KR20120003519U - Arranging structure of the UV lamp in disinfection UV irradiative reactor with pipe connection - Google Patents

Abstract

The present invention relates to a UV lamp arrangement method of the tube insertion type sterilization UV reactor, the purpose is that the cross section of the flow direction in which the UV lamp is installed is not constant, or when the UV lamp longer than the length of the cross section is installed in the pipe, the same size Rather than installing one or more UV lamps in a direction perpendicular to the axial direction of the pipe, it is to provide an array structure of the UV lamps to maximize the sterilizing power to microorganisms by inclining the axial direction.
The construction of the present invention to achieve this is in the UV lamp array structure of the tube insert type sterilization UV reactor, at least one having the same length in the UV reactor having a circular or square cross-sectional shape installed in the fluid flowing pipe to sterilize microorganisms Features of the design of the UV lamp array of the tube insert type sterilizing ultraviolet reactor installed by arranging the UV lamps in an inclined direction with the pipe axis direction.

Description

Arranging structure of the UV lamp in disinfection UV irradiative reactor with pipe connection}

The present invention relates to a UV lamp array structure of a pipe-insertion type sterilizing ultraviolet reactor, and in detail, a pipe-insert type UV which is used by irradiating ultraviolet (Ultra-Violet) light to biodegradation or sterilization in water. The UV lamp is arranged obliquely in the irradiation reactor so that all microorganisms passing through the UV reactor can be disposed in the UV reactor in a UV field of a certain intensity or more, for a predetermined time or longer.

In general, in order to sterilize microorganisms contained in seawater or fresh water with ultraviolet rays (hereinafter referred to as UV), a reactor equipped with a UV lamp that emits UV in the wavelength range of 200 to 280 nm, which is known to have sterilization power, is used to discharge seawater or fresh water. Pass it through.

However, if the amount of UV (UV Dosage, hereinafter referred to as "UV dose") irradiated to the microorganism does not meet a certain level or more, it is reported that there is no bactericidal effect. The UV dose is calculated as the product of the UV intensity of the microorganisms irradiated and the time the microorganisms are exposed to UV.

In addition, the microbial sterilization rate is an important criterion for evaluating the performance of the UV reactor. This requires a high rate at which the UV irradiation amount of each microorganism that has passed through the UV reactor becomes a certain value or more.

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.

1 is a general UV lamp structure, as shown in the UV lamp outside is protected by a quartz tube, the quartz tube connection nozzles are installed around both ends of the quartz tube to prevent the leakage of the fluid through the internal reactor structure do. In addition, the power cable at both ends of the UV lamp is connected to the power supply ballast (not shown) is configured to supply power. In the following description, the UV lamp means a UV lamp whose outer surface is protected by a quartz tube for convenience. In addition, natural components, such as connection nozzles, are abbreviate | omitted and demonstrated.

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 (UV) light irradiation apparatus is usually low pressure lamp according to the gas pressure in the lamp The medium pressure lamp is mainly used for high irradiation density applications.

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

In order to achieve this purpose, a horizontal piping type ultraviolet (UV) reactor is largely divided into a flange, a diffuser connecting between a flange and a cross section of a UV reactor, and a reactor cross-sectional area in which UV lamps are installed. The cross-sectional structure of the UV lamp installation area is generally used in the form of round or square deformation.

Figure 2 is a conventional general cross-sectional pipe insertion type UV reactor layout. As shown, the arrangement of a conventional horizontally piped UV reactor has a UV lamp protected by a quartz tube, which is a protective tube, installed horizontally in parallel with the cross section of the reactor. It is arranged up and down. Here, the length of the quartz tube, which is a protective tube protecting the UV lamp and the UV lamp, is the same, and the method of preventing leakage of the quartz tube, which is the protective tube, consists of a quartz tube connection nozzle as shown in FIG. Silver is omitted for the convenience of illustration as a sealing configuration that must be of course in the lamp structure is installed where the fluid flows.

The UV lamps shown are seen from the front, so the lamps in the front section and the UV lamps in the rear section are the same. Promote.

However, in the conventional UV lamp arrangement method, since the length of the UV lamp horizontally moved in the circumferential direction is different from that when passing through the central section of the pipe, each capacity must be designed differently, and the required number of lamps to secure the same irradiation amount is increased. There is a problem that must be increased.

3 is a conventional rectangular cross-sectional pipe insertion type UV reactor layout. As shown in the drawing, a conventional horizontal piping type ultraviolet (UV) reactor having a rectangular cross section is largely divided into a connecting flange connected to the piping by zone, a diffuser connecting between the flange and the UV reactor cross section, and a reactor cross section area where the UV lamp is installed. . The cross-sectional structure of the region where the UV lamp is installed is a rectangular cross section as shown.

When the aspect ratio is more than three times the aspect ratio of the rectangular shape shown, the ratio of the connection flange and the diffuser is increased, making it difficult to uniformize the flow rate distribution in the lamp installation area, and the shorter the square, the shorter the cross section ratio. There is a problem that the number of lamps is increased.

That is, as shown, the pipe is a circular pipe, the square reactor cross section is composed of a square, the angle of the diffuser is different depending on the length of the connection between the pipe and the square cross section, and the angle of the reactor must be small for the uniformity of flow There is a disadvantage that increases.

An object of the present invention for solving the above problems is that the cross section of the flow direction in which the UV lamp is installed is not constant, or when installing a UV lamp longer than the length of the cross section in the pipe, at least one UV lamp having the same size pipe Rather than being installed in the axial direction orthogonal to the axial direction, it is installed to be inclined with the axial direction to provide an array structure of UV lamps to maximize the sterilizing power for microorganisms.

Another object of the present invention is to reduce the number of UV lamps while placing the UV lamp in the UV reactor so that all the microorganisms passing through the reactor stay in the UV field of a certain intensity for a certain time or more, the horizontal pipe type UV satisfying the required dose It is to provide a UV lamp array structure of the reactor.

The present invention to achieve the object as described above and to perform the problem for removing the conventional defects in the UV lamp array structure of the tube insert type sterilization UV reactor, the fluid is installed in the pipe flows installed to sterilize microorganisms or It is achieved by providing a UV lamp array structure of the pipe-insertion type sterilizing ultraviolet reactor characterized in that the UV reactor having a square cross-sectional shape is installed by arranging at least one UV lamp having the same length in an oblique direction to the pipe axis direction.

In addition, the inclination angle of the UV lamp in the present invention is characterized by a structure in which the inclination is installed differently depending on the length of the UV lamp and the length of the cross section.

In addition, the UV lamp in the present invention is characterized in that the structure is arranged to reduce the overall UV reactor length by cross-installing the UV lamp arranged in the "X" shape on the basis of the center line in the same section in the pipe.

In addition, the UV lamp in the present invention is characterized in that the arrangement arranged to ensure the residence time of the fluid passes through the UV reactor by arranging the UV lamp adjacent to the vertical direction at regular intervals.

In addition, in the present invention, when the UV reactor is a square shape, the UV lamp larger than the width of the UV reactor is inclined horizontally to reduce the width ratio of the UV reactor to reduce the width ratio of the UV reactor diffuser connected to the pipe. Features,

As described above, the present invention does not have a constant cross section in the flow direction in which the same size UV lamps are installed, or when UV lamps longer than the length of the cross section are installed in the pipe orthogonally in the axial direction of the pipe, instead of the UV lamps. It is installed to be inclined in the axial direction, and the inclination angle is provided by the arrangement method to install the inclination differently according to the length of the UV lamp and the length of the cross section. Reactors can be manufactured and UV lamps placed to increase the UV irradiation time and increase the probability of microorganisms passing through the UV field over a certain intensity by minimizing the interruption surface of the UV lamp in the flow direction. By devising has the effect of improving the UV irradiation efficiency.

In addition, the width ratio can be designed irrespective of the length of the UV lamp in the square pipe. Therefore, the width ratio of the connecting flange and the square pipe can be reduced to equalize the distribution of flow velocity in the flow cross section. It is a useful design with the effect that it can reduce the industrial use is expected to be greatly expected.

1 is a general UV lamp structure diagram,
Figure 2 is a conventional circular cross-sectional pipe insertion type UV reactor layout,
Figure 3 is a conventional rectangular cross-sectional pipe insertion type UV reactor layout,
4 is a schematic layout view of a UV lamp installed in an ultraviolet reactor according to an embodiment of the present invention,

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in describing the present invention, if it is determined that the detailed description of the related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Figure 4 is a schematic layout of the UV lamp installed in the ultraviolet reactor according to an embodiment of the present invention, the present invention is to increase the probability of passing the UV field over a certain intensity of the microorganisms passing through the UV reactor and increase the UV irradiation time It shows a UV lamp arrangement arrangement protected with quartz tube. At this time, the left structure of FIG. 4 is similar to that of FIG. 2, but FIG. 2 is arranged horizontally, and the present invention may refer to the right perspective view as the UV lamps installed at an angle look similar to each other via a ball view in cross section.

According to an embodiment of the present invention, the present invention is installed to connect and sterilize an ultraviolet reactor having a circular or square cross section connected by a connecting flange (see FIG. 3) to a section of a pipe through which a microbe-containing fluid flows. Connection nozzles (not shown) for installing UV lamps protected by quartz tubes are installed inside the reactors on both sides of the UV reactor having a circular (or square cross-section) pipe shape, and connection nozzles (not shown) on both sides of the UV lamps. In the horizontal section of the UV lamp installation level, the UV lamps are installed diagonally and moved to the length Z. The configuration of the quartz tube, the connection nozzle, and the like in the reactor configuration is replaced by the conceptual description shown in FIG. 1.

What is important in the present invention is that all UV lamps installed in the reactor have the same length. Therefore, one or more UV lamps can be installed symmetrically in the vertical end face of the UV reactor, and the next section is installed by adjusting the number of columns according to the length of the UV reactor (meaning that it is installed on the back side instead of the same section).

In addition, the inclination angle of the UV lamp was arranged by installing different inclination according to the length of the UV lamp and the length of the reactor cross section. That is, when the UV lamp of the same length is installed, the angle of the UV lamp to be installed varies depending on the size of the reactor cross section (inner diameter).

In addition, the upper and lower parts of the symmetrical cross section are installed so as to shorten the length of the reactor by crossing the X letter.

In addition, the UV lamp is arranged so as to secure the residence time for the fluid to pass through the UV reactor by placing the adjacent UV lamp in the vertical axis direction at regular intervals.

In addition, when the UV reactor is rectangular, UV lamps larger than the UV reactor width are inclined horizontally to reduce the width ratio of the UV reactor diffuser connected to the pipe by reducing the width ratio of the UV reactor.

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

Ultraviolet (UV) reactors can be manufactured by using UV lamps of the same size in circular pipes with different cross-sections in the direction of UV lamp installation. It is possible to improve the irradiation efficiency according to the lamp arrangement to increase the probability of passing through the UV field over a certain intensity and to increase the UV irradiation time.

In addition, the width ratio can be designed irrespective of the UV lamp length in the square pipe, so the width ratio of the connecting flange and the square pipe is reduced, so that the flow velocity in the cross-sectional direction is equalized, and the length of the unit lamp is longer than the same capacity to reduce the overall number of lamps. It becomes possible.

The present invention is not limited to the above-described specific preferred embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Claims (5)

In the UV lamp array structure of the tube insertion type sterilization ultraviolet reactor,
Pipe insert-type sterilization ultraviolet reactor, characterized in that installed in one or more UV lamps having the same length inclined in the direction of the pipe axis in the UV reactor having a circular or square cross-sectional shape installed to sterilize microorganisms in the fluid flowing pipe UV lamp array structure.
The method according to claim 1,
The inclination angle of the UV lamp is a UV lamp array structure of the tube insert type sterilization UV reactor, characterized in that arranged by arranging different inclination according to the length of the UV lamp and the length of the cross section.
The method according to claim 1,
The UV lamp UV of the pipe insert type germicidal UV reactor, characterized in that arranged to reduce the length of the overall UV reactor by cross-installing the UV lamp arranged in the "X" shape on the basis of the center line in the same section in the pipe. Lamp array structure.
The method according to claim 1,
The UV lamp is a UV lamp array structure of the pipe-type sterilization ultraviolet reactor characterized in that the arrangement is arranged to ensure the residence time of the fluid passing through the UV reactor by arranging the adjacent UV lamp in the vertical axis at regular intervals up and down.
The method according to claim 1,
When the UV reactor is a rectangular shape, the pipe insertion type characterized in that the UV lamp larger than the width of the UV reactor is installed inclined horizontally to reduce the width ratio of the UV reactor to reduce the width ratio of the UV reactor diffuser connected to the pipe. UV lamp array structure of the UV reactor for sterilization.

Images