KR20110061599A - Excimer lamp, excimer lamp unit, and ultraviolet irradiation device - Google Patents

Abstract

An object of the present invention is to provide an excimer lamp and an excimer lamp unit capable of connecting a power supply to the external electrodes 3 and 4 of the excimer lamp 1 without using a lead wire.
An excimer lamp arranges a pair of external electrodes in the upper and lower flat surfaces of the discharge tube 2 which sealed the gas for discharge in the internal discharge space 2a, and has a pair of connector terminals 8 connected to these external electrodes, respectively, It is set as 8) the structure arrange | positioned at the upper and lower flat surface of the connector part 2b provided in the edge part of this discharge tube. In addition, the excimer lamp unit is provided with a socket portion 7a for inserting and supporting the connector portion of the excimer lamp so that the connector portion can be attached and detached, and the pair of connector terminals in the inserted connector portion while being inside the socket portion. The lamp socket 7 which arrange | positioned the pair of multipoint contact material 13 and 13 connected to the power supply of an excimer lamp in the position which contact | connects to is set as the structure included.

Description

Excimer lamp and excimer lamp unit and ultraviolet irradiation device {EXCIMER LAMP, EXCIMER LAMP UNIT, AND ULTRAVIOLET IRRADIATION DEVICE}

The present invention supports an excimer lamp which generates discharge by an external electrode in a discharge space in a discharge tube containing a gas for discharge, and emits ultraviolet rays, and supports the excimer lamp with a lamp socket, and further, an external electrode. The excimer lamp unit which connects with a power supply, and the ultraviolet irradiation device using these are related.

The excimer lamp emits high energy vacuum ultraviolet rays having a center wavelength of 172 nm when xenon gas is used as the gas for discharge, and thus an ultraviolet irradiation device which performs light cleaning or the like on an irradiated object such as a glass substrate or a semiconductor wafer of a liquid crystal display. It can be used as a light source lamp of. As the excimer lamp, a cylindrical tube is used as the discharge tube enclosing the gas for discharge (see, for example, Patent Document 1), or a rectangular sealed container is used (see, for example, Patent Document 2).

Since vacuum ultraviolet rays are absorbed by oxygen and generate ozone, they are immediately attenuated when released into the air. Therefore, in the case of using an excimer lamp using a discharge tube of a cylindrical tube, an excimer lamp is disposed inside an ultraviolet irradiation device in which a glass plate is disposed at the lower end to make an atmosphere in which oxygen is purged. It is necessary to irradiate the vacuum irradiated to the flat to-be-projected object arrange | positioned at the lower side through the glass plate of this in order to prevent this vacuum ultraviolet-ray from attenuating in air in vain. However, in the case of using an excimer lamp using a rectangular discharge tube, vacuum ultraviolet rays can be directly irradiated to flat irradiated objects arranged at a slight distance below the wide lower flat surface, thereby simplifying the structure of the ultraviolet irradiation device. have.

The conventional structural example of an excimer lamp using a square discharge tube is shown to FIG. 10 and FIG. The discharge tube 2 of the excimer lamp 1 is a rectangular hermetically sealed container formed of synthetic quartz having a long side to the left and a flat surface up and down, and xenon gas is enclosed in the internal discharge space 2a. . As shown in FIG. 10, the discharge tube 2 is formed with an external electrode 3 formed on the upper flat surface over the entire surface, and as shown in FIG. The electrode 4 is formed. These external electrodes 3 and 4 are made of a metal thin film formed on the surface of the discharge tube 2 by metal deposition or the like. However, although the external electrode 3 of the upper flat surface uniformly forms a metal thin film in the film forming area, the external electrode 4 of the lower flat surface meshes the metal thin film in the film forming area except for the left end. It is formed into a (mesh) pattern.

The excimer lamp 1 applies a high frequency high voltage between the external electrodes 3 and 4, so that a dielectric barrier discharge is performed in the discharge space 2a inside the discharge tube 2 made of a dielectric. Since the ultraviolet rays are emitted to emit vacuum ultraviolet rays, the vacuum ultraviolet rays can be emitted downward through the gap between the mesh grids of the external electrodes 4 on the lower flat surface.

Here, since the conventional excimer lamp 1 applies a high frequency high voltage between the external electrodes 3 and 4, the lead wires 5 and 5 are connected to the external electrodes 3 and 4, as shown in FIG. have. That is, the excimer lamp 1 solders the leading ends of the lead wires 5 and 5 to the ends of the left side of the external electrodes 3 and 4, respectively, and further includes the leading ends of these lead wires 5 and 5, respectively. The edge part of the discharge tube 2 side is clamped by the pair of ceramic blocks 6 and 6 from up and down. Then, the ceramic blocks 6 and 6 are supported and fixed to an ultraviolet irradiation device (not shown), and the base side of the lead wires 5 and 5 are connected to a high voltage terminal and a ground terminal of a high frequency high voltage power supply (not shown). The high frequency high voltage is applied to the external electrodes 3 and 4 of the excimer lamp 1.

However, each lead wire 5 needs to cover the conducting wire with the coating | covering material 5a for the insulation of a high frequency high voltage. In the excimer lamp 1, since the discharge tube 2 becomes hot due to discharge, a silicon wire coated with a conductive wire with a silicone resin having high insulation and heat resistance and flexibility, is used as the lead wire 5.

Japanese Patent Application Publication No. 2001-243920 (FIG. 4) Japanese Patent Application Publication No. 2000-260396

However, the vacuum ultraviolet rays radiated from the discharge space 2a of the discharge tube 2 may leak to the outside from the left and right ends due to the repeated reflection in the tube wall of the discharge tube 2, and the silicone resin. May deteriorate by vacuum ultraviolet rays. Therefore, each lead wire 5 further covers the silicone resin of the silicon electric wire with PFA (thermoplastic fluorine resin) which is not easily deteriorated by vacuum ultraviolet rays and has high insulation and heat resistance, so that the two-layer structure of these silicone resins and PFA The covering material 5a is used.

However, the present inventors found out the following fact as a result of repeating experiment and examination. PFA used as the outer layer of the covering material 5a of the lead wire 5 is also degraded to some extent when exposed to high energy vacuum ultraviolet rays for a long time. When the PFA is deteriorated by vacuum ultraviolet rays, decomposition gas is generated, and the excimer lamp 1 is irradiated because the external electrodes 3 and 4 are discolored or the surface of the discharge tube 2 is contaminated by the decomposition gas. There was a problem that the intensity of the vacuum ultraviolet rays decreased. In addition, there is a problem that the irradiated object is contaminated by the decomposition gas. In addition, when the PFA in the upper layer of the coating material 5a cracks due to deterioration, vacuum ultraviolet rays are applied to the lower silicone resin, so that chalking occurs, and thus powdery matter by this choking is produced. There was also a problem that this fall caused the contamination of the irradiated object.

And even if it is ultraviolet-ray of wavelength longer than a vacuum ultraviolet-ray, since resin differs in degree but eventually deteriorates, also in the case of an excimer lamp which radiates ultraviolet-rays other than vacuum ultraviolet-ray, these problems arise similarly. In addition, since the power supply of an excimer lamp is a very high voltage, when the lead wire is used for connection, insulation by the resin coating material 5a becomes essential.

An object of the present invention is to provide an excimer lamp and an excimer lamp unit that can solve the above-described problems, and an ultraviolet irradiation device configured using these.

The excimer lamp of Claim 1 arrange | positions a pair of external electrode in the different site | part of the outer surface of the discharge tube which filled the gas for discharge in the internal discharge space, and connects a pair of connector terminal respectively connected to these external electrodes with this discharge tube It is arrange | positioned at the mutually different site | part of the outer surface side of the connector part provided in the edge part of this.

The excimer lamp of Claim 2 is a part in which the said connector part is the edge part of the left side or the right side of a discharge tube, and a discharge space does not exist inside.

The excimer lamp of Claim 3 is a rectangular sealed container in which the said discharge tube is long left and right, and the upper and lower flat surfaces were formed, and a pair of external electrodes were arrange | positioned at the upper and lower flat surfaces of the said discharge tube, respectively, It is characterized by the above-mentioned.

The excimer lamp of claim 4 is characterized in that each of the external electrodes is formed of a metal thin film formed on an outer surface of a discharge tube.

The excimer lamp of claim 5 is characterized in that each of the external electrodes is made of a metal plate arranged on an outer surface of a discharge tube.

The excimer lamp of claim 6 is characterized in that each of the connector terminals comprises a portion arranged on the outer surface of the connector portion of the discharge tube in the external electrode.

The excimer lamp of claim 7 is characterized in that each of the connector terminals is a block-type terminal pressed through a multi-point contact material to a portion formed on the outer surface of the connector portion of the discharge tube in the external electrode.

The excimer lamp of claim 8 is characterized in that each of the connector terminals is made of a metal plate connected and fixed to a portion formed on the outer surface of the connector portion of the discharge tube in the external electrode via a solder layer.

The excimer lamp of claim 9, wherein each of the connector terminals is a block-type terminal pressed through a multi-point contact material to a metal sheet connected and fixed to a portion formed on the outer surface of the connector portion of the discharge tube at the external electrode through the solder layer. It features.

The excimer lamp of claim 10 is characterized in that each of the block-type connector terminals is pressed by a pair of ceramic blocks in which the connector portions of the discharge tube are clamped from both sides.

Claim 11 is characterized in that the excimer lamp emits vacuum ultraviolet rays.

12. Each said connector terminal is a block-type terminal provided in the part formed in the outer surface of the connector part of the discharge tube in the external electrode.

The ultraviolet irradiation device of Claim 13 was equipped with the said excimer lamp, It is characterized by the above-mentioned.

The excimer lamp unit of claim 14 has a socket portion for inserting and supporting the excimer lamp and the connector portion of the excimer lamp, and is located inside the socket portion and in contact with a pair of connector terminals in the inserted connector portion. It is characterized by consisting of lamp sockets each having a pair of terminal contacts connected to a power supply of an excimer lamp.

The excimer lamp unit of claim 15 is characterized in that each of the terminal contacts is made of a multi-point contact material.

The excimer lamp unit of claim 16 is characterized in that each of the terminal contacts is made of a metal leaf spring.

The ultraviolet irradiation device of claim 17 is provided with the said excimer lamp unit. It is characterized by the above-mentioned.

In addition, the directions of left and right and up and down in these claims are merely for showing the directions orthogonal to each other, and are not necessarily limited to the ones which are actually coincident with the left, right and up and down directions.

According to the invention of claim 1, since the connector portion connected to the external electrode is disposed at the end of the discharge tube, it is possible to connect to the power supply only by contacting the terminal contactor or the like, without connecting the lead wire to the external electrode, thereby covering the resin of the lead wire. Due to the deterioration of the resin due to the ultraviolet rays, the decomposition gas is not generated or the powdered matter due to the choking does not fall.

According to the invention of claim 2, since there is no discharge space inside the connector portion of the discharge tube, even if pressure is applied to the connector portion, there is no fear that the discharge tube will be damaged. Therefore, it is possible to adopt a structure in which the connector portion is pressed by a connector terminal or the like, or when the excimer lamp is supported by a lamp socket or the like, firmly supported or connected by pressing.

According to the invention of claim 3, even in an excimer lamp using a rectangular discharge tube, the risk of contamination of the irradiated object can be eliminated. That is, if a glass plate or the like is disposed between the excimer lamp and the irradiated object, the decomposition gas generated by the deterioration of the resin or the powdered powder due to the choking may not contaminate the irradiated object, but the excimer lamp using the rectangular discharge tube In this case, since there is no need to arrange a glass plate or the like, conventionally, this decomposition gas or powdered powder by choking may contaminate the irradiated object. However, according to the present invention, there is no need to use a lead wire coated with resin, so that such a problem of contamination can also be solved.

According to the invention of claim 4, since the external electrode of the metal thin film can be brought into close contact with the outer surface of the discharge tube without a gap, the discharge efficiency can be improved.

According to the invention of claim 5, since the external electrode is formed only by disposing a metal plate on the outer surface of the discharge tube, the external electrode can be easily assembled.

According to invention of Claim 6, since the external electrode arrange | positioned at the outer surface of a discharge tube can be used as a connector terminal in a connector part as it is, there is no need to assemble a separate connector terminal.

According to the invention of claim 7, since the block-type terminal serving as the connector terminal is pressed against the external electrode through the multi-point contact material, the connection between the block-type connector terminal and the external electrode becomes small and secure in contact resistance. Desorption is also easy. In addition, since the multi-point contact material is connected through a plurality of contacts, it is particularly suitable for connection of excimer lamps to which high frequency and high voltage are applied. And since a block-type connector terminal has large heat capacity, it is not easy to connect it directly to an external electrode by soldering etc. Therefore, the connection is reliably performed by pressing the block-type connector terminal to the external electrode through the multi-point contact material.

According to the invention of claim 8, even if the external electrode is easily cut or peeled off such as a metal thin film or the like, the connector terminal which contacts or presses the terminal contactor or the like is connected and fixed to the external electrode through a solder layer. Since it becomes a metal plate, the external electrode can be prevented from being chipped or peeled off. And since the metal plate which is a connector terminal has a comparatively small heat capacity, it can solder easily to the external electrode which is a metal thin film.

According to the invention of claim 9, even if the external electrode is easily cut and peeled like a metal thin film or the like, the connector terminal for contacting or applying pressure to the terminal contactor or the like becomes a block type terminal, so that the external electrode is sharpened. Or peeling can be prevented. Moreover, since the multi-point contact material interposed between this block-type connector terminal and an external electrode also comes into contact with the metal sheet connected and fixed to this external electrode through the solder layer, this multi-point contact material cuts off an external electrode, There is no fear of peeling. And since the block-type connector terminal has a large heat capacity, it is not easy to directly solder to an external electrode such as a metal thin film. Therefore, first, the metal sheet with a small heat capacity is soldered to the external electrode, and then the metal sheet is reliably connected by pressing the block-type connector terminal through the multi-point contact material.

According to the tenth aspect of the present invention, the block-type connector terminal can be pressed by a pair of ceramic blocks that are insulating and have no fear of deterioration due to ultraviolet rays, so that the connection of the connector terminals to the external electrodes can be ensured.

According to the invention of claim 11, it is possible to provide an invention particularly suited to an excimer lamp which is susceptible to deterioration of the resin by emitting high energy vacuum ultraviolet rays.

According to invention of Claim 12, it is not necessary to attach a lead wire, and it can be set as the structure which is easy to manufacture and handle.

According to the invention of claim 13, since the connector portion connected to the external electrode is disposed at the end of the discharge tube, even if the lead wire is not connected to the external electrode, it is possible to connect to the power supply only by contacting the terminal contactor or the like, so that the resin coating of the lead wire By the deterioration of the resin due to the ultraviolet rays, an ultraviolet irradiation device in which decomposition gas does not occur or powdered matter due to choking does not fall can be made. In addition, since there is no discharge space inside the connector portion of the discharge tube, there is no fear that the discharge tube will be damaged even if pressure is applied to the connector portion. Therefore, it is possible to adopt a structure in which the connector portion is pressed by the connector terminal or the like, or when the excimer lamp is supported by the lamp socket or the like by applying pressure to reliably support or connect.

According to the invention of claim 14, since the lamp socket supports the connector portion of the excimer lamp at the socket portion, and connects a pair of terminal contactors inside the socket portion to the power supply by contacting the connector terminal of the excimer lamp, the excimer lamp is mounted. Can be discharged. In addition, since it is not necessary to use a lead wire coated with resin, decomposition gas is not generated due to deterioration of the resin due to ultraviolet rays, or powdered substances due to choking do not fall. The excimer lamp does not need to be supported only by the lamp socket, but can be mounted by, for example, a combination of support by the lamp socket and support by another support material.

According to the invention of claim 15, since the terminal contact of the lamp socket contacting the connector terminal of the excimer lamp is made of a multi-point contact material, the contact resistance of the excimer lamp and the high frequency high voltage power supply becomes small and reliable, and the detachment degree It becomes easy. In addition, since the multi-point contact material is connected through a plurality of contacts, it is particularly suitable for connection of excimer lamps to which high frequency and high voltage are applied.

According to the sixteenth aspect of the present invention, since the terminal contact of the lamp socket contacting the connector terminal of the excimer lamp is made of a metal leaf spring, the connection between the excimer lamp and the high frequency high voltage power supply is assured, and the attachment and detachment is easy. .

According to the invention of claim 17, since the lamp socket supports the connector portion of the excimer lamp at the socket portion, and connects a pair of terminal contacts inside the socket portion to the power supply by contacting the connector terminal of the excimer lamp, the excimer lamp is mounted. The ultraviolet irradiation device can be made to discharge. Moreover, since it is not necessary to use the lead wire | coated coated with resin, decomposition gas does not generate | occur | produce or the powdery substance by choking does not fall by deterioration of resin by an ultraviolet-ray. In addition, since the terminal contact of the lamp socket contacting the connector terminal of the excimer lamp is made of a multi-point contact material, the contact resistance of the excimer lamp and the high-frequency high-voltage power supply becomes small and reliable, and the attachment and detachment is also easy. In addition, since the multi-point contact material is connected through a plurality of contacts, it is particularly suitable for connection of excimer lamps to which high frequency and high voltage are applied. In addition, since the terminal contact of the lamp socket contacting the connector terminal of the excimer lamp is made of a metal leaf spring, the connection between the excimer lamp and the high frequency high voltage power supply is assured, and the attachment and detachment is easy.

Figure 1 shows an embodiment of the present invention, a partial enlarged side cross-sectional view showing the configuration of the excimer lamp unit.
Figure 2 shows an embodiment of the present invention, a plan view (a), a side view (b) and a back view (c) showing the configuration of the discharge tube of the excimer lamp.
Figure 3 shows an embodiment of the present invention, a partial enlarged plan view (a) and a partial enlarged side cross-sectional view (b) showing the configuration of the excimer lamp.
Figure 4 shows an embodiment of the present invention, is a partially enlarged side cross-sectional view showing the configuration when the excimer lamp is inserted into the lamp socket.
Fig. 5 shows another embodiment of the present invention, and is a partially enlarged side sectional view showing the configuration of an excimer lamp.
6 shows another embodiment of the present invention, and is a partially enlarged side sectional view showing the configuration of an excimer lamp unit.
Fig. 7 shows another embodiment of the present invention and is a partially enlarged side sectional view showing the configuration of an excimer lamp unit.
Fig. 8 shows another embodiment of the present invention and is a partially enlarged side sectional view showing the configuration when the excimer lamp is inserted into the lamp socket.
Fig. 9 shows another embodiment of the present invention and is a partially enlarged side sectional view showing the configuration of an excimer lamp unit.
Fig. 10 shows a conventional example and is an overhead view showing the structure of a discharge tube of an excimer lamp.
Fig. 11 shows a conventional example and is a perspective view showing the structure of a discharge tube of an excimer lamp.
12 shows a conventional example and is a partially enlarged side cross-sectional view showing the configuration of an excimer lamp.

Best Mode for Carrying Out the Invention The best embodiment of the present invention will now be described with reference to Figs. In these drawings, the same numerals are assigned to constituent members having the same functions as the conventional examples shown in FIGS. 10 to 12.

As shown in FIG. 1, the present embodiment has the excimer lamp 1 using the rectangular discharge tube 2 filled with xenon gas, and an ultraviolet irradiation device which performs light cleaning of an irradiated object such as a glass substrate of a liquid crystal display. The lamp socket 7 for mounting the excimer lamp 1 will be described.

[Discharge tube of excimer lamp]

As shown in Figs. 2A to 2C, the discharge tube 2 of the excimer lamp 1 is formed of synthetic quartz in which the left and right opening ends of the long rectangular body are made of synthetic quartz. It is a hermetically sealed container formed with a quartz block to form a discharge space 2a, and xenon gas is enclosed in this discharge space 2a as a gas for discharge. Since the discharge side of the discharge tube 2 has a longer length of right and left than the right side of the synthetic quartz block blocking the open end of the left side of the main body, the discharge space of the discharge tube 2 extends to the left end of the discharge tube 2 over a certain length from side to side. There exists a part (2a) which does not exist, ie, the part which consists only of synthetic quartz, and this part becomes the connector part 2b. The discharge tube 2 is composed of an upper flat surface and a lower flat surface having substantially flat upper and lower surfaces, an external electrode 3 formed on the upper flat surface, and an external electrode 4 formed on the lower flat surface. have.

The outer electrode 3 of the upper flat surface is, as shown in Fig. 2A, an aluminum vapor deposition film uniformly formed on substantially the entire surface of the upper flat surface of the discharge tube 2, and a nickel vapor deposition film to protect the surface. It is a two-layer metal thin film which consists of. And this external electrode 3 is continuously formed also in the upper flat surface of the connector part 2b which does not have discharge space 2a in the lower side. As shown in Fig. 2C, the outer electrode 4 of the lower flat surface includes an aluminum vapor deposition film formed in a mesh pattern on the substantially entire surface of the lower flat surface of the discharge tube 2 and the surface of this mesh type. It is a two-layered metal thin film which consists of a nickel vapor deposition film which protects on a. The external electrode 4 is also continuously formed on the lower flat surface of the connector portion 2b without the discharge space 2a on the upper side, and this portion is formed in a constant pattern rather than a mesh shape.

When the discharge tube 2 of the excimer lamp 1 configured as described above applies a high frequency high voltage from a high frequency high voltage power source (not shown) between the external electrodes 3 and 4, the discharge tube 2 of the inside of the discharge tube 2 made of a dielectric material is used. Since dielectric barrier discharge occurs in the discharge space 2a, xenon atoms, which are discharge gases, are excited in this discharge space 2a, and when the xenon atoms return to the ground state, vacuum ultraviolet rays having a center wavelength of 172 nm are generated. Emit (excimer luminescence). The vacuum ultraviolet rays are emitted downward through the gap between the mesh grids of the external electrodes 4 on the lower flat surface of the discharge tube 2. Therefore, by irradiating the irradiated object with the vacuum gap emitted below the discharge tube 2 through a small gap, the irradiated object can be light-cleaned. The high frequency high voltage power supply of the excimer lamp 1 of the present embodiment has a frequency of 70 kHz, and supplies a high frequency high voltage of 14 kV at the start of voltage and 5 kV at the start of discharge.

[Connector terminal of excimer lamp]

As shown in FIG. 1, the excimer lamp 1 uses a pair of connector terminals 8 and 8 mounted on the upper and lower portions of the connector portion 2b at the left end of the discharge tube 2 to the external electrodes 3 and 4. Are connected to each. The connector terminals 8 and 8 are block-type terminals for connecting with the high frequency high voltage power supply of the excimer lamp 1 via the lamp socket 7, and are all nickel plated with copper alloy. And in the connector terminal 8 attached to the upper side of the connector part 2b, the projection part 8a which protrudes further upward in the center part is formed in the center part of the upper surface of a rectangular block shape, and below the connector part 2b. The connector terminal 8 to be attached is formed with a projection 8a which protrudes further downward in a center portion of the lower surface of the rectangular block shape.

Hereinafter, the mounting structure of the connector terminals 8 and 8 will be described in detail. Nickel sheets 10 and 10 are fixed to the surfaces of the external electrodes 3 and 4 of the connector portion 2b via the indium solder layers 9 and 9, respectively. And the connector terminals 8 and 8 are arrange | positioned on the surface of the nickel sheet 10 and 10 via the multipoint contact material 11 and 11, respectively.

Each of the multi-point contact materials 11 is a state in which a plurality of metal spring materials are in contact with the connector terminals 8 and the nickel sheet 10 up and down when the connector terminals 8 are pressed to the nickel sheet 10 side. Since it is a pressurized contact material, by this, the connector terminal 8 and the nickel sheet 10 are connected in the state which pressed the spring material in many points, and it can reliably connect with a small contact resistance even if high voltage is applied.

As a metal spring material used for the multipoint contact material 11, it is preferable to use the metal material for contacts which has big elasticity and is high in electroconductivity and small in contact resistance, and surface treatments, such as plating, in order to reduce contact resistance May be performed. In addition, when the multipoint contact material 11 supports many spring materials by a frame body etc., this frame body also uses a metal thing. As such a multi-point contact material 11, for example, many short leaf springs are arranged to be inclined between the connector terminal 8 and the nickel sheet 10, but many short coil springs are provided for the connector terminal 8, for example. ) And a plurality of coil springs inclined so as to be arranged in a plurality of longitudinal directions between the nickel sheet 10 and the nickel sheet 10 in a horizontal direction between the connector terminal 8 and the nickel sheet 10. Such as to be arranged.

As for the connector part 2b of the discharge tube 2, the pair of ceramic blocks 6 and 6 are clamped from the top and the bottom. As shown in Fig. 3, the upper ceramic block 6 is made of rectangular ceramics that are long before and after, and the lower center portion is concave in the upper portion and the hole in the form penetrating to the upper surface in the center portion of the recess is opened. Further, the front and rear ends of the lower surface protrude downward. Further, the lower ceramic block 6 is made of rectangular ceramics that are long before and after, and the upper center portion is recessed in a rectangle at the lower side, and a hole having a form penetrating into the lower portion at the center portion of the recess is opened, and the front and rear sides of the upper surface are further opened. The end protrudes upwards. Then, these ceramic blocks 6 and 6 are sandwiched from the top and bottom by passing the connector portion 2b of the discharge tube 2 over the front and rear, and the protruding ends of the front and rear ends are overlapped and fixed by bolts 12 and 12. The pinching is fixed.

Here, when each ceramic block 6 clamps the connector part 2b of the discharge tube 2 from up and down, the connector terminal 8 is inserted in the recessed part inside. At this time, in each connector terminal 8, the projection part 8a is fitted in the hole of the recessed part of the inside of the ceramic block 6, and the tip part protrudes. Moreover, each connector terminal 8 presses the circumference | surroundings of this protrusion part 8a by the ceramic block 6 to the discharge tube 2 side, and pressurizes the nickel sheet 10 through the multipoint contact material 11, have.

By the above-described mounting structure, the connector terminals 8 and 8 are connected to the external electrodes 3 and 4 via the multipoint contact materials 11 and 11, the nickel sheets 10 and 10, and the indium solder layers 9 and 9, respectively. ) Is securely connected. Since the connector terminal 8 has a large heat capacity, it is difficult to heat it to melt the indium solder layer 9 and directly connect it to the external electrodes 3 and 4. In addition, when the connector terminal 8 is pressed against the external electrodes 3 and 4 through the multi-point contact material 11, the spring material of the multi-point contact material 11 cuts the thin metal thin film of the external electrodes 3 and 4. Or peeling off. Therefore, the metal thin film of the external electrodes 3 and 4 is protected by heating the nickel sheet 10 having a small heat capacity, melting the indium solder layer 9 and soldering the external electrodes 3 and 4. In addition, since the nickel sheet 10 is not shaved or peeled off by the spring material of the multi-point contact material 11, the nickel terminal 10 is reliably connected by pressing the connector terminal 8 through the multi-point contact material 11. . The connector terminals 8 and 8 are connected to the external electrodes 3 and 4 made of a metal thin film through the indium solder layers 9 and 9, or the connector terminals 8 and 8 themselves are melted to directly connect and fix each other. If it can, the nickel sheets 10 and 10 and the multipoint contact materials 11 and 11 become unnecessary.

[Lamp socket]

The lamp socket 7 is a mounting tool which supports the excimer lamp 1 and is connected to a high frequency high voltage power supply, and is attached to an ultraviolet irradiation device or the like not shown. As shown in Fig. 1, the lamp socket 7 is formed with a recessed socket portion 7a that is opened to the right. The socket portion 7a is a concave portion capable of inserting and supporting the connector portion 2b of the excimer lamp 1 together with the ceramic blocks 6, 6, and the like. The contact materials 13 and 13 (terminal contactor) are arrange | positioned.

These multi-point contact materials 13 and 13, like the multi-point contact materials 11 and 11, are contacted and pressed to the upper and lower surfaces so that a plurality of metal spring materials are pressed in a state of being in contact with these upper and lower surfaces. to be. The multi-point contact material 13 disposed on the upper surface of the inner side of the socket portion 7a contacts the upper ends of the plurality of spring materials to the lower surface of the terminal connecting plate 14 disposed at a slightly concave position from the upper surface thereof, thereby providing The lower end protrudes a little lower than the upper surface inside the socket part 7a, and is arrange | positioned. Moreover, the multi-point contact material 13 arrange | positioned at the lower surface inside the socket part 7a contacts the lower end of many spring materials to the upper surface of the terminal connection board 14 arrange | positioned at the position slightly concave from this lower surface, and these The upper end of the spring member is disposed to protrude slightly above the lower surface of the inner side of the socket portion 7a. And these terminal connection boards 14 and 14 are respectively connected to the high voltage terminal and the ground terminal of a high frequency high voltage power supply.

When the connector portion 2b at the left end of the excimer lamp 1 is inserted together with the ceramic blocks 6 and 6 into the socket portion 7a of the lamp socket 7 configured as described above, as shown in FIG. Likewise, this excimer lamp 1 is supported by the lamp socket 7. In addition, the excimer lamp 1 does not necessarily need to be supported only by this lamp socket 7. In the case of the excimer lamp 1 of the present embodiment, even if the front and rear widths are about 70 mm, the left and right lengths are extremely long, which may exceed 1000 mm. The right end part can also be supported by the other support material which is not shown in figure.

At the time of insertion into the socket portion 7a, the protrusions 8a and 8a of the connector terminals 8 and 8 projecting up and down from the holes of the ceramic blocks 6 and 6 are the upper surfaces of the inside of the socket portion 7a. And a plurality of spring members of the multi-point contact materials 13 and 13 disposed on the lower surface are pushed apart while being pushed upward and downward, respectively, and inserted into the socket portion 7a completely, these multi-point contact materials 13 and 13 Many spring materials of a stop are stopped at the pressure contact position.

Therefore, when the excimer lamp 1 is connected to the lamp socket 7, the external electrode 3 of the excimer lamp 1 is the indium solder layer 9 and the nickel sheet 10 on the upper side of the discharge tube 2. And a high voltage terminal of a high frequency high voltage power supply through the multipoint contact member 11 and the connector terminal 8 and through the multipoint contact member 13 and the terminal connecting plate 14 on the upper surface side inside the socket portion 7a. Is connected to. The external electrode 4 of the excimer lamp 1 has an indium solder layer 9, a nickel sheet 10, a multi-point contact material 11, and a connector terminal 8 below the discharge tube 2. Moreover, it is connected to the ground terminal of a high frequency high voltage power supply via the multipoint contact material 13 and the terminal connection board 14 of the lower surface side inside the socket part 7a.

[Effect of this embodiment]

According to the above-described configuration, the lamp socket 7 can support the connector portion 2b of the excimer lamp 1 with the socket portion 7a. In addition, the pair of multi-point contact materials 13 and 13 on the inner side of the socket portion 7a are pressed against the connector terminals 8 and 8 of the excimer lamp 1, so that the external electrode 3 of the excimer lamp 1 Since the high frequency high voltage power supply is connected to 4), this excimer lamp 1 can be discharged.

Moreover, since it is not necessary to connect the lead wire | coated with resin to the external electrodes 3 and 4 of the excimer lamp 1, decomposition gas generate | occur | produces by deterioration of resin by vacuum ultraviolet-ray, or the powdery substance by choking is irradiated. Falling on is prevented. That is, the excimer lamp 1 of this embodiment connects and fixes the nickel sheets 10 and 10 to the external electrodes 3 and 4 via the indium solder layers 9 and 9, and the nickel sheets 10 and 10 The connector terminals 8 and 8 are connected to each other via the multi-point contact materials 11 and 11, and the connector terminals 8 and 8 are pressed by the ceramic blocks 6 and 6, so that these metal or ceramic members are made. Even if vacuum ultraviolet rays are irradiated, there is no fear of deterioration. In the lamp socket 7 of the present embodiment, since the multi-point contact materials 13 and 13 and the terminal connecting plates 14 and 14 inside the socket portion 7a are made of metal, they may deteriorate even when irradiated with vacuum ultraviolet rays. There is no.

In particular, in the case of the present embodiment, since the excimer lamp 1 emits high-energy vacuum ultraviolet rays, deterioration becomes severe when the resin is used. Therefore, the structure consisting of only metal and ceramics is extremely effective.

In addition, in the case of this embodiment, since the excimer lamp 1 uses the square discharge tube 2, since a vacuum ultraviolet-ray can be irradiated directly to a to-be-tested object without penetrating a glass plate etc. below this discharge tube 2, The structure which does not generate cracked gas by deterioration and powdery matter by choking becomes extremely effective.

In addition, in the present embodiment, since the discharge space 2a does not exist inside the connector portion 2b of the discharge tube 2 held by the ceramic blocks 6 and 6, the ceramic blocks 6 and 6 are bolted. The discharge tube 2 is not broken by these pressures even if the connector terminals 8 and 8 are pressed from the top and the bottom through the multi-point contact materials 11 and 11, or clamped from the top and the bottom with (12, 12).

[Other Embodiments]

Incidentally, in the above embodiment, a case where xenon gas is used as the gas for discharging has been shown, but other rare gases capable of excimer light emission, halides thereof, or other substances may be used. Moreover, in the said Example, although the case where the vacuum ultraviolet-ray of wavelength 172nm was radiated was shown, since the wavelength of an ultraviolet-ray is determined by the substance used as a gas for discharge, it is not limited to wavelength 172nm, It is not limited also to vacuum ultraviolet-ray. Do not.

In addition, in the above embodiment, the left and right openings of the long rectangular body, made of synthetic quartz, are blocked by a rectangular synthetic quartz block, whereby a long rectangular discharge tube 2 is produced left and right. The manufacturing method of this discharge tube 2 is not limited to this. Here, the long rectangle right and left means a rectangle having a longer left and right length than the front and back width and the top and bottom height. In addition, as for the form here, the longitudinal cross-sectional shape by the cut surface along the front-back direction and the up-down direction may be substantially square, and a chamfer, rounding R, etc. may be sufficient as a corner part. In addition, as long as the upper surface and the lower surface are substantially flat surfaces, the front and rear side surfaces do not necessarily need to be flat surfaces, for example, they may be somewhat curved outward. In addition, some irregularities may be formed in the outer shape of the discharge tube 2 for suction / charge of gas, attachment of the excimer lamp 1, or the like.

In addition, in the said embodiment, although the excimer lamp 1 which used the rectangular discharge tube 2 of the elongate right and left was demonstrated, the shape of this discharge tube 2 is arbitrary, for example, the discharge tube 2 which consists of a cylindrical tube. It can be implemented similarly to the excimer lamp 1 using In the case where the discharge tube 2 is made of a cylindrical tube or the like, since the emitting surface of the ultraviolet light (lower flat surface in the above embodiment) does not become a flat surface, in order to purge oxygen or the like around the excimer lamp 1, You may arrange | position a glass plate etc. between the irradiated objects of. Even when the glass plate or the like is disposed in this way, when the decomposed gas or the powdered matter due to the choking occurs due to the deterioration of the resin, the external electrodes 3 and 4 are discolored or the surface or the glass plate of the discharge tube 2 is contaminated. The invention can solve this problem.

In addition, in the said Example, although the case where synthetic quartz was used for the discharge tube 2 was shown, if it is a material with high transmittance | permeability of the ultraviolet-ray radiating | emitted and there is little deterioration by this ultraviolet-ray, it is not necessarily limited only to synthetic quartz.

Moreover, in the said Example, although the case where the nickel sheet 10, 10 was connected and fixed to the surface of the external electrodes 3 and 4 of the connector part 2b via the indium solder layers 9 and 9 was shown, As long as it can reliably connect and fix the metal thin film of the external electrodes 3 and 4 or the nickel sheets 10 and 10 without any damage, it is not limited to the soldering material using indium, and other soldering materials or lead Connection fixation can also be carried out through a solder layer using a material.

Moreover, although the case where the nickel sheet 10 was used was shown in the said Example, if another metal sheet can be reliably connected without being cut off or peeled off by the spring material of the multi-point contact material 11, It is also possible to use, and is not limited to a metal sheet, a metal plate or the like may be used.

In addition, although the case where the ceramic blocks 6 and 6 were used was shown in the said Example, if it is sufficient rigidity and insulation and is not influenced by an ultraviolet-ray, the material is not limited only to ceramics, For example, synthetic quartz can also be used. In addition, in order to pressurize the connector terminals 8 and 8, it is not limited to the structure which clamps the connector part 2b of the discharge tube 2 with such ceramic blocks 6 and 6, For example, FIG. As shown in the figure, the cap-shaped ceramic block 6 made of ceramic may be inserted into the connector portion 2b of the discharge tube 2.

In addition, although the case where the nickel plated copper alloy was used for the connector terminals 8 and 8 was shown in the said Example, if it is made of metal with sufficient rigidity, the material and surface treatment of the connector terminals 8 and 8 It can carry out arbitrarily and a shape is not limited to the thing of the said Example, either.

In the above embodiment, the connector terminals 8 and 8 are made of a thin metal film through the multi-point contact materials 11 and 11, the nickel sheets 10 and 10, and the indium solder layers 9 and 9, respectively. And 4), the connector terminals 8 and 8 may be connected and fixed directly to the external electrodes 3 and 4 via the indium solder layers 9 and 9 and the like. 6 shows a configuration in which the connector terminals 8 and 8 are connected and fixed to the external electrodes 3 and 4 via the solder layer. In this case, the connector terminals 8 and 8 use a metal plate with a small heat capacity so that soldering by the indium solder layers 9 and 9 is easy.

In addition, when the block-type connector terminals 8 and 8 can be connected and fixed directly to the external electrodes 3 and 4 via the indium solder layers 9 and 9, for example, as shown in FIG. Similarly, these connector terminals 8 and 8 can be taken out to the position which covers a part of the left end surface of the discharge tube 2, and the inclined surface for a connection can be formed in the edge part of the left side of these connector terminals 8 and 8. . In this case, the lamp socket 7 is a ceramic material 16 disposed between the upper and lower metal terminal connection blocks 15 and 15 and the terminal connection blocks 15 and 15 for insulation, as shown in FIG. 7. ), And the socket portion 7a is made into a V-shaped recess (groove) opened to the right, and is inclined end faces of the terminal connection blocks 15 and 15 exposed to the upper and lower sides of the V-shaped recess. The multipoint contact materials 13 and 13 can also be arrange | positioned. In this case, for example, by arranging a supporting member (not shown) for pressing the excimer lamp 1 to the left end of the excimer lamp 1, the support member and the lamp socket 7 The excimer lamp 1 can be supported on both sides. Thereby, the inclined surface of the left end part of the connector terminals 8 and 8 of the excimer lamp 1 is made into the V-shaped recessed part of the socket part 7a of the lamp socket 7 via the multipoint contact material 13 and 13. Since it is press-contacted to the inclined end surface of the terminal connection block 15 and 15 which is exposed, it is reliably connected to a high frequency high voltage power supply.

In addition, in the above embodiment, the case where the external electrode 3 is a metal thin film uniformly formed, and the external electrode 4 is a metal thin film formed in a mesh pattern is shown. ) May be formed into any pattern. For example, both the external electrodes 3 and 4 may be metal thin films in which all of the external electrodes 3 and 4 are formed in a mesh pattern. If the ultraviolet rays can be emitted to the outside of the discharge tube 2, the external electrodes 3 and 4 on both sides may be used. All of these may be metal thin films uniformly formed. In addition, for example, in order to measure the intensity of the emitted ultraviolet rays, a part of the external electrode made of a metal thin film uniformly formed may have a window portion formed in a partially mesh-shaped pattern, and formed into a mesh-shaped pattern. A part of the external electrode made of the thin metal thin film may be uniformly formed (the external electrode 4 formed in the connector portion 2b is made of a metal thin film uniformly formed even in the above embodiment).

Further, in the above embodiment, the mesh grid pattern of the external electrode 4 becomes a square or a rectangle by orthogonally intersecting a plurality of thin metal thin films, but the pattern shape and size of the mesh pattern May be arbitrary. For example, an elongated metal thin film may not be orthogonal and a mesh grid may be a rhombus or a parallelogram, for example, a mesh grid may be a hexagonal honeycomb mesh. For example, it may be a comb-tooth type which arranged the several thin metal thin film in parallel.

In the above embodiment, the case where the external electrodes 3 and 4 are two layers of a metal thin film made of an aluminum vapor deposition film and a nickel deposition film to protect the surface thereof is shown. However, only one layer of the metal thin film or three or more metal thin films is shown. The metal material of each layer may also be selected, without being limited to aluminum or nickel. In addition, these external electrodes 3 and 4 may be metal thin films formed by methods such as sputtering other than vapor deposition, or may be formed by conductive films such as thick films other than metal thin films. In addition, these external electrodes 3 and 4 are not limited to what is arrange | positioned at the outer surface of the discharge tube 2 by film-forming, What is arrange | positioned by attaching metal foil to the outer surface of the discharge tube 2, and conductive materials, such as a metal plate, May be disposed on the outer surface of the discharge tube 2.

8 illustrates a case where the external electrodes 3 and 4 are made of a metal plate arranged on the outer surface of the discharge tube 2. In this case, the connector terminals 8 and 8 can be comprised by the part arrange | positioned at the outer surface of the connector part 2b of the discharge tube 2 in the external electrodes 3 and 4 which consist of these metal plates. When using the external electrodes 3 and 4 made of the metal plate in this way, for example, in order to make the external electrodes 4 into a mesh shape, a punched metal, an expanded metal, or the like may be used. However, even when such a punching metal, expanded metal, etc. are used, the part arrange | positioned on the outer surface of the connector part 2b of the discharge tube 2 is made into a normal metal plate, and this part is made into the connector terminal 8 It is preferable to set it as. Further, only the connector terminal 8 may be made of a metal plate, and the external electrode 4 made of a wire mesh may be connected by soldering or the like.

In addition, the external electrodes 3 and 4 are not disposed in the connector portion 2b of the discharge tube 2 in any case such as a metal thin film or a metal plate, but are made of a metal plate or the like disposed on the connector portion 2b. You may connect to the terminal 8 and 8 via metal lead materials, etc., respectively.

In the above embodiment, the case where the multi-point contact materials 13 and 13 are used as the terminal contact of the lamp socket 7 is shown. However, as shown in FIG. It can also be used as a terminal contactor. Also in this case, since the leaf springs 17 and 17 are pressed against the connector terminals 8 and 8 by elasticity, reliable connection can be performed. In addition, the terminal contact of the lamp socket 7 can also use the metal plate etc. which were pressed by the coil spring. However, these terminal contacts are pressurized to the connector terminals 8 and 8 according to the insertion when the connector portion 2b of the excimer lamp 1 is inserted into the socket portion 7a of the lamp socket 7. It is set as the structure which widens automatically.

In addition, when the connector terminals 8 and 8 are configured to press the multi-point contact materials 11 and 11 as in the above embodiment, the terminal contact of the lamp socket 7 may be a fixed metal plate, a metal block, or the like. In this case, when the connector terminals 8 and 8 are inserted between a pair of terminal contacts, the multi-point contact materials 11 and 11 are further pushed in and slightly inserted.

This application is based on the JP Patent application (application number 2008-242644) of an application on September 22, 2008, The content is taken in here as a reference.

[Industry availability]

Since the lead wire does not need to be used to connect the power supply to the external electrode of the excimer lamp, the resin coating of the lead wire does not deteriorate and is extremely useful when used as a light source lamp of an ultraviolet irradiation device.

1: excimer lamp 2: discharge tube
2a: discharge space 2b: connector portion
3: external electrode 4: external electrode
5: lead wire 5a: coating material
6: ceramics block 7: lamp socket
7a: socket 8: connector terminal
8a: protrusion 9: indium solder layer
10: nickel sheet 11: multi-point contact material
12: Bolt 13: Multi-point contact material
14: terminal connection board 15: terminal connection block
16: ceramic material 17: leaf spring

Claims (17)

A pair of external electrodes are arranged at different portions of the outer surface of the discharge tube in which the gas for discharge is enclosed in the internal discharge space, and a pair of connector terminals respectively connected to the pair of external electrodes is provided at the end of the discharge tube. An excimer lamp arrange | positioned in the different site | part on the outer surface side of the connector part provided in the back part. The method of claim 1,
The connector part is an excimer lamp which is an end portion on the left side or the right side of the discharge tube and in which no discharge space exists. The method according to claim 1 or 2,
The said discharge tube is a rectangular sealed container which is long in right and left, and has the flat surface upper and lower, and an excimer lamp which arrange | positioned the said pair of external electrodes in the upper and lower flat surfaces of the said discharge tube, respectively. The method according to claim 1 or 2,
Each said external electrode consists of a metal thin film formed in the outer surface of the said discharge tube, The excimer lamp. The method according to claim 1 or 2,
Each said external electrode consists of a metal plate arrange | positioned at the outer surface of the said discharge tube. The method of claim 5,
Each said connector terminal consists of the part arrange | positioned at the outer surface of the connector part of the said discharge tube in the said external electrode. The method according to claim 1 or 2,
Each said connector terminal is an excimer lamp | ramp which is a block-type terminal pressed by the multipoint contact material in the part formed in the outer surface of the connector part of the said discharge tube in the said external electrode. The method according to claim 1 or 2,
Each said connector terminal consists of a metal plate connected and fixed to the part formed in the outer surface of the connector part of the said discharge tube in the said external electrode through the solder layer. The method according to claim 1 or 2,
Each said connector terminal is an excimer lamp which is a block-type terminal pressurized through the said multi-point contact material to the metal sheet connected and fixed by the solder layer to the part formed in the outer surface of the connector part of the said discharge tube in the said external electrode. The method of claim 7, wherein
Each of the block-type connector terminals is pressurized by a pair of ceramic blocks sandwiching and fixing the connector portions of the discharge tube from both sides. The method according to claim 1 or 2,
And the excimer lamp emits vacuum ultraviolet rays. The method according to claim 1 or 2,
Each said connector terminal is a block type terminal provided in the part formed in the outer surface of the connector part of the discharge tube in the said external electrode. The ultraviolet irradiation device containing the excimer lamp of Claim 1 or 2. The excimer lamp according to claim 1 and a socket portion for inserting and supporting the connector portion of the excimer lamp are provided, and the position of the excimer lamp is positioned inside the socket portion and in contact with the pair of connector terminals in the inserted connector portion. An excimer lamp unit comprising lamp sockets each having a pair of terminal contacts connected to a power supply. The method of claim 14,
Each of said terminal contacts being made of a multi-point contact material. The method of claim 14,
Each said terminal contactor consists of a metal leaf spring. The ultraviolet irradiation device containing the excimer lamp unit in any one of Claims 14-16.

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