KR200255073Y1 - UV lamp tube for ozone generation with removable cap - Google Patents

Abstract

The present invention is an improvement on the UV lamp tube and the cap for sealing the water applied in the field of water purification, by threading each of the UV lamp tube (1) and the cap (2) by screwing each other or simply by a cicada hook By sealing the end of the lamp tube, it is easy to open and close the cap from the lamp tube to facilitate the replacement of the UV lamp, and by inserting a perforated net inside the cap to prevent damage and deformation from external force and internal pressure It provides a structure that enhances heat resistance, and also ozone generating means for ozoneizing oxygen, fluid aeration means for mixing ozonized air with fluid flowing through a water supply pipe, and UV ultraviolet ray for improving sterilizing power by irradiating UV ultraviolet rays. It provides UV lamp tube with integrated irradiation means.

Description

UV lamp tube for ozone generation with detachable cap

The present invention activates the water quality by the high concentration of ozone water generated by supplying compressed air ozone (O ₃ ) by ultraviolet radiation to the water flowing into the public facilities such as small water purifiers, swimming pools, water tanks, etc. The present invention relates to an improved UV lamp tube installed in an ozone generator.

In general, the UV lamp tube is installed between the static pressure compressor that compresses air at a constant pressure and the fluid mixing expanse pipe that increases the dissolved amount of oxygen, and the UV lamp at a pressure of about 1.3 to 5 kg / cm2 through the line of the constant pressure compressor. By irradiating compressed air flowing into the pipe with ultraviolet rays generated by UV lamps, it increases ozone (O ₃ ) oxygen concentrations in the air and increases sterilization power. It is widely used in the field of water purification.

Conventionally, the utility model registration No. 128115 registered by the present applicant for the structure of such a UV lamp tube has been presented. That is, as shown in Fig. 1, the structure is provided with shock absorbing holes in which springs 55 ₁ to 56 ₃ are mounted at both ends of the UV lamp tube so that the UV lamp 52 housed in the UV lamp tube 51 is not damaged. (54) are provided, respectively, and both ends of the lamp are inserted into the openings formed in the center of the buffer port 54 to prevent fluidity of the lamp, and a power line connected to the UV lamp is connected to the cap 53. Connected to the UV lamp lighting lamp which is drawn out through the tip and positioned outside the UV lamp tube, the both ends of the tube are sealed by the cap 53 to prevent leakage of fluid flowing into the tube, and the UV lamp blinks. The optical fiber 57 is inserted into the upper portion of the UV lamp tube so that it can be visually checked from the outside. Reference numerals 58 ₁ , 58 ₂ are the backing rubber, 59 is the compression ring, 60 is the elbow pipe connected to the constant pressure compressor. In this case, the cap is coated with an adhesive therein to be firmly combined with the UV lamp tube, and the UV lamp tube and the cap are generally chlorinated polyvinyl chloride resin (CPVC) in consideration of the adhesive strength and heat resistance of the adhesive material. ) Material was used.

Furthermore, in the related art, in order to mix air ozonated by UV lamp with water by using such UV lamp tube, the following three types are generally used according to the structure of the fluid mixing aerator installed in the water tank or in the fluid transport conduit or the main transport pipe. I'm using the method.

1. Method of mixing ozonized air and water from UV lamp tube by operating propeller charged in the lower part of water tank where water is stored.

2.The method of floating ozone mixed with water by injecting ozonized air at high pressure through a plurality of minute holes formed in the bottom of the water tank where water is stored.

3. Ozonated air is introduced through the gaps between the small particles filled in the water tank so that it floats up in the water to prolong the time that the ozoneized air comes into contact with the water, thereby increasing the oxygen dissolved capacity and sterilizing power of the water.

In this process, however, if the abnormal operation of the UV lamp is detected through the optical fiber 57 stored in the lamp tube during the operation of the UV lamp tube, the UV lamp is stored even if the need for repair or replacement of the UV lamp is recognized. Since the lamp tube and the cap of the CPVC material are sealed with adhesive, the UV lamp tube cannot be separated, resulting in economic inefficiency to replace the entire expensive lamp tube.

In addition, the appearance of the UV lamp tube made of CPVC is deformed due to the pressure (0.1 to 5 kg / ㎠) applied to the UV lamp tube by the heat emitted from the UV lamp and the air flowing into or out of the UV lamp tube. There was.

In addition, the UV lamp tube for ozoneizing the air and the aeration device for mixing ozonated air and water are separated from each other, resulting in a large volume of the device and a large amount of space. Since each device is installed, there was a problem in the cost of manufacturing a small sterilizing water purifier and a high concentration ozone water maker.

Therefore, the general purpose of the present invention is to easily open and close the cap from the UV lamp tube in order to solve the above-mentioned problems, and to improve the heat resistance of the cap and to be installed easily in narrow places and the ozone generating means and fluid It is to provide a structure having an aeration unit integrally.

The first object of the present invention is to easily check or replace the UV lamp or lighting lamp in the case of visual confirmation that the UV lamp is flashing through the optical fiber, and furthermore, it has heat resistance and high strength which can be more resistant to external shock or heat. Eggplant is to provide a UV lamp tube and a cap that is screwed or cicada fastened to the UV lamp tube.

In addition, a second object of the present invention is to provide a compact UV lamp tube which is integrally provided with a means for uniformly mixing ozonated compressed air with water and then sterilizing with ultraviolet rays.

1 is an installation state diagram of a lamp tube according to a conventional method.

Figure 2 is a state diagram used in accordance with the first embodiment of the present invention.

3 is a view showing the structure of a cap (cap) sealed to the UV lamp tube shown in FIG.

4 is a perforated network inserted into the cap in FIG.

Figure 5 is a cicada hook type connection state of the cap and the UV lamp tube.

6 is a cross-sectional view of the inside of the UV lamp tube according to the second embodiment of the present invention.

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

2 and 3, the configuration according to the first embodiment of the present invention is similar to the structure of the UV lamp tube shown in Fig. 1, and the UV lamp is installed in the UV lamp tube 1, and this UV The end of the lamp is held in the buffer port and the UV lamp tube 1 is sealed with the cap 2, and the female screw is provided inside the cylindrical cap 2 so that the UV lamp tube 1 can be sealed by screwing. Is formed, and correspondingly, male screws are formed outside the both ends of the UV lamp tube 1. The cap 2 is made of a heat resistant resin such as polycarbonate so as not to be deformed by heat generated from a UV lamp or an external machine.

In addition, when forming the cap to prevent deformation of the cap 2 which may be caused by heat or externally or internally applied pressure, a metal is formed between the outer surface 2 ₁ and the inner surface 2 ₂ of the cap 2. Install the perforated network (3) manufactured by. As shown in Fig. 4, the perforated network 3 has a shape in which a plurality of holes 4 are drilled in a cylindrical metal tube. At this time, if the size of the hole formed in the perforated network 3 is too small, the flow of resin may not be smooth when the cap 2 is molded, and thus the resin may not be filled in the hole 4, resulting in pin-holes. It may be formed. In addition, if the size of the hole is excessively large, the shrinkage of the resin in the area where the hole 4 is in the process of condensation of the liquid resin is larger than that without the hole, so that the hole 4 of the perforated network 3 is present. The part may become concave. The hole 4 of the perforated network 3 may be formed in polygonal shape instead of spherical shape. However, when forming the cap 2, in order to prevent the uniform flow of resin and defects such as pinholes in the cap 2, it is preferable to form holes with a spherical diameter of about 10 mm.

As the means for fastening the UV lamp tube 1 and the cap 2, a means for screwing by a male screw and a female screw respectively formed on the UV lamp tube 1 and the cap 2 as described above may be used. As shown in Fig. 5, a fastening means such as a cicada hook may be used. When the UV lamp tube 1 and the cap 2 are combined by screwing, the cap must be rotated. In this case, the UV lamp power wire drawn out to the outside through the hole formed at the tip of the cap is twisted together. There are disadvantages. Therefore, in order to compensate for these disadvantages, a conventional fastening part 5 having a ring-shaped fastening piece 6 formed on the outside of the UV lamp tube 1 is attached and bent in a c-shape on the outer circumference of the cap 2. Insert the metal ring (8) in which the hook (7) is formed integrally, so that the fastening piece (6) is caught by the hook (7) in a cicada hook method when the UV lamp tube (1) and the cap (2) are fastened. Thus, the UV lamp tube 1 and the cap 2 can be firmly fixed. At this time, a protruding edge portion 9 is formed around the distal end of the cap 2 so that the metal ring 8 is not detached from the cap 2 so that the metal ring 8 is fixed at the position of the protruding edge portion 9. The pressing ring is inserted into the inner end of the cap 2. The fastening part 5 and the ring 7 may be installed at least two outside the UV lamp tube 1 and the cap (2), respectively.

As the material of the UV lamp tube 1, a metal material was used to easily form a male thread or attach a cicada hook to the outside. Then, the UV lamp tube (1) is a control box in which the heat generated from the UV lamp is discharged to the outside through the UV lamp tube (1) when the built-in UV lamp is turned on (the UV lamp tube (1) is housed) In order to prevent the machine from overheating, such as a control box, the inner surface of the UV lamp tube 1 may be thermally treated by coating an insulating material such as TEMP-COAT (trade name). The outer surface of the lamp tube may be subjected to a surface treatment such as a coating using a fluorine resin such as Teflon in order to prevent corrosion of the UV lamp tube 1.

Now, a second embodiment of the present invention will be described with reference to FIG.

Unlike the first embodiment described above, the UV lamp tube according to the second embodiment of the present invention has ozone generating means such as a UV lamp that generates ozone by UV discharge, and ozonated air discharged from the ozone generating means. It adopts a structure in which fluid aeration means for maximizing dissolved oxygen and sterilization power by mixing the fluids introduced through the water supply pipe are integrated. The lamp tube main body 11 ', mainly in the center of the lamp tube main body, Built-in quartz tube 14. The UV inlet 13, which is held in the quartz tube 14 and held by the buffer port 29 having the structure as shown in Fig. 1, is formed at the upper and lower ends of one side wall of the lamp tube body 11 '. Separator 22 and separator 22 disposed between the fluid outlet 21, the fluid inlet 20, and the fluid outlet 21 to define the upper and lower spaces 30, 31. It is installed in the lower space below the separator 24 and the polyhedron 24 to evenly mix the ozonized air with water filled in the upper space 30 of the one end portion to support the bottom edge of the separator 22 And the other end is inserted into the groove 32 formed at the end in the tube body and is supported in a double slide manner, the plurality of spring wound T-shaped elastic supports 25 and the first and second sealing the components It consists of the caps 12 ₁ and 12 ₂ (15 ₁ and 15 ₂ ).

The separator 22 has an opening formed at its central portion so that the quartz tube 14 can be inserted through the opening when the quartz tube 14 is accommodated in the tube body, and the central portion 22 ₁ and the outer portion 22 _{2 are formed.} ) Protrudes up and down, and has a structure in which a plurality of outflow holes 23 are formed between the protruding central portion and the outer portion. In FIG. 6, one end of the elastic support 25 is shown to be supported in a state of blocking the outlet hole 23 of the separator 22, but in fact, the lower edge portion of the separator plate in which the outlet hole 23 is not formed. It is to be noted that support for In addition, an end portion of the spring and quartz tube 14 provided on one surface of the buffer port 29 is supported by retainers 26 located at both ends of the tube body, and the retainer 26 is supported by the quartz tube. It is firmly supported when the first cap 12 ₁ and 12 ₂ for sealing the cap are fitted. The UV lamp tube body formed by such a structure has male threads formed on both top and bottom sides of the tube body 11 ', and is sealed by a second cap 15 ₁ (15 ₂ ) having a female thread formed therein. do.

The first caps 12 ₁ and 12 ₂ are bent in a c-shape at the end, and their inner diameter is slightly larger than the outer diameter of the quartz tube 14, so that the first cap 12 12 ₁ ) Since a small gap is formed between the 12 ₂ ) and the quartz tube, the retainer 27 is opened under the end of the first cap 12 ₁ (12 ₂ ) with the center portion slightly open. Projection portion 27 ₁ of the retainer 27 in which the central portion protrudes by the pressure applied when the first cap 12 ₁ , 12 ₂ is fastened to the tube body by being fitted to the outer circumferential surface of the quartz tube 14 so as to be located at. ) To be in close contact with the quartz tube.

An elbow pipe 32 is connected to the fluid inlet 20 to introduce a fluid flowing through a water supply pipe (not shown) into a space filled with a polyhedron, and the fluid outlet 21 is connected to the separator 22. It acts as a passage for discharging the fluid discharged into the lower space 31 through the formed outlet hole to the outside of the tube body 11 '.

Furthermore, a groove is formed in the center of the second cap 15 ₁ and 15 ₂ so that the first cap 12 ₁ and 12 ₂ can be accommodated when the screw is fastened, and both sides of the first cap 15 12 ₁ ) A female thread corresponding to the male thread of 12 ₂ is formed, and one side of the cap 15 ₁ on the upper side of the second cap 15 ₁ and 15 ₂ is ozoneized polyhedron. Inflow path 18 is formed so that it can be introduced into the filled space, and similarly in the central portion of the first cap (12 ₁ ) for sealing the quartz tube is discharged to discharge the ozonized air by UV discharge ( 16 is formed and the inlet path 18 and the outlet path 16 are connected by an elbow pipe 19, the first cap (12 ₁ ) (12 ₂ ) and the second cap (15 ₁ ). 15 ₂ is screwed to seal the entire UV lamp tube. In the middle of the elbow pipe 19, a normal valve 33 for preventing back water such as a check valve or a slide valve is provided. In addition, although the elbow tube 32 and the air inlet 18 are illustrated to face each other in FIG. 6, the fluid and the air inlet 20 flowing into the UV lamp tube 11 through the fluid inlet 18 are actually formed. Ozoneized air flowing into the UV lamp tube 11 through) should be formed to be offset from each other to minimize mutual inflow resistance.

In the structure of the separator, the inner diameter of the formed outlet hole 23 may be such that only the fluid is discharged without the polyhedron 24 being separated.

In the first cap 12 ₂ which seals the lower end of the quartz tube 14, a compressed air inlet path 17 for introducing compressed air introduced at a constant pressure from the constant pressure compressor is formed.

At this time, the first cap 12 ₁ (12 ₂ ) according to the second embodiment of the present invention is made of a heat resistant resin such as polycarbonate as in the first embodiment, and in particular, the first cap 12 ₁ (12 ₂ ). ), A perforated network is loaded therein as shown in FIG. And a second cap (15 ₁₎ (15 ₂₎ may be a metallic material so that can dissipate heat generated at both ends of the UV lamp to the outside when the UV lamp is lit, where the second cap ₍₁₅₁₎ (15 ₂ The inner surface of) can be surface treated to prevent corrosion. In addition, like the first embodiment, the UV lamp tube 11 according to the second embodiment is also made of a metal material, the outer surface of the UV lamp tube 11 is coated with a heat insulating material (coating) to prevent condensation, heat treatment treatment At the same time, the inner surface may be surface treated to prevent corrosion. Reference numeral 28 is a second cap (15 _1, 15 ₂₎ as a retainer for holding the adhesion when fastened to the UV lamp tube 11, the second cap (15 ₁₎ (15 ₂₎ the inner surface corners of the Is installed on.

In addition, as in the first embodiment, the outer ring of the second cap (15 ₁ ) (15 ₂ ) is fitted with a metal ring (8) formed integrally with the c-shaped bent ring (7), UV lamp tube 11 UV lamp tube 11 and second cap by attaching a conventional fastening part 5 having a fastening piece 6 to the outer side thereof so that the fastening piece 6 is hooked to the hook 7 in a cicada hook manner. (15 ₁ ) (15 ₂ ) can be fixed firmly.

According to the present invention configured as described above, the compressed air introduced through the compressed air inlet passage 17 is ozonated by ultraviolet rays generated from the UV lamp 13 in the quartz tube 14 to pass through the outlet passage 16. Then it is introduced into the inflow path 18 via the elbow pipe 19. At this time, the ozonated air increases the amount of dissolved oxygen while passing through the gap of the filled polyhedron 24 in a mixed state with water discharged through the elbow pipe 32 through the fluid inlet 20 to the upper space 30. Let's go. Thereafter, the fluid is discharged into the lower space 31 through the outlet hole 23 formed in the separator 22 and is generated in the UV lamp 13 and sterilized by ultraviolet rays emitted through the quartz tube 14. It is discharged to an appropriate place through the outlet 21.

According to the first embodiment of the present invention as described above, since the UV lamp tube is sealed by the cap and screw fastening or by the cicada hook, the lamp tube can be opened and closed easily when repairing the internal parts. Only damaged parts can be easily replaced or repaired.

In addition, the material of the UV lamp tube is made of metal, which not only protects the UV lamp from external shocks, but also the inside of the lamp tube is heat-dissipated to prevent heat from radiating from the lamp tube to the outside. It is possible to prevent overheating inside the machine.

In addition, by using a heat-resistant resin as the cap of the UV lamp tube and inserting a perforated network of metal material therein, it can be prevented from being deformed or damaged by heat generated from the UV lamp.

On the other hand, according to the second embodiment of the present invention, it is possible to implement a device to ozone oxygen and aeration device for supplying compressed air ozone to the water can be easily installed in a narrow space when applied to household water purifiers, In addition, by uniformly distributing compressed air containing ozone in water and simultaneously performing two processes of irradiating ultraviolet rays, high concentration ozone water with increased sterilization power can be produced.

Claims (2)

In the UV lamp tube for ozone generation that UV lamp is stored, A female screw is formed inside the cylindrical cap 2 that seals the UV lamp tube 1 of the metal material, and correspondingly, male threads are formed outside the both ends of the UV lamp tube 1 so as to be screwed in. Cap 2 composed of a heat-resistant resin such as polycarbonate is injection molded by inserting a metal perforated net 3 having a plurality of holes 4 formed between the outer surface 2 ₁ and the inner surface 2 ₂ . And The inner surface of the UV lamp tube (1) is a UV lamp tube with a detachable cap, characterized in that the heat treatment by coating the heat insulating material and at the same time the outer surface is treated with a coating resin to prevent corrosion. The outer ring of the cap 2 is fitted with a metal ring (8) formed integrally with the bent ring (7), and fastened to the bent ring (7) on the outside of the UV lamp tube (1). Fastening part 5 is provided with a fastening piece 6 for forming a UV lamp tube with a detachable cap, characterized in that for fastening the UV lamp tube 1 and the cap 2 in a cicada hook method. .