KR910001959Y1 - Upflow efflux apparatus of water bed - Google Patents

Abstract

No content.

Description

Supernatant Outflow Device of Cross-flow Chemical Substrate Battery

1 is a plan view of the chemical needle battery is installed device.

Figure 2 is a longitudinal cross-sectional view of the chemical needle battery is installed device.

Figure 3 is an enlarged view of part "A" of Figure 2 showing the configuration and action of the supernatant outlet, which is the main part of the device of the present invention.

* Explanation of symbols for main parts of the drawings

1: Inflow of raw water 2: Outflow of top water

3: flow process wall 3a: rectification hole

4: flocculation paper 5: sedimentation basin

6: supernatant outflow trap 10: supernatant outflow

11 channel 12 fixed water inlet

13 variable inlet 13a: fixed tube

13b: screw groove 13c: funnel type inlet

13d: Vertical connector 13e: Adjustment handle

13f: Vertical adjustment bar P1, P2: Upper water flow section

The present invention relates to a device for discharging supernatant of a crossflow type chemical sedimentation battery. In particular, a rectification hole is formed only in a lower portion of the perforated rectifying wall installed at the inlet of the crossflow type chemical sedimentation battery. It relates to a supernatant outflow device of a cross-flow type drug settler to improve the sedimentation efficiency of the drug settler by allowing the supernatant water to be introduced into the upper part of the supernatant inlet and having a flow rate control device installed therein.

The chemical settler is installed to reduce the burden on the subsequent rapid filter paper by removing most of the large and heavily grown flocks by injecting, admixing and floc forming chemicals through the mixed paper by precipitation separation. . In general, the chemical precipitator installed generally divides the middle part of the rectangular sedimentation basin where the raw water inlet and the supernatant water outlet are disposed at both ends in the longitudinal direction by vertical vertical process flow walls, and the one side of the rectification wall, that is, the raw water inlet side, is agglomerated paper. A sedimentation basin is used as the sedimentation basin on the other side, that is, the raw water that has passed through the rectifying wall, and an outlet trap for discharging the floc precipitated sediment, that is, the supernatant, into the outlet. .

However, in the conventional cross-flow type chemical sedimentation battery as described above, the rectifying holes formed in the oil process flow wall are disposed at equal intervals over the entire surface of the rectifying wall so that the raw water flowing into the inside of the sedimentation basin through the rectifying holes is flow rate in the sedimentation basin. Although there are differences depending on the turbidity, most of the flocs contained in the inflow water do not settle until the outlet end of the sedimentation basin, i.e., the outflow trap installation region, is disposed. Since it is discharged to the sediment effluent through the effluent trap having a certain standard, there is a disadvantage that the residence time of the influent water is lengthened and the sedimentation efficiency is lowered due to the restriction of the supernatant effluent area of the sedimentation basin.

In addition, the supernatant discharged as described above is unable to control the flow rate according to the fluctuation of the water level of the sedimentation basin, so that the freezing of the supernatant does not occur during the freezing of the winter, and when the water surface is frozen, the ice pressure of the sedimentation basin structure As it is delivered to the wall as it is, there is a problem such as having a damage factor of the structure.

Therefore, the main object of the present invention is to provide a supernatant outflow device of the drug settler battery does not have the above disadvantages and problems.

Another object of the present invention is to provide a dead space in which the supernatant can be introduced above the raw water inlet of the sedimentation basin in which the rectifying wall is installed, and a separate supernatant outflow device is installed in the rectifying area, thereby providing a normal outflow. In parallel with the outflow of the supernatant by the pump, it is possible to provide a predetermined amount of the supernatant in the rectifying area, thereby providing a supernatant outflow device of the cross-flow chemical impregnation battery that can greatly improve the sedimentation efficiency of the sedimentation area.

It is another object of the present invention to provide a supernatant outflow device of a cross flow type chemical sedimentation basin capable of adjusting the outflow location of the supernatant and the outflow location and the outflow amount according to the fluctuation of the sedimentation basin level.

Still another object of the present invention is to provide a supernatant outflow device for a cross-flow chemical sedimentation basin that can eliminate the damaging factors of the sedimentation basin structure by absorbing the ice pressure caused by ice freezing through the supernatant outflow basin.

Hereinafter, the present invention for achieving the above object will be described in detail by the accompanying drawings.

1 and 2 are a plan view and a cross-sectional view showing the overall configuration of the sedimentation basin in which the supernatant outflow device is installed according to the present invention, as shown in FIG. It is disposed at both ends, and the middle part thereof is divided into a vertical flow stream wall 3 to be separated into a flocculation basin 4 and a sedimentation basin 5, and flows into the upper part of the sedimentation basin 5 above the outflow side end of the sedimentation basin 5. In the cross-flow type chemical immersion battery provided with an outflow trap 6 for discharging the supernatant water to the supernatant outflow tank 2, the supernatant water outlet device according to the present invention includes a rectifying hole 3a formed in the oil process flow wall 3. It is disposed only in the middle lower portion of the vertical rectifying wall 3, and the raw water flowing out of the flocculating paper 4 flows into the settling basin 5 through the rectifying hole 3a below the rectifying wall 3, , On the upper side of the raw water inlet of the sedimentation basin 5, that is, the rectifying hole 3a is not formed. A dead space in which the supernatant water flows is formed in the upper side of the rectifying wall 3, and the upper portion of the upper water inlet, that is, the upper side of the rectifying wall 3 adjacent to the rectifying wall 3, is disposed on the upper side of the rectifying wall 3. 10 is installed. The supernatant runner 10 has a certain width and depth A channel 11 having a cross section is disposed between the front and rear inner walls 5a and 5b of the unit settler 5 at a distance from the upper end of the rectifying wall 3 along the longitudinal direction of the rear wall 5b. The channel 11 of the effluent stream 10 is installed in an L-shape over and one end of the channel 11 is connected to the supernatant effluent stream 2, and is installed in parallel with the flow process flow wall (3). As shown in FIG. 3, a plurality of fixed submersible inlets 12 into which the supernatant is introduced and variable inlets 13 which can be adjusted in height according to the level of the sedimentation basin are provided in the lower side of each side wall, respectively. Therefore, they are installed at equal intervals.

Each of the fixed submersible inlets 12 is provided with a flow control valve 12b at the inner end of the inlet pipe 12a, which is introduced into the outlet channel 11, and the valve 12b is exposed to the upper surface of the water surface. By operating the handle 12d of the upper end of the vertical valve rod (12c) can be adjusted to open and close. In addition, the variable inlet 13 is installed on the opposite side is one end of the horizontal portion of the fixed tube 13a bent in an L-shape is fixed to the lower side of the one side wall of the channel 11 is formed on the top of the vertical portion of the fixed tube (13a) The lower end of the vertical connecting pipe 13d having the funnel-type inlet 13c is connected to the screw groove 13b by screwing, and the adjustment handle 13e is located above the inner circumferential wall of the funnel-type inlet 13c. The lower end of the vertical adjustment bar (13f) having a) is fixed by the + -shaped support section (13g), it is possible to adjust the lifting and lowering funnel-type inlet (13c) in accordance with the rotation operation of the control bar (13f).

In the figure, reference numeral 7 denotes a process flow stream wall installed in the raw water inlet portion of the reception 4, 4a and 4b are partition walls installed in the interior of the aggregation 4, 8a, 8b, 8c is a stirrer for reception, 1a shows the raw water inlet valve of the raw water inlet 1, 9 shows the sludge outlet for the sedimentation basin 5, respectively.

The working effect of the subject innovation supernatant outflow device configured as described above is as follows.

When the raw water flowing into the raw water inlet 1 is introduced into the agglomerate 4 through the raw water inlet valve 1a and the process flow flow wall 7, the agglomerate 4 partitioned into partitions 4a and 4b. The circulation of the floc is promoted during the circulation of the inside, and the raw water containing the grown floc is introduced into the sedimentation basin 5 through the rectifying hole 3a formed under the intermediate rectifying wall 3. Inflow is as known.

However, the raw water introduced into the sedimentation basin 5 in this way forms an upward water flow in the inclined direction at the inlet inner section and flows toward the supernatant outlet 2 side, and thus the flow contained in the inflow water. In the outflow process as described above, the tank is settled while drawing a parabola as shown in the direction of the arrow in FIG. 2, and thus is formed in the upper portion of the raw water inlet side of the sedimentation basin 5 in which the flow path wall 3 is installed. Each of the upper water flow portions P1 and P2 constituting a cross section of an equilateral triangle is formed at the upper portion of the outlet side where the dead space portion and the outlet trap 6 are installed.

Therefore, the supernatant flowed into the supernatant flow part P1 (P2) as described above is transferred to the supernatant outlet 2 through the supernatant outlet 10 of the raw water inlet side and the existing outlet trap 6 according to the present invention. At the same time, the outflow efficiency of the supernatant can be greatly increased by the outflow, and the process of outflow of the supernatant by the supernatant discharge device of the present invention will be described in more detail as follows.

As shown in FIG. 3, the supernatant introduced into the upper portion of the raw water inlet of the sedimentation basin 5 is channeled through the respective inlets 12 and 13 formed on both side walls of the channel 11 of the supernatant outlet 10 of the present invention. (11) is introduced into the bar, at this time, the fixed water inlet 12 is located in the water, so that the flow control valve (12b) in the open state regardless of the water level of the settling basin (5) at any time The supernatant can be discharged, and the flow rate of the supernatant can be reduced or blocked by the operation of the valve 12b, and the variable inlet 13 on the other side is rotated by the vertical adjustment rod 13f. Since the opening position of the upper funnel type inlet portion 13c with respect to the water surface can be adjusted up and down by elevating and adjusting the connecting position of the connecting tube 13d connected to the upper end of the lower fixing tube 13a by screwing. Of sedimentation basin (5) It is possible without regard to the above changes could spill a quantity of supernatant.

On the other hand, the supernatant outflow basin 10 of the present invention having the above-described action is L over the left and right directions of the front and rear inner circumferential wall (5a) (5b) and the rear circumferential wall (5b) of the sedimentation basin (5). Since it is arranged in a shape, ice pressure applied to the wall surface of the sedimentation basin 5 during winter ice is simultaneously applied to both side walls of the channel 11 of the sedimentation basin 10 and the wall of the sedimentation basin 5. By absorbing the ice pressure acting on the wall surface of (5), it is possible to exclude the fear of damage to the structure of the settling basin 5, that is, the wall surface caused by the freezing of the water surface.

In the present invention as described above, in the outflow of the supernatant of the sedimentation basin, rectification holes are formed only in the middle lower portion of the flow path of the flow of flow of raw water in the flocculation basin so that the raw water flows into the depth of the sedimentation basin. The upper water flow portion formed at the upper end of the water surface of the adjacent sedimentation basin is formed separately from the upper water flow portion formed at the discharge side end of the sedimentation basin. Since it is configured by installing the supernatant outflow basin which can control the sediment, the capacity of the sedimentation basin can be increased even though the total capacity of the sedimentation basin is reduced in proportion to the amount of outflow by the supernatant outflow basin of the present invention. And thus contribute to the production of supernatant The sedimentation efficiency of the sedimentation basin can be greatly improved.In particular, the flow rate of the supernatant can be adjusted according to the level change of the sedimentation basin.In case of freezing of the water, it is possible to control the outflow and flow rate of the supernatant through the fixed water inlet. By absorbing the applied ice pressure, it is possible to eliminate the damage factor of the sedimentation basin due to freezing of the water surface.

Claims (2)

The raw water inlet 1 and the supernatant outlet 2 are divided into a flow stream 3 and separated into a contact 4 and a sedimentation basin 5, which are formed above the outflow side end of the sedimentation basin 5. In the horizontal flow type chemical needle battery in which the outflow trap 6 is installed in the upper flow section P2, the rectifying hole 3a formed in the flow path flow wall 3 is provided only at the middle lower portion of the rectifying wall 3. The upper stream current portion P1 is formed above the inflow portion of the sedimentation basin 5 adjacent to the rectifying wall 3, and the plurality of fixed water inflow portions 12 and the variable inflow portion 13 are formed at the upper flow portion P1. The supernatant outflow trap 10 disposed on both side walls of the channel 11 across the front and rear circumferential walls of the sedimentation basin 5 and disposed along the rear wall of the sedimentation basin 5. The upper shoe outflow device of the cross-flow type chemical needle battery, characterized in that configured to connect the outlet side of the pump (10) to the upper water outlet (2). According to claim 1, The variable inlet 13 of the upper water outlet trap 10 is a vertical connection pipe having a funnel type inlet (13c) in the screw groove (13b) of the upper end of the fixed tube (13a) bent in a shape ( 13d) is connected to the lower end of the screw coupling, the inlet portion (13c) is connected to the lower end of the vertical adjustment rod (13f) having an adjustment handle (13e) connected to the upper water discharge device of the cross-flow chemical needles.