The method of claim 1, wherein the lamp body, An outer tube in which the first electrode is disposed on an outer surface thereof; And An inner tube disposed in the outer tube and connected to the outer tube; And the discharge gas is disposed in the inner tube and the outer tube, and the second electrode plate is disposed on an inner surface of the inner tube. The method of claim 3, wherein the first electrode plate has a plurality of first bending auxiliary holes, the first bending auxiliary holes are distributed around the first electrode plate, surrounding the outer periphery of the first light transmitting opening A dielectric barrier discharge lamp, characterized in that. 4. The wire rod of claim 3, further comprising a wire rod, wherein the first electrode plate has a through hole penetrating through the wire rod, wherein the wire rod is configured to completely adhere the first electrode plate onto the outer surface of the outer tube. A dielectric barrier discharge lamp characterized in that. The method of claim 3, wherein the first electrode has a plurality of engagement holes and a plurality of protrusions, the plurality of engagement holes are located on one side of the first electrode plate, the plurality of protrusions of the first electrode plate And a plurality of protrusions engaged in the plurality of engagement holes such that the first electrode plate is completely in contact with the outer surface of the outer tube. 4. The dielectric barrier discharge lamp of claim 3, wherein one side of the first electrode plate and the other side of the first electrode plate are welded and completely adhered to the outer surface of the outer tube. The method of claim 1, wherein the first electrode plate further comprises a plurality of second light transmitting openings arranged at regular intervals, wherein the second light transmitting openings are distributed on one side or both sides of the first light transmitting openings. A dielectric barrier discharge lamp, characterized in that. 9. The dielectric barrier discharge lamp of claim 8, wherein the first and second light transmissive openings are similar to each other. 10. The dielectric according to claim 9, wherein when the arrangement interval of the first light transmission openings is D2 and the arrangement interval of the second light transmission openings is D3, D3 = D2 / n, and n is a positive integer. Barrier discharge lamp. The dielectric barrier discharge according to claim 1, wherein the lamp body is a lamp tube, the first electrode plate is located on an outer surface of the lamp tube, and the second electrode is located inside the lamp tube. lamp. The dielectric barrier discharge lamp of claim 1, wherein the lamp body is a flat lamp body. The method of claim 12, wherein the flat lamp body, An upper substrate; A lower substrate positioned below the upper substrate; And A plurality of sidewalls connected between the upper substrate and the lower substrate, And the first electrode plate is disposed on an upper surface of the upper substrate, and the second electrode is disposed on a lower surface of the lower substrate. The dielectric barrier discharge lamp of claim 1, wherein the first light transmissive openings are polymorphic openings. The dielectric barrier discharge lamp of claim 1, wherein the first light transmitting openings of the first electrode plate are formed by an etching process or a press process. The dielectric barrier discharge lamp of claim 1, wherein the first light transmitting openings each comprise an equilateral triangle opening, a square opening, a regular hexagon, a rhombic opening, or a trapezoidal opening. The material of the first electrode plate and the second electrode plate is copper, aluminum, nickel, chromium, gold, molybdenum, silver, platinum, iron, titanium, tungsten, cobalt or a mixture of these metals. A dielectric barrier discharge lamp comprising: The method of claim 1, wherein the discharge gas is a gas mercury, helium, neon, xenon, argon, krypton, nitrogen, hydrogen selenide, deuterium, fluorine or chlorine, bromine, iodine or a mixture of two or more of these gases A dielectric barrier discharge lamp comprising: An electrode plate, characterized in that it comprises a plurality of first light transmitting openings arranged at regular intervals. 20. The electrode plate of claim 19, further comprising a plurality of first bend aid holes, wherein the first bend aid holes are distributed around the electrode plate and surround the outer circumference of the first light transmitting openings. . 20. The method of claim 19, further comprising a plurality of engagement holes and a plurality of protrusions, the plurality of engagement holes are located on one side of the electrode plate, the plurality of protrusions protrude from the other side of the electrode plate, the electrode And when the plate is bent, the plurality of protrusions are engaged in the plurality of engagement holes. 20. The apparatus of claim 19, further comprising a plurality of second light transmissive openings arranged at regular intervals, wherein the plurality of second light transmissive openings are distributed on one or both sides of the plurality of first light transmissive openings. An electrode plate characterized by the above-mentioned. 23. The electrode plate according to claim 22, wherein the plurality of first light transmitting openings and the plurality of second light transmitting openings are similar to each other. The method of claim 22, wherein when the arrangement interval of the plurality of first light transmission openings is D2, and the arrangement interval of the plurality of second light transmission openings is D3, D3 = D2 / n, and n is a positive integer. An electrode plate characterized by the above-mentioned. 23. The electrode plate according to claim 22, wherein the plurality of first light transmitting openings and the plurality of second light transmitting openings are polygonal openings.

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