KR101066078B1 - Deuterium lamp housing - Google Patents

Abstract

The deuterium lamp housing of the present invention is excellent in heat dissipation and sealing properties, and is advantageous for aligning a cylindrical quartz tube lamp in the center of the center, and provides a structure in which a focus lens is easily installed on the housing lid. In the housing of the deuterium lamp which is provided with the light emitting part 2 in the inside of the tube 1, and the inside of the quartz tube 1 is sealed with deuterium gas, The housing which has the lamp storage part 26 in which the said deuterium lamp is integrated is provided. A rubber packing part including a main body 21 and a housing lid 27 for sealing the lamp storage part 26 of the housing main body 21, the recessed groove of a closed curve elongated at a portion where the housing main body and the housing lid abut. (23) is formed and a packing ring having a height slightly larger than the depth of the groove of the rubber packing part 23 is inserted into the rubber packing part 23, and then the housing body and the housing lid are fastened. It is characterized in that the fastening by means.

Deuterium lamp, housing, pinch section, flat type.

Description

Deuterium lamp housing

The present invention relates to a deuterium lamp housing, and more particularly, to a deuterium lamp housing having excellent heat dissipation and sealing properties and easy replacement of a focus lens.

In general, deuterium lamps are light sources that calibrate and measure background effects caused by molecular absorption or light scattering, and are non-charged discharge lamps that emit a strong continuous spectrum from approximately 190 nm to 425 nm. This complements where most of the atomic absorption occurs and where the background absorption effect occurs. Deuterium gas (D2) is used as a light source of an analyzer such as a spectrophotometer because the continuous spectrum is generated rather than the line spectrum.

Deuterium lamps consist of an arc aperture between two cathodes (filament, cathode) and a metal anode (Anode) that emits heated electrons. A discharge current of several hundred mA excites the D2 gas. The discharge passes through small arc holes, forms a restricted area in a high excited state, and emits high wavelength light.

On the other hand, the inside of the deuterium lamp must be maintained at a low pressure state of about 1/100 atmosphere, and has a characteristic that is sensitive to the influence of external temperature changes. That is, due to excessive cooling or overheating, it is difficult to obtain stable output characteristics of the deuterium lamp and the lamp life may be shortened. That is, when used indoors or outdoors, there is a need to use a lamp housing so as not to be affected by the surrounding environment such as changes in weather.

7 is an overall perspective view of a deuterium lamp according to the prior art, Figure 8 is an exploded perspective view of the light emitting portion of the deuterium lamp according to the prior art.

As shown in the figure, the light emitting portion 102 is housed inside the cylindrical quartz tube 101 made of glass, and deuterium gas (not shown) is sealed for several Torr. In addition, the stem made of glass is formed in the bottom part of the container 101, and the lead wire 104 flows outside. The quartz tube 101 is formed of ultraviolet ray transmitting glass, quartz glass, or the like having a good ultraviolet ray transmittance.

Four lead wires 104 are fixed to the stem in parallel in a straight line, and each lead wire 104 penetrates the stem and is covered with an insulating material, respectively, and is led out as a lead wire to an external power source (not shown). Connected.

In addition, the light emitting part 102 is located in the front outer plate 111 made of metal (Ni or SUS) or ceramic, the cylindrical intermediate plate 112 disposed in the rear part, and one side in the front plate. But it includes a side plate 116 located outside the rear plate. In addition, as shown in FIG. 7 and FIG. 8, the metal anode 106 is fixed to the tip of the lead wire 104 while being supported by the anode support 108 at the tip of the lead wire 104. In addition, an arc hole 107 extending in a direction orthogonal to the tube axis is formed, and the light transmitting hole 112a concentric with this is also formed in the intermediate plate 112. Therefore, the emitted light can be projected to the outside by the arc hole 107 and the light transmitting hole.

In addition, the back surface of the anode 106 is contact-supported to the anode support 108, and the anode support 108 is integrally formed of a ceramic having electrical insulation and high thermal conductivity. Therefore, the anode support 108 acts as a heat sink with respect to the anode 106 which has become a high temperature, and can efficiently dissipate heat accumulated in the light emitting portion 102 to the outside with good efficiency.

The front outer plate 111 is fixed to the front surface in a substantially U-shaped cross section. In the center of the front outer plate 111, an opening window 111a for ultraviolet light transmission is formed, which is opposed to the arc hole 107 and the light transmitting hole 112a. Therefore, by arranging the arc hole 107, the light transmitting hole 112a, and the opening window 111a in a row, the light projected from the light emitting part 102 is emitted to the opening window. In the space formed by the front outer plate 111, the cathode 105 of the helical filament for generating hot electrons is disposed, and the cathode 105 is located off the optical path, that is, the side in the front outer plate 111. It is arranged in the direction. The negative electrode 105 is supported by the negative electrode support 115, and the negative electrode support 115 is insulated by the insulating tube 110. The upper and lower portions of the cylindrical intermediate plate 112 are sealed with the upper plate 113 and the lower plate 114.

Referring to the above operation of the deuterium lamp, first, the electric power of about 10 W is supplied to the cathode 105 from an external power source (not shown) for about 20 seconds before discharge, and the cathode 105 is preheated. Thereafter, a DC opening voltage of about 150V is applied between the cathode 105 and the anode 106 to prepare for arc discharge.

After the preparation, a trigger voltage of 350 to 500 V is applied between the cathode 105 and the anode 106. At this time, the hot electrons emitted from the cathode 105 pass through the slit 116a of the side plate 116 to reach the anode 106. After the arc discharge is generated in front of the arc hole 107 and the ultraviolet rays extracted from the arc ball by the arc discharge pass through the opening window 111a, the peripheral surface of the glass quartz tube 101 is made. It penetrates and is released to the outside. At this time, the anode 106 and the intermediate plate 112 are at a high temperature exceeding several hundred degrees Celsius, and the heat is continuously and properly discharged to the outside by the anode support 108 made of ceramic or the like.

These deuterium lamps are mainly used as the reference light source of the optical measuring analyzer, and the optical measuring analyzer depends on the interference gas and the time variation of the light source, and the reliability of the result depends on the UV (200-400 nm) band. In separating the gas-based absorption difference, the solution is solved by applying statistical mathematical theory.

In addition, since the UV light characteristic of the deuterium lamp is sensitive to the ambient temperature, it is preferable to keep it in a separate lamp housing because it is always maintained at a constant temperature. In this case, the surface temperature of the deuterium lamp reaches several hundred degrees Celsius. For this reason, special heat dissipation measures are required for the housing, and special sealing alternatives are required for outdoor use.

A first object of the present invention is to provide a deuterium lamp housing having excellent heat dissipation and sealing properties in order to improve the above conventional problems.

Further, a second object of the present invention is to provide a structure that is advantageous for aligning a cylindrical quartz tube lamp in the center of the center, and is easy to install a focus lens on the housing lid.

Further objects and effects of the present invention will become more apparent from the following detailed description of the invention.

Deuterium lamp housing according to an aspect of the present invention, in order to achieve the object of the invention described above, is provided with a light emitting portion (2) inside the cylindrical quartz tube (1), the inside of the quartz tube (1) is deuterium gas A sealed deuterium lamp housing, comprising: a housing main body 21 having a lamp reservoir 26 in which the deuterium lamp is embedded, and a housing lid for sealing the lamp reservoir 26 of the housing main body 21; 27), wherein the housing body and the housing lid is formed in the grooves of the closed curved elongated groove to form a rubber packing portion 23, and has a height slightly larger than the depth of the groove of the rubber packing portion 23 After the packing ring is inserted into the rubber packing part 23, the housing body and the housing lid are fastened by fastening means.

Preferably, the housing main body 21 is formed with one or more lead wire connection portions 25 in a through shape, and unused through holes are sealed with a lead wire connection plug 25, and the number of lead wires is provided in the through hole portion where the lead wires extend. Sealed with a small diameter grooved rubber packing disk 34, the rubber packing disk 34 is characterized in that the fixing using the packing fixture 35,

More preferably, at least one surface of the housing body 21, characterized in that to form a heat dissipation unit 22 having a plurality of wing-shaped heat dissipation fins,

Most preferably, the wing direction of the heat radiation fin of the heat dissipation portion 22 is characterized in that the same direction as the flow of the outside air.

Deuterium lamp housing according to another aspect of the present invention, in order to achieve the object of the present invention, has a light emitting portion (2) inside the cylindrical quartz tube (1), the inside of the quartz tube (1) is deuterium gas A sealed deuterium lamp housing, comprising: a housing main body 21 having a lamp reservoir 26 in which the deuterium lamp is embedded, and a housing lid for sealing the lamp reservoir 26 of the housing main body 21; Including the 27, the housing lid 27 is fixed to the lamp support portion 28 integrally formed with the lid 27, bar-shaped quartz tube inside the wide ring-shaped lamp support 28 It is characterized in that it is configured to facilitate the alignment of the quartz tube of the cylindrical shape by the lamp support portion 28 so that the stamp is formed.

Preferably, the housing lid 27 has a condenser lens portion 29 formed therein, the UV light output and intensity of the deuterium lamp in the inner through hole of the flange-shaped condensing lens portion 29 having a through hole A focus lens 30 is installed to increase the focus lens, and the focus lens is fastened to the condenser lens unit 29 by the lens holder 31.

Also preferably, the light emitting part 2 may include a cathode 5 and an anode 6 for discharging, a back plate 9 for supporting the intermediate plate 12 and an anode, and a front plate through which light is emitted ( 11) and an arc hole (7), wherein the back plate (9) is a flat plate of the "C" shape, characterized in that the intermediate plate 12 forming a closed space with the back plate is also a flat plate,

Also preferably, the light emitting part 2 may include a cathode 5 and an anode 6 for discharging, a back plate 9 for supporting the intermediate plate 12 and an anode, and a front plate through which light is emitted ( 11) and an arc hole (7), characterized in that the pinch portion (3) surrounding the lead wire (4) is further provided.

Above, according to the deuterium lamp housing according to the present invention, it is excellent in heat dissipation and sealing properties, advantageous in aligning the quartz tube lamp in the center, and has various advantages in that it is easy to install a focus lens on the housing lid.

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

First, the deuterium lamp according to the present invention will be described in detail with reference to FIGS. 1 to 4.

1 is an overall perspective view and a front view of a deuterium lamp according to the present invention, Figure 2 is an exploded perspective view of the light emitting portion of the deuterium lamp according to the present invention, Figure 3 is a partially assembled perspective view of the light emitting portion of the deuterium lamp according to the present invention, Figure 4 is a plan sectional view of a light emitting portion of a deuterium lamp according to the present invention.

First, as shown in (a) of FIG. 1, the light emitting part 2, the pinch part 3, and the lead wire 4 are provided in the quartz tube 1 having a cylindrical shape. It is sealed with several torr of deuterium gas. An arc hole 7 is located in front of the light emitting portion 2 (see FIG. 1B).

The intensity and amount of ultraviolet light emitted vary depending on the material of the quartz tube. Generally, high purity quartz glass (borosilicate) UV glass is used a lot, and synthetic silica or magnesium fluoride (MgF ₂ ) glass is also used. In addition, since transmittance depends on the thickness of a quartz tube, it is preferable to use 1 mm or less normally.

As shown in FIG. 2, the above-described light emitting part 2 includes a cathode (filament, Cathode) 5, an anode 6, an arc hole 7, an intermediate plate 12, and a back plate (anode support part). 9), the front plate 11 and the like.

The positive electrode 6 is supported by being in contact with the positive electrode support 8 of the rear plate 9 corresponding to the anode support of the rear side, the rear plate 9 is a material having excellent electrical insulation and thermal conductivity of the "c" shape, namely , Ceramics, nickel, molybdenum, etc. When the electrons are emitted, a very high temperature of several hundred degrees Celsius is generated inside the lamp, thus acting as a heat sink for the anode to stabilize the light output and also increase the efficiency. The backplane also plays an important role in controlling the discharge voltage.

Since the anode support 8 is a high temperature of more than a few hundred degrees Celsius, molybdenum and KOVAR materials are used. Also, ceramic or quartz tubes were inserted into the anode support to maintain insulation from other adjacent leads.

In the deuterium lamp of the present invention, a quartz tube was used rather than a ceramic tube. This is because quartz tubes are advantageous in terms of price, and in particular, high purity quartz tubes are used because the moisture content is less than 1 ppm and the purity is very high. This reduces the impurities inside the lamp and can produce good UV light.

Next, the cathode 5 (filament, Cathode) is a section which is a source for emitting UV light as a part for emitting hot electrons. It is spiral shaped and made of tungsten coated with barium, strontium and calcium oxide. The filament voltage is usually around 2-12V. The material of the cathode support is made of molybdenum, which is solid and has excellent temperature characteristics.

The arc aperture 7 is then concave (dimpled in shape) and UV light is emitted through the arc aperture. UV intensity depends on the diameter of the arc hole. In the deuterium lamp of the present invention, it was found that the most efficient when the diameter of about 0.5mm ~ 1.0mm. In addition, to obtain high UV intensity, it must be located in front of the anode. The material of the arc hole should be made of molybdenum with excellent temperature characteristics.

In addition, the intermediate plate 12, the front plate 11, the back plate 9, the side plate 16 will be described, it is necessary for the smooth assembly of the cathode 5 and the light emitting portion (2). In particular, the intermediate plate 12 is useful for facilitating the coupling between the negative electrode support 15 and the pinch portion (3). In addition, the front plate 11 and the rear plate 9 is in a rectangular shape in the unfolded state, and when assembled, it is easy to process the material because it is made of 'c' shape, and also the flange portion which is the portion where both plates meet and are joined together is flat. Therefore, the assembly work of the light emitting portion 2 brings about an easy effect. It is preferable to use a high purity nickel material.

The side plate 16 is located perpendicular to the intermediate plate 12, and the hot electrons emitted from the cathode (filament), the light transmitting hole 12a of the intermediate plate 12 and the slit 16a of the side plate 16 It is rectified through and finally emits UV light through the opening (11a) of the front plate 11 through the arc hole (7).

In particular, in the deuterium lamp according to the present invention, since the pinch portion 3 is provided, the conventional technique does not adopt the pinch method and uses a mold method for fixing each lead so that the arc cannot be aligned at the correct position. There was a problem that UV light was not accurately emitted through the hole. In the deuterium lamp according to the present invention, by using the pinch method, each lead alignment can be precisely and firmly supported, which is stable. For each lead wire, use molybdenum or coba material that is strong and has excellent temperature characteristics. In the deuterium lamp related to the present invention, molybdenum material was applied in consideration of cost.

Unexplained reference numerals 10, 13, and 14 denote the upper and lower plates of the insulating tube, the rear plate, respectively.

The upper plate 13 and the lower plate 14 can be easily assembled due to the upper and lower flange portions 9a of the rear plate.

In addition, the back plate 9 and the front plate 11 in the deuterium lamp according to the present invention are provided with flange portions 9b and 11b in the form of flat plates at the portions to be welded, and further, above and below the rear plate 9. The flange portion 9a of the flat plate is also provided at the welding portion with the plates 13 and 14.

Hereinafter, the operation of the deuterium lamp according to the present invention will be described.

As shown in FIG. 4, when an ignition voltage of several hundred volts (approximately 300 to 600 V) is applied between the cathode 5 and the anode 6, hot electrons are emitted from the cathode 5 and discharge of several hundred mA. The electric current is turned on by exciting the deuterium gas and emitting UV light through the arc hole 7. This ultraviolet light penetrates the cylindrical quartz tube 1 and is emitted to the outside.

In general, about 10 to 15 minutes after the power supply to the discharge to reach the thermal equilibrium state. Therefore, a warm-up time of at least 20-30 minutes is required. In addition, in order to maintain the stability of the lamp light output, a constant power type power supply (Power supply) is required, and above all, the role of the cathode and the anode is important.

In addition, looking at the assembly process of the deuterium lamp related to the present invention with reference to Figures 3 and 4, since the intermediate plate 12 is not made of a cylindrical shape (plate), it is easy to work and reduce material costs Of course, the negative electrode 5 is placed inside the space consisting of the intermediate plate 12, and it is easy to align the negative electrode in the center, and the negative electrode and the negative electrode support contact the surface of the intermediate plate 12. There is no fear of electrical short-circuit, and the upper and lower flanges 9a of the rear plate facilitate assembly of the upper plate 13 and the lower plate 14.

In addition, in the deuterium lamp according to the present invention, since the pinch portion 4 pinches a plurality of lead wires 4 simultaneously, no molding work is required, and the alignment of each lead wire 4 is easily performed, and therefore, properly. UV light output can be produced.

In addition, in the case of the deuterium lamp according to the present invention, the external front plate 11 and the rear plate 9 in the form of the 'c' shape, easy to work and maintain the exact shape, and at the same time, the back plate ( 9) and the front plate 11 are welded, but the flanges 9b and 11b of the front and rear face plates are all flat, so welding is easy.

The deuterium lamp housing according to the present invention will now be described in detail with reference to FIGS. 5 and 6.

5 is an exploded perspective view of the deuterium lamp housing according to the present invention, and FIG. 6 is a perspective view of an assembled state of the deuterium lamp housing according to the present invention.

5 and 6, the lamp housing of the present invention is separated into a housing body 21 having a lamp reservoir 26 and a housing lid 27. First, the lamp housing of the present invention is used outdoors. In order to increase the sealability, the rubber packing ring 23 is formed with a long closed groove in a portion where the housing body and the housing lid are in contact with each other, and a rubber packing ring having a height slightly larger than the depth of the groove in the rubber packing part ( (Not shown) is inserted into the rubber packing part 23, and then the bolt 32 and the nut 33 are fastened.

In addition, among the through holes of the two or more lead wire connection portions 25, unused through holes are sealed with a lead wire connection plug 25, and the rubber packing disc 34 having a small diameter groove as many as the number of lead wires is provided in the through hole through which the lead wires extend. Sealed using, but the rubber packing disc 34 is fixed to the lead wire connection using the packing fixture 35 again.

On the other hand, in order to solve the problem of heat dissipation resulting from the complete sealing in this way, the heat dissipation portion 22 was configured in the shape of several wings. In other words, by making the shape of a wing, the surface area becomes wide so that the heat dissipation area increases by that much. Furthermore, the heat dissipation wing direction is designed to be in the same direction as the flow of external air (that is, in the vertical direction) to maximize the heat dissipation effect.

In addition, the lamp support part 28 is fixedly formed in the housing lid 27 of the lamp housing of the present invention integrally with the lid 27, and the quartz of cylindrical shape is formed inside the lamp support part 28 having a wide ring shape. Allow the stamp of the tube to form.

Therefore, the lamp support portion 28 is configured to facilitate alignment of the cylindrical quartz tube in the center of the housing.

Finally, the condenser lens portion 29 is formed in the lid 27 of the housing of the present invention, and the inner light aperture of the flange-shaped condenser lens portion 29 having a circular through hole is provided with UV light output of a deuterium lamp. The focus lens 30 is installed to increase the intensity, and the focus lens is fastened to the condenser lens unit 29 by the lens holder 31. By forming the condenser lens unit in this way, it is configured to increase the UV light output and intensity and to facilitate replacement when the focus lens is contaminated.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 is an overall perspective view and a front view of a deuterium lamp according to the present invention.

Figure 2 is an exploded perspective view of the light emitting portion of the deuterium lamp according to the present invention.

Figure 3 is a partially assembled perspective view of the light emitting portion of the deuterium lamp according to the present invention.

Figure 4 is a plan sectional view of the light emitting portion of the deuterium lamp according to the present invention.

5 is an exploded perspective view of the deuterium lamp housing according to the present invention.

Figure 6 is a perspective view of the assembled state of the deuterium lamp housing according to the present invention.

7 is an overall perspective view of a deuterium lamp according to the prior art.

Figure 8 is an exploded perspective view of the light emitting portion of the deuterium lamp according to the prior art.

<Description of Symbols for Main Parts of Drawings>

1: quartz tube 2: light emitting part

3: pinch part 4: lead wire

5: cathode filament 6: anode

7: arc hole 8: anode support

9: back plate 10: insulated tube

11: front panel 12: intermediate panel

13: top 14: bottom

15: cathode support 16: side plate

9a, 9b: rear plate flange 11a: opening window

11b: flange 12a: light transmitting hole

16a: slit

21: housing body 22: heat dissipation unit

23: rubber seal 24: lead wire connection

25: lead wire connecting plug 26: lamp storage

27: housing lid 28: lamp support

29: condensing lens unit 30: lens

31: lens holder 32: bolt

33: Nut 34: Packing Disc

35: Packing fixture

Claims (8)

In the quartz tube 1 of the cylindrical shape is provided with a light emitting portion 2, the inside of the quartz tube 1 is a housing of a deuterium lamp sealed with deuterium gas, A housing main body 21 having a lamp storage unit 26 in which the deuterium lamp is embedded; It includes a housing lid 27 for sealing the lamp reservoir 26 of the housing body 21, A rubber packing part 23 is formed as a recess in a closed curve in a portion where the housing body and the housing lid are in contact with each other. After inserting the packing ring having a height greater than the depth of the groove of the rubber packing portion 23 into the rubber packing portion 23, Fastening the housing body and the housing lid with a fastening means, The light emitting part 2 includes a cathode 5 and an anode 6 for discharging, a back plate 9 for supporting the intermediate plate 12 and an anode, a front plate 11 and an arc hole from which light is emitted. (7), Deuterium lamp housing, characterized in that the pinch portion (3) surrounding the lead wire (4) is further provided. The method of claim 1, One or more lead wire connecting portions 25 are formed in the housing main body 21, and unused through holes are sealed with a lead wire connecting plug 25, and through holes through which the lead wires extend are provided with the number of grooves. Sealed with a rubber packing disk (34), deuterium lamp housing, characterized in that the rubber packing disk (34) is fixed using a packing fixture (35). The method according to claim 1 or 2, Deuterium lamp housing, characterized in that the at least one surface of the housing main body 21, forming a heat dissipation portion 22 having a plurality of wing-shaped heat dissipation fins. The method of claim 3, wherein Deuterium lamp housing, characterized in that the wing direction of the heat radiation fin of the heat dissipation portion 22 to be in the same direction as the flow of external air. delete delete The method according to claim 1 or 2, The light emitting portion 2, Including a negative electrode (5) and a positive electrode (6), the intermediate plate 12 and the back plate (9) for supporting the anode and the front plate 11 and the arc hole (7) from which light is discharged, The back plate 9 is a flat plate of "ㄷ" shape, Deuterium lamp housing, characterized in that the intermediate plate (12) forming a closed space with the back plate. delete

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