KR100499565B1 - Water level adjustment structure of water channel - Google Patents

Abstract

The present invention relates to a water level control structure of a water channel, and more specifically, a dam at a rear end of an ultraviolet lamp to prevent the water level from rising due to a rapid increase in flow rate in a water channel equipped with several ultraviolet lamps for sterilization of sewage. Install the zigzag water level control dam to have the effect of lengthening the length of the dam, and the dam length is reduced by designing the water level control dam in consideration of the sewage flowing through the channel and the flow velocity of the channel according to the frictional resistance of the channel. It is possible to precisely control the water level by reducing the dam length inefficiency loss.In addition, a drain valve is installed at any position of the water level control dam, and a guide perpendicular to the water level increase prevention plate and the water level increase prevention plate is integrated in front of the UV lamp. It is related to the water level control structure of the channel formed by sliding the screen vertically formed and easy to insert .

Description

Water level control structure of water channel {WATER LEVEL ADJUSTMENT STRUCTURE OF WATER CHANNEL}

The present invention relates to a water level control structure in which a water level control dam is installed to prevent the water level from rising due to a sudden increase in the flow rate at the rear end of the UV lamp in the channel having several UV lamps for sterilization of sewage.

Sewage discharged from homes and industrial complexes contains a lot of suspended solids and harmful microorganisms, which, if directly introduced into rivers or rivers, can cause pollution of rivers, severe pollution of rivers and seas, and destruction of natural ecosystems. As a result, sewage is usually purified and discharged to a large extent through chemicals or other purification facilities.

However, even after the sewage is purified, various harmful microorganisms inhabit the sewage, and as a means for preventing the sewage, the sewage is discharged after being irradiated with UV rays for a predetermined time.

The water treatment method for treating sewage with ultraviolet light is largely an open type method such as a closed type and a water channel, and the present invention is installed in an open water channel so that the ultraviolet light emitted by the ultraviolet lamp for the sterilization process is sufficiently irradiated to the sewage without loss. It is intended to disclose a water level control structure for.

Unlike the closed type, the water treatment system in the channel has a device that allows the ultraviolet rays to be sufficiently irradiated to the sewage because the water level is often variable depending on the flow rate or the flow rate of the sewage, so that the water level is always kept constant regardless of the flow rate. A number of measures have been introduced.

Among such methods, as an example of the prior art, the Republic of Korea Utility Model Registration No. 0296731 'waterway type ultraviolet water sterilizer' may be mentioned.

In the related art, the flow rate of the water channel is not constant, so that the flow rate is controlled by installing a water gate that is opened and closed by a brake controller at the inlet and the outlet of the water channel.

In the case of the electric control method, while the water level control has a relatively accurate advantage, the installation cost is not only expensive, but also a maintenance cost of the control device and the water gate, there is a problem to consider a significant cost loss.

According to another conventional technology, when the pressure of the fluid and the weight due to the stop / movement of the weight are balanced, the gate is opened when the internal pressure of the fluid is large, and when the internal pressure of the fluid falls below the reference level when the gate is opened, A gate controlled by a kind of water level that allows the gate to be closed has been introduced, and in this context, an improved design can be referred to as Korean Utility Model Registration No. 0295112.

However, the above design has the advantage of not requiring maintenance and maintenance costs, while being suitable for large sewage treatment plants, it is difficult to apply to small sewage treatment facilities, and it is impossible to control the water level when the flow rate is lower than the design value, as well as the gate. There is a problem that a continuous leak occurs between the wall and.

Referring to the structure of FIG. 6 proposed as another prior art, several ultraviolet lamps 2 for sterilization treatment are installed at one side of the channel 1, and the dam is installed at the rear thereof to adjust the water level.

That is, when the quantity is small, water is not discharged from the water channel but is sterilized by ultraviolet rays stored in the dam, and when the water level of the dam rises, the sewage overflows and discharges to the top of the dam. In addition, it can be applied to both small and small sewage treatment plants, and since dams are built on existing waterways, installation costs are very low and maintenance management costs are not required.

However, when the water quantity increases rapidly, as shown in Fig. 6, the dam 3 provided in the narrow water channel cannot sufficiently prevent the sewage of a large flow rate, so that water having a high water level is higher than the height of the dam 3. Since it is stored, there is a non-sterile area A that is not irradiated with ultraviolet rays, and this non-sterile area A exists in the upper portion of the relatively high flow rate, so that most of the sewage is discharged without being sterilized. do.

As a conventional method for solving this problem, a zigzag dam 4 has been devised as shown in FIG. 7, which is also described in the prior art description of Korean Patent Laid-Open Publication No. 2001-0012046. In order to make the length longer, it is composed of a zigzag-shaped dam, so that the fluctuation of the water depth of the flowing water against the fluctuation of the water level is made as small as possible. ”

That is, referring to FIG. 7, the dam 4 is formed in a zigzag manner with respect to the narrow channel 1 so that the length of the dam is relatively longer than that of the straight dam, and the narrow width of the channel 1 is increased. It has the effect of overcoming and widening, thus preventing the water level from rising sharply above the height of the dam even if the flow rate increases rapidly.

However, the zigzag dam 4 as described above has a dam length inefficiency region B in which the dam length is not used as a whole as shown in FIG.

This will be described in more detail with reference to FIG. 8, and the illustrated "C" represents the speed of the sewage flowing in the channel 1 as a vector VECTOR.

As the sewage is frictional with the side wall of the channel in the channel 1 as shown in the vector (C) graph, the flow velocity is slower as it is closer to the side wall of the channel 1, faster from the side wall, that is, toward the center, Faster flow rate means that the flow rate is larger per unit time.

When sewage having a different speed according to the position reaches the zigzag dam 4, the water level rises at the central part rather than at the edge of the waterway 1, so that a larger amount of sewage flows and flows to the side wall. As it gets closer, the overflow of the sewage decreases, resulting in a dam length inefficiency area (B) where water does not overflow, as shown, resulting in both sidewalls of the channel, resulting in an extension of the length of the dam (4). The entire length of the dam is not used efficiently, resulting in a reduction in the actual length of the dam.

Meanwhile, the ultraviolet lamp 2 according to the prior art as shown in FIGS. 6 and 7 may damage the lamp or lower the light transmittance of the lamp due to impact and deposition caused by various suspended solids or solids contained in the sewage. In addition, the suspended matter deposited around the lamp 2 may cause a malfunction of the scraper to remove the suspended matter while reciprocating the outer circumferential surface of the lamp 2.

Accordingly, the present invention has been created in order to solve the above problems, the present invention is low installation cost, but does not require maintenance and management costs, and despite the variable inflow water level is raised above a certain height It provides a water level control dam with a structure that does not generate an unsterilized area of the UV lamp, and provides a water level control structure for the water level control dam that can efficiently use the entire length of the dam in response to the flow rate of the sewage. Has a primary purpose.

The present invention also provides an auxiliary structure for enabling arbitrary discharge of the water stored in the water level control dam and preventing the water level of the ultraviolet sterilization zone from rising even if the sewage is rapidly increased. A second purpose is to provide a channel level control structure that minimizes the suspended matter contained.

In order to achieve the above object, the present invention is to accumulate a dam in a narrow channel, and to increase the length of the top of the dam to pile the dam in a zigzag form to adjust the water level of the dam, sewage in consideration of the sewage flow rate in the channel The closer to the side wall the dam is disposed in front of the waterway, and the farther behind the dam according to the position velocity reached.

In addition, the present invention includes at least one drain valve installed at the base of the dam to discharge any sewage stored in the water level control dam.

In addition, the present invention includes a water level preventing plate installed in the vicinity of the UV lamp group to open to the predetermined height from the bottom of the channel as an auxiliary means for preventing the water level of the ultraviolet lamp area rises.

In addition, the present invention is provided with a screen that is integrally provided with a guide in the UV lamp group ahead, preferably a water level preventing plate, and slides perpendicularly to the guide to minimize the floating matter remaining in the sewage flowing through the UV lamp area is installed. It includes what has become.

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

1 is a perspective view schematically showing a water channel to which another water leveling structure is applied to the present invention, and FIG. 2 is a partial plan view of FIG. 1 for explaining the structure of the water leveling dam according to the present invention.

1 and 2, in order to increase the efficiency of sterilization by ultraviolet light in the region of the ultraviolet lamp 11, the sewage flowing in the water channel 10, that is, the non-sterile region is generated as described above in the prior art. In order to prevent the length of the dam to extend the length of the dam to have a wide effect of the zigzag water level control dam 12 is installed.

However, as shown in FIG. 2, the sewage flowing through the width of the water channel 10 has a slower flow rate as it is closer to the side wall of the water channel 10, and the flow rate increases as it is farther from the side wall, which is represented by a vector VECTOR. "to be.

Therefore, the water level control dam 12 of the present invention is installed in a zigzag-level level control dam 12 in consideration of the speed according to the position in the sewer 10, the side wall of the water channel 10 By arranging it forward in the front and rearward as it moves away from the side wall, it is designed as a zigzag water level dam 12 in the form of an ARCH, which is mathematically considered in consideration of the width and height of the channel 10. By calculating, a curve value equal to the flow velocity vector C is calculated, and it is satisfied if it is designed accordingly.

Since the water leveling dam 12 designed as described above overflows water evenly over the entire length of the dam, the dam length inefficiency region does not occur in the side wall portion of the waterway 10, which is a conventional zigzag level control. The dam length is prevented from being substantially reduced.

Figure 3 is a plan view of the channel to which the water level control structure according to another embodiment of the present invention, Figure 4 is a side sectional view of the embodiment of Figure 3, showing another preferred embodiment of the present invention.

3 and 4, a water level increase preventing plate 13 is installed at the upper end of the channel 10 so as to open only to a predetermined height at the bottom of the channel 10 in front of the ultraviolet lamp 11 region.

The water level increase prevention plate 13 prevents the water level from rising above the ultraviolet irradiation region of the ultraviolet lamp 11 in the ultraviolet lamp 11 region even if the water level rises due to the increase in the flow rate of the sewage. In order to be inclined or to form a rounded curved portion as shown in the lower end.

On the other hand, although the structure of the ultraviolet lamp 11 is not shown, the scraper which reciprocates in the longitudinal direction of the ultraviolet lamp 11 is installed in the outer periphery of each ultraviolet lamp 11, This scraper is the surface of the ultraviolet lamp 11 This is to solve the problem of reducing the amount of UV radiation to sewage due to the suspended matter deposited on the sewage and inhibiting the sterilization effect.It is automatically generated by a signal such as a sensor (not shown) that detects UV transmittance after a predetermined time. It is a known technique to reciprocately transfer and wipe off the suspended matter deposited on the surface of the ultraviolet lamp.

However, since the sewage contains a lot of suspended matter (solids), suspended matter is deposited and cured between the scraper and the ultraviolet lamp 11 in the field, so that the operation of the scraper may be disturbed or the ultraviolet lamp 11 may be broken. Preferably, a large part of the suspended matter contained in the sewage flowing into the ultraviolet lamp 11 region needs to be removed.

Therefore, in the present invention, the guide 14 having grooves on the water level increase preventing plate 13 is installed to face each other in the width direction of the channel 10, and the screen having meshes on the grooves of the guide 14 is provided. 15) was installed.

The guide 14 may be provided with at least one groove, and thus, at least one screen 15, which is vertically slid and inserted from the groove, may be installed to efficiently filter suspended matter or solids.

The screen 15 configured as described above can be inserted into and removed from the channel 10 along the groove of the guide 14, and thus, when suspended matter is deposited on the mesh of the screen 15, the screen 15 can be removed and cleaned.

In another preferred embodiment, a drain valve 16 is provided at the rear of the water level control dam 12 of the present invention.

The sewage stored in the waterway by the water level control dam 12 needs to be removed as needed, i.e., to repair / repair the ultraviolet lamp 12 device or to clean the waterway inside, where the drain valve 16 ) Can be artificially discharged sewage stored in the waterway (10).

The drain valve 13 may be a manual valve or an automatic system intermittent by an electrical device, and the configuration thereof may be satisfied by employing a known mechanism and electrical means.

FIG. 5 is a perspective view conceptually showing another embodiment of the present invention, schematically showing a disc filter 20 used for filtering, which is a pretreatment process in which sewage flows into the water channel 10.

The disc filter 20 is configured such that a plurality of donut-shaped discs 21 are rolled out to be rotated.

Briefly explaining the operation of such a filter, the sewage for water treatment flows into the center of the disk 21, and the introduced sewage filters various floats or solids in the form of manure from the disk due to the rotation of the disk 21. The filtered suspended matter moves upward to the center of the disc 21 and is collected and discharged by the alveoli 22 provided in the center of the disc 21, and the treated water passing through the disc 21 is discharged to the water channel 10. Will be.

In addition, in order to clean the disk 21, the cleaning pipe 23 is installed above the disk 21 to perform a kind of backwashing process for spraying water on the disk 21, the water used for cleaning The treated water filtered out by the disc 21 is used.

The disk filter 20 may be selected as a pretreatment process of the water channel 10 according to the size of the sewage treatment plant or the capacity of the sewage treatment plant, and a small sewage treatment plant in which the disk filter 20 does not need to be installed is as described above. It is possible to remove the suspended matter by the same screen (15).

Although the above configuration and operation description are shown and described only with respect to the preferred embodiments of the present invention, design changes can be made as many as necessary by those skilled in the art without departing from the technical idea described in the description of the present invention. It is obvious that modifications should be made within the scope of the claims, which are bound by the claims of the present invention described below, as well as equivalent techniques.

As described above, the water level control structure of the water channel according to the present invention can be easily installed without any difficulty in the existing water channel of the sewage treatment plant already installed, and there is no cost because it does not require installation cost or maintenance cost. However, even if the inflow rate increases sharply, the UV non-sterile zone is prevented from occurring due to the rapid rise of the water level.

In addition, since the water level control dam was installed in consideration of the flow velocity according to the position of the waterway, the dam length inefficiency area where water does not overflow does not occur, so the dam level is effectively prevented by using the entire dam length efficiently. Has

In addition, it is possible to increase the sterilization efficiency by preventing the water level increase in the UV lamp area by the water level preventive plate, and it is easy to clean the waterway by randomly discharging the water stored in the water level control dam, and the pretreatment process of the waterway Even in a small sewage treatment plant without an in-filter installation, since floating matters are removed by a screen that can be easily inserted and removed, it has an effective effect of preventing malfunction and damage of the ultraviolet lamp.

1 is a perspective view schematically showing a water channel to which another water leveling structure is applied to the present invention;

Figure 2 is a partial plan view of Figure 1 for explaining the structure of the water level control dam according to the present invention.

Figure 3 is a plan view of the channel to which the water level control structure according to another embodiment of the present invention.

4 is a side cross-sectional view of the FIG. 3 embodiment.

5 is a perspective view conceptually showing another embodiment of the present invention.

Figure 6 is a schematic installation state of the level control dam according to the prior art.

Figure 7 and Figure 8 is a structure and explanatory diagram of another level control dam according to the prior art.

Claims (6)

In the sewage canal, a UV sterilizer equipped with a plurality of UV lamps is installed at the top, bottom, left and right, and at the rear of the sewage treatment plant having a predetermined height for the entire width of the canal and a zigzag level control dam. In the channel, The water level control dam is disposed in the front of the water channel as it is closer to the inner wall of the water channel in consideration of the sewage flow rate according to the frictional resistance of the sewage and the side wall in the water channel, and is arranged in the rear side as far as it is, so that the line connecting the tip of the bent portion is an arch curve. Water level control structure for the high efficiency UV sterilizer, characterized in that made of. delete delete delete delete The method according to claim 1, The water level control structure of the channel for the high-efficiency UV sterilizer, characterized in that at least one drain valve is installed at a predetermined position on the bottom of the water level control dam.