KR200464243Y1 - Disinfection UV Irradiative Reactor Using the Pocket Chamber - Google Patents

Abstract

The present invention relates to a ultraviolet reactor for sterilization using a pocket-type chamber, in particular, the length of the reactor having a square or cylindrical shape is formed equal to the effective length of the ultraviolet lamp installed inside the quartz tube, and exposed to the outside of the reactor A pocket-type chamber is installed between the outer circumferential surface of the prepared quartz tube and the outer side of the reactor, and a part of the power cable for supplying power to drive the ultraviolet lamp and the insulator are located in the quartz tube located inside the pocket-type chamber. And a leakage preventing packing is provided between the rear end of the pocket-type chamber and the contact portion of the quartz tube.
In this germicidal UV reactor using a medium pressure lamp with a relatively high output per unit length, the lamp's insulation and power cable connections, which are not actually involved in UV irradiation, exist inside the reactor for cooling the lamp. The passing fluid has a limit in satisfying the irradiation dose required for sterilization, whereas in the present design, an additional pocket-type chamber can be installed to secure an area where the fluid is recirculated inside the chamber, so that the fluid passing through the reactor can be effectively applied to the lamp. Since only the section can be passed, the irradiation dose required for sterilization can be satisfied, and the temperature inside the chamber is applied to a liquid fluid with a larger heat capacity than air, so the temperature rise is small. Only circulating below can satisfy sterilization dose It is.

Description

Disinfection UV Irradiative Reactor Using the Pocket Chamber

The present invention relates to a UV reactor for sterilization using a pocket-type chamber, and more particularly to a UV irradiation reactor used by irradiating ultraviolet (Ultra-Violet) light to biodegradation or sterilization in water. The ultraviolet lamp can be installed using a reactor having a reactor main cross-sectional length equal to the discharge length of the UV lamp, by placing the discharge end of the lamp inside the pocket-type chamber. It is designed to cool using the treated water flowing inside.

In general, in order to sterilize microorganisms contained in seawater or freshwater with ultraviolet rays (UV), it is necessary to pass seawater or freshwater through a reactor equipped with UV lamps that emit UV rays in the wavelength range of 200-280nm, which are known to be sterilizing. .

However, if the amount of UV irradiation to the microorganisms (hereinafter referred to as "UV Dosage") does not meet a certain level or more has been reported to have no bactericidal effect.

UV Dosage is calculated by multiplying the UV Intensity of the microorganisms irradiated by the time the microorganisms are exposed to UV, and the sterilization rate of microorganisms is an important criterion for evaluating the performance of the UV reactor.

This requires a high rate at which the UV dosage of each microorganism that has passed through the UV reactor is above a certain value.

Therefore, it is important in the UV reactor design to place a UV lamp in the UV reactor so that all the microorganisms passing through the reactor can stay in the UV field for a certain amount of time or longer.

On the other hand, ultraviolet (UV) light irradiation apparatus has been widely used for the purpose of sterilization or killing of microorganisms in the treatment field, such as drinking water, and such ultraviolet light irradiation apparatus is usually low pressure lamp and medium pressure lamp in accordance with the gas pressure in the lamp Medium pressure lamps are mainly used for high irradiation density applications.

In the case of the medium-pressure lamp, since the irradiation density per lamp is large, the heat generation amount of the lamp is high and there is a possibility of increasing the temperature of the water in contact with the water treatment field. It is recommended to install in the direction of gravity and horizontal to reduce the pressure.

In order to achieve this purpose, the ultraviolet (UV) reactor is used to efficiently arrange the UV lamp, and to prevent damage to the packing material due to overheating of the lamp, it is used to configure the cooling to be smooth.

Figure 1 shows the arrangement of a conventional horizontal piping type UV reactor.

According to this, in the conventional UV reactor, the fluid to be treated flows between the sections of the reactor 1 in which the lamp is installed, and the quartz tube 3 for protecting the lamp and the lamp is installed, and the ultraviolet ray is inside the quartz tube 3. Lamp 2 is installed, the end of the quartz tube 3, the power cable 5 and the insulator 4 for power supply is installed, the end of the reactor 1 and the contact portion of the quartz tube (3) The ultraviolet ray lamp 2 in operation has a structure in which the leak-proof packing 6 is provided, and it is a structure which cools automatically by the fluid which flows out of the quartz tube 3 outside.

However, in the sterilizing ultraviolet reactor having such a configuration, not only the region where ultraviolet light is emitted but also a part of the power cable and an insulator are present inside the reactor, so the fluid to be treated passes through the insulator region, which is a non-light emitting region, to satisfy the amount of ultraviolet radiation required for sterilization. Since the area does not increase, there is a problem that the number of lamps should be further increased for the overall sterilization treatment.

The present invention has been devised to solve such a conventional problem, in the reactor in which the ultraviolet lamp is installed, the width of the reactor to the effective length of the longitudinal direction of the UV lamp, the insulating portion and the packing portion of the lamp separately It is configured to be installed in the pocket-type chamber of the reactor to be independent of the main flow flowing in the reactor, in particular, the upper shape of the chamber is inclined in the range of 90 ° or more and 150 ° or less in the lateral or tangential direction of the reactor so that air does not stay inside. In this case, a lamp having a high irradiation density per lamp can smoothly cool the heating unit and provide a sterilizing ultraviolet reactor using a pocket chamber that can secure a dose required to secure a constant sterilizing power for the fluid flowing through the reactor. The purpose is to.

The present invention for achieving the above object, the length of the reactor having a square or cylindrical shape is formed equal to the effective length of the ultraviolet lamp installed inside the quartz tube, and the outer peripheral surface of the quartz tube exposed to the outside of the reactor A pocket-type chamber is installed between the outer side of the reactor, and a part of the power cable for supplying power to drive the ultraviolet lamp and the insulator are installed to be located in a quartz tube located inside the pocket-type chamber. Between the rear end of the chamber and the contact portion of the quartz tube is characterized in that the leakage preventing packing is installed.

At this time, the outer peripheral surface of the pocket-type chamber is formed to be inclined in the range of 90 ° or more and 150 ° or less in the lateral or tangential direction of the reactor, characterized in that the air does not stay inside.

In addition, between the pocket-type chamber and the rear end of the reactor, a recirculation tube and a circulation pump are further installed to recirculate the water passing through the reactor to the pocket-type chamber when the size of the pocket-type chamber is limited and the desired natural circulation cannot be obtained. It is characterized in that the cooling object can be achieved.

In addition, the inner circumferential surface of the pocket chamber is processed stepwise.

As described above, according to the germicidal ultraviolet reactor using the pocket-type chamber of the present invention, in the germicidal ultraviolet reactor using a medium pressure lamp having a relatively high output per unit length, the germicidal ultraviolet reactor does not actually participate in the ultraviolet irradiation for cooling the lamp. The lamp's insulation and power cable connections are inside the reactor, and there is a limit to satisfy the irradiation dose required for sterilization for the fluid passing through the invalid section. It is possible to satisfy the irradiation amount required for sterilization because the fluid passing through the reactor can pass only the effective section of the lamp by securing the area where the gas is recycled, and the temperature inside the chamber is applied to the liquid fluid having a larger heat capacity than air. Low temperature rise and convection effect due to density difference It is a very useful design, such that only a certain amount or less can be automatically circulated to satisfy the sterilization dose.

2 is a schematic configuration diagram of an ultraviolet reactor to which an embodiment of the present invention is applied.
3 is a schematic configuration diagram of an ultraviolet reactor to which another embodiment of the present invention is applied.
Figure 4 is a schematic diagram of a UV reactor to which another embodiment of the present invention is applied.

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

2 shows a schematic configuration diagram of an ultraviolet reactor to which an embodiment of the present invention is applied, and FIG. 3 shows a schematic configuration diagram of an ultraviolet reactor to which another embodiment of the present invention is applied, and FIG. 4 shows another embodiment of the present invention. A schematic diagram of the applied ultraviolet reactor is shown.

According to this, an embodiment of the present invention is shown in Figure 2,

The length of the reactor 1 having a square or cylindrical shape is formed to be the same as the effective length of the ultraviolet lamp 2 provided inside the quartz tube 3,

A pocket-type chamber 7 is installed between the outer circumferential surface of the quartz tube 3 exposed to the outside of the reactor 1 and the outside of the reactor 1,

A part of the power cable 6 for supplying power to drive the ultraviolet lamp 2 and the insulator 4 are installed in the quartz tube 3 located inside the pocket-type chamber 7,

A leakage preventing packing 6 is provided between the rear end of the pocket-type chamber 7 and the contact portion of the quartz tube 3.

At this time, the outer circumferential surface of the pocket-type chamber 7 is formed to be inclined in the range of 90 ° or more and 150 ° or less in the lateral or tangential direction of the reactor 1 to prevent air from staying inside.

In addition, another embodiment of the present invention, as shown in Figure 3,

Between the front part of the pocket-type chamber 7 and the rear end of the reactor 1, a recirculation tube 8 and a circulation pump 9 are further installed to limit the size of the pocket-type chamber 7 to secure a desired natural circulation. It is characterized in that the water passed through the reactor 1 when not able to be recycled to the pocket-type chamber 7 side to achieve the cooling purpose.

In addition, another embodiment of the present invention, as shown in Figure 4,

It is characterized in that the outer peripheral surface of the pocket-type chamber 7 is processed stepwise.

Referring to the effect of the present invention configured as described above are as follows.

First, the present invention is formed to have the same width as the effective length of the ultraviolet lamp 2 installed in the quartz tube 3 when manufacturing the reactor 1 having a square or cylindrical shape, and to the outside of the reactor 1 A pocket chamber 7 was provided between the outer circumferential surface of the quartz tube 3 that was exposed to the outside and the outside of the reactor 1.

At this time, the outer circumferential surface of the pocket-type chamber 7 is formed to be inclined in a range of 90 ° or more and 150 ° or less with respect to the side surface or the tangential direction of the reactor 1 so that air does not stay inside the pocket-type chamber 7. Will not.

In addition, an insulator which is provided inside the quartz tube 3 to insulate the ultraviolet lamp 2, including a part of a power cable 6 which supplies a power voltage to the ultraviolet lamp 2. 4) is installed so as to be located in the quartz tube 3 located inside the pocket-shaped chamber 7, and leaks fluid between the rear end of the pocket-shaped chamber 7 and the contact portion of the quartz tube 3; It has the structure which provided the leakage prevention packing 6 for preventing.

That is, in the sterilizing ultraviolet reactor 1 which applies the medium pressure lamp which has a relatively large output per unit length, the insulator 4 of the ultraviolet lamp 2 which does not actually participate in ultraviolet irradiation in order to cool the ultraviolet lamp 2, ) And the connecting portion of the power cable 6 is present in the reactor 1 as in the prior art, there is a limit to satisfy the irradiation amount required for sterilization for the fluid passing through the invalid section.

However, in the present invention, by adding a pocket-type chamber 7 between the reactor 1 and the quartz tube 3 to configure a sterilizing ultraviolet reactor, the area where the fluid is recirculated inside the pocket-type chamber 7 is secured. The fluid passing through the reactor 1 passes only the effective section of the ultraviolet lamp 2, thereby satisfying the irradiation dose required for sterilization.

At this time, the temperature inside the pocket-type chamber 7 is applied to a liquid fluid having a larger heat capacity than air, so the temperature rise is small, and only a certain amount or less is automatically circulated due to the convection effect caused by the density difference, thereby satisfying the sterilization dose. Will be.

On the other hand, Figure 3 shows another embodiment of the present invention, when the size of the pocket-type chamber (7) is limited to ensure the desired amount of natural circulation, the pocket-type chamber (7) front and reactor ( A separate recirculation tube 8 and a circulation pump 9 are further installed between the rear ends of 1) to forcibly recirculate water passing through the reactor 1 to the pocket-type chamber 7 through the circulation pump 9. By doing so, the cooling objective can be sufficiently achieved.

In addition, Figure 4 shows another embodiment of the present invention, when processing the pocket-shaped chamber (7) by using a thick pipe its inner peripheral surface 90 ° or more 150 ° in the lateral or tangential direction of the reactor (1) It was formed to be inclined in the following range, but when viewed from the front side was formed to have a form stepped stepwise.

As such, when the inclined inner circumferential surface of the pocket-type chamber 7 is formed to be bent in a step shape, it has an advantage of being easy to manufacture while having a smooth convection effect as shown in FIGS. 2 and 3.

Although the above-described embodiment has been described with respect to the most preferred embodiment of the present invention, it is not limited to the above embodiment, it will be apparent to those skilled in the art that various modifications are possible without departing from the technical spirit of the present invention.

1: reactor 2: ultraviolet lamp
3: quartz tube 4: insulator
5: power cable 6: leakage prevention packing
7: pocket-type chamber 8: recirculation tube
9: circulating pump

Claims (4)

The length of the reactor having a square or cylindrical shape is formed equal to the effective length of the ultraviolet lamp installed inside the quartz tube, and a pocket-type chamber is installed between the outer circumferential surface of the quartz tube exposed to the outside of the reactor and the outside of the reactor. And a part of the power cable for supplying power to drive the ultraviolet lamp and an insulator are installed in a quartz tube positioned inside the pocket chamber, and between the rear end of the pocket chamber and the contact portion of the quartz tube. Install the leak proof packing,
The outer circumferential surface of the pocket-type chamber is formed to be inclined in a range of 90 ° or more and 150 ° or less in the lateral or tangential direction of the reactor so that the air does not stay inside the sterilized ultraviolet reactor using a pocket-type chamber.
delete The method according to claim 1,
Between the pocket-type chamber and the rear end of the reactor, a recirculation tube and a circulating pump are further installed to recirculate the water passed through the reactor to the pocket-type chamber when the size of the pocket-type chamber is limited to secure the desired natural circulation. Sterilizing ultraviolet reactor using a pocket-type chamber, characterized in that to achieve.
The method according to claim 1,
Sterilizing ultraviolet reactor using a pocket-type chamber, characterized in that the inner peripheral surface of the pocket-type chamber processed stepwise.

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