KR20130025106A - Coagulant mixing method by using weir mixing device and baffle - Google Patents

Abstract

PURPOSE: A mixing method of coagulant using Weir styled scrambler and baffle is provided to efficiently remove material such as nitrogen by maximizing coagulant admixture efficiency, reduce maintenance cost and is easy to manage by comprising through structural configuration. CONSTITUTION: A coagulant mixing method for removing nitrogen etc by installing in the settling pond of sewage disposal plant comprises the following steps: a step of distributing and supplying coagulant from drug dispersion group(102) through coagulant dispensing tube to several nozzles; a step of supplying pressurized water to one side of each nozzle through pressurized water feeding line; a step of spraying coagulant and pressurized water on top of Weir style scrambler(201) installed zigzag at one side of supporting wall which is installed at settling pond waterway; a step of admixture agglomerating by Weir style scrambler; and a step of passing several baffles(202,203) installed in the settling pond waterway.

Description

Coagulant Mixing Method by using Weir Mixing Device and Baffle}

The present invention relates to the rapid mixing of chemicals introduced in sewage treatment plants and water purification plants. In general, the sewage treatment plant collects contaminated sewage and sends it to the sedimentation basin, and is transferred to the first sedimentation basin at the sedimentation basin. The treated sewage is composed of the process of discharged back to the stream. The present invention relates to the effective removal of substances such as phosphorus, nitrogen by installing a weir type mixer and baffle in the sedimentation basin which is a passage for transferring sewage from the sedimentation basin to the sedimentation basin.

Prior art related to the present invention is shown in FIG. In the conventional rapid mixing system using a conventional drop as shown in FIG. 1, the treated water introduced into a treatment facility such as a landing well and a sedimentation basin is provided with a weir 11 for the purpose of maintaining a constant water level. Perforated pipe 12 is configured to be introduced into the treated water flows through the weir (11) to form a water flow drop, through the porous pipe 12 is formed a number of chemical discharge holes in the upper part of the chemical at regular intervals It is configured to rapidly mix chemicals and treated water. In the conventional water flow drop mixing system configured as described above, when the treated water drops the chemical at regular intervals using the porous tube 12 having a plurality of drug discharge holes formed in the water flow drop portion formed while passing through the weir 11, Water and chemicals are rapidly mixed by turbulence generated by the dropping in the retention tank 13, and then mixed with the retention tank 13 for a predetermined time, and then run through the outflow water pipe 14 to the next process. It is.

      The conventional water flow drop mixing system as described above is a method of mixing the drug using turbulence generated when the treated water passes through the weir 11 and falls into the retention tank 13, so that weirs are required to generate the appropriate turbulence required for mixing. There should be a drop of a certain height between the (11) and the holding tank 13, the drop is generated by the air bubbles accompanying the formation of turbulence, so that the injected chemical is adsorbed to the bubble in the process of mixing with the treated water There is a problem in that the scum 16 is formed while the floating tank 13 floats on the water surface, thereby lowering the chemical efficiency. Further, the bubbles 15 that do not rise in the retention tank 13 are along the outflow water pipe 14. As it flows, it accumulates in a certain upper portion of the outlet conduit 14, causing air padding to form large air masses, which discharge the treated water in a natural flow manner. While gradually growing in the outflow conduit 14 to hinder the flow of the treated water, consequently reducing the flow rate flowing inside the outflow conduit 14, raising the level of the retention tank 13, excessively grown air The padding 17 has a problem that water shock generated when it is discharged to the atmosphere from the inlet or outlet of the outlet water pipe 14 causes the level of the retention tank 13 to act as a disturbing factor for uniform and continuous chemical input. will be.

Therefore, in the flocculant mixing method using the weir type mixer and baffle of the present invention, the weir type mixer is installed on one side of the weir overflowing with the inflow water, and the sewage passed through the weir type mixer is subjected to the sewage again through a baffle installed in the sedimentation basin. It is for changing a flow path and improving cohesive agent mixing cohesion efficiency.

The coagulant mixing method using the weir mixer and baffle of the present invention for solving the problems of the prior art as described above, dispensing and supplying the coagulant to each vortex nozzle through the coagulant distribution tube in the chemical distribution tank, pressurized water Supplying pressurized water to one side of the vortex nozzle through a supply pipe, and coagulant and pressurized water at the vortex nozzle on the weir type mixer 201 installed in a zigzag on one side of the support wall 220 installed in the sedimentation basin. And spraying the treated water passing through the weir mixer and passing the plurality of baffles installed vertically or horizontally in the sedimentation basin channel so that the flocculant is effectively mixed and aggregated in the treated water. It is.

The coagulant admixture method using the weir type admixture and baffle of the present invention configured as described above has the effect of efficiently removing substances such as phosphorus and nitrogen by maximizing the coagulant admixture efficiency. In addition, the coagulant admixture method using the weir type admixture and baffle of the present invention is made through a structural configuration is that the maintenance is convenient and the maintenance cost is reduced.

자형 혼화판의 작용 설명도,
도 8은 본 발명에 적용된 혼화판을 구비한 위어식 혼화기의 절개 사시도,
도 9는 본 발명 제1실시 예인 위어식 혼화기와 배플을 이용한 응집제 혼화 시스템 전체 구성도,
도 10은 본 발명 제2실시 예인 배플을 이용한 응집제 혼화 시스템 전체 구성도이다.1 is a block diagram of a rapid mixing system using a conventional drop,
2 is an overall configuration diagram of a multi-vortex nozzle mixing system applied to the present invention;
Figure 3 is a cross-sectional configuration of the multi-vortex nozzle applied to the present invention,
Figure 4 is a cross-sectional configuration of the weir blender applied to the present invention,
5 is a configuration diagram showing a mixing plate arrangement state of the weir mixers applied to the present invention,
6 is a bubble flow chart of the mixing plate composed of a multi-layer in the weir blender applied to the present invention,
7 is applied to the present invention

Explanatory drawing of the action of the female-shaped mixing plate,
Figure 8 is a cutaway perspective view of the weir mixer with a mixing plate applied to the present invention,
9 is an overall configuration diagram of a flocculant admixture system using a weir type mixer and baffle of the first embodiment of the present invention;
10 is an overall configuration diagram of a flocculant admixture system using a baffle of a second embodiment of the present invention.

Referring to the present invention having the above object with reference to Figures 2 to 10 as follows.

2 is an overall configuration diagram of a multi-vortex nozzle 101 mixing system applied to the present invention. In FIG. 2, the multiple vortex nozzle mixing system applied to the present invention supplies a manifold 110 to which the multiple vortex nozzles 101 are connected, and pressurized water to the plurality of multiple vortex nozzles via the manifold 110. Chemicals that distribute the amount of coagulant supplied from the pressurized water supply pipe 309 and the coagulant supply pipe 103 to the multi vortex nozzle 101 through the coagulant distribution tube 105 by distributing the installed quantity of the multi vortex nozzle 101. Consisting of the distribution tank 102 and the multiple vortex nozzle 101 for injecting and mixing the flocculant with the vortex generated in the process of spraying the pressurized water supplied to the manifold 110 toward the treated water and sprayed into the treated water. It is showing.

3 is an overall cross-sectional view of the multi-vortex nozzle 101 applied to the present invention. In FIG. 3, the multi-vortex nozzle 101 applied to the present invention is supplied by splitting and supplying the chemicals by the installation quantity of the multi-vortex nozzle 101 in the chemical distribution tank 102, and the radially introduced into the upper cap 141. Flows into the interior of the upper housing 143 along the furnace 142, and then flows into the nozzle 144 through the vertical notch 145 processed at each nozzle 144, and finally the nozzle outlet 149. The pressurized water supplied from the manifold 110 is supplied to the lower housing 146 through the pressurized water supply pipe 309 and then the vortex induction path 147 and the vortex generating room 148. It is to be injected into the treated water while forming the vortex via.

자형 혼화판(205)과, 상기 각각의

자형 혼화판(205)의 내부 일측에 구성된 기포 배출구(206)와, 상기 기포 배출구(206)에서 배출된 기포를 외부로 배출하기 위한 기포 상승통로(204)로 구성되는 것을 나타내고 있는 것이다. 상기와 같이 구성된 혼화판을 구비한 위어식 혼화기는 위어(210)를 통과한 처리수가 혼화 챔버(201)로 떨어지고, 상기 혼화 챔버(201)로 유입된 처리수는 지그 재그이면서, 다층으로 설치된

자형 혼화판(205) 사이를 흐르게 되는 것이다. 상기와 같이 지그 재그로 다층으로 형성된

자형 혼화판(205) 사이를 통과하는 처리수는 분리되고 합해지는 과정을 반복적으로 하게 되므로 혼화 효율이 향상되는 것이며, 또한 위어(210)의 낙차에서 발생한 기포는

자형 혼화판(205)의 내부 상층부로 모이게 되고, 상기

자형 혼화판(205)의 내부 상층부에 모인 기포는 기포 배출구(206)를 통하여 기포 상승통로(204)로 유입되어 외부로 배출되는 것이다. Figure 4 is a cross-sectional configuration of the weir blender applied to the present invention. In FIG. 4, the weir type mixer 201 applied to the present invention includes a weir 210 formed on an upper portion of the support wall 220 installed on the initial settler channel, and a mixing chamber in which the treated water passing through the weir 210 is obtained. 201) and a plurality of zigzags are installed below the mixing chamber 201.

Shape mixing plate 205 and the respective

It is shown that the bubble discharge port 206 formed on one inner side of the magnetic mixing plate 205 and the bubble rising passage 204 for discharging the bubbles discharged from the bubble discharge port 206 to the outside. The weir type mixer having the mixing plate configured as described above is treated with water that has passed through the weir 210 to the mixing chamber 201, and the treated water introduced into the mixing chamber 201 is zigzag and installed in multiple layers.

It is to flow between the magnetic mixing plate (205). Zig-zag as described above formed in a multilayer

Since the treated water passing through the magnetic mixing plate 205 is repeatedly separated and combined, the mixing efficiency is improved, and the bubbles generated in the drop of the weir 210 are

Gathered into the inner upper layer of the magnetic compound plate 205,

Bubbles collected in the inner upper layer of the magnetic mixing plate 205 is introduced into the bubble rising passage 204 through the bubble discharge port 206 and discharged to the outside.

자형 혼화판(205)은 지지벽(220)에 설치되는 것으로 지그 재그로 설치되고, 처리수는 상기

자형 혼화판(205) 사이들을 통과하면서 분리와 혼합이 자동으로 이루어질 수 있는 구조이고, 따라서 투입된 약품이 효과적으로 혼화할 수 있는 구조임을 나타내고 있는 것이다. 또한 상기

자형 혼화판(205)은 하부가 개방되고 상부가 막힌 구조이며 내부 상층부에 기포 배출구(206)가 형성된 구조로 위어(210)의 낙차로 인하여 발생한 기포가 상기

자형 혼화판(205) 내부로 모일 수 있는 것을 나타내고 있는 것이다. 5 is a configuration diagram showing a mixing plate arrangement state of the weir mixers applied to the present invention. 5 applied to the present invention

The magnetic mixing plate 205 is installed in the support wall 220 in a zigzag, and the treated water is

It is a structure that can be separated and mixed automatically while passing between the shape of the mixing plate 205, and thus indicates that the injected chemicals can be effectively mixed. Further,

The magnetic mixing plate 205 has a structure in which the lower part is opened and the upper part is blocked, and the bubble outlet 206 is formed in the inner upper layer.

It shows what can be gathered in the inside of the magnetic compound board 205. FIG.

자형 혼화판(205)은 다층으로 구성되는 것으로 위어(210)의 낙차에 의하여 혼화 챔버(201)로 떨어진 처리수는 상기

자형 혼화판(205) 사이를 흐르게 되고, 상기와 같이

자형 혼화판(205) 사이를 흐르는 동안 발생된 기포는 상기 각각의

자형 혼화판(205)의 하부 개방부를 통하여

자형 혼화판(205)의 내부로 유입되고 상층부에 모이는 것을 나타내고 있는 것이다. 상기와 같이

자형 혼화판(205)의 내부 상층부에 모인 기포는 일정 크기로 성장한 후 기포 배출구(206)를 통하여 기포 상승통로(204)로 유입되고 외부로 배출되는 것이다. 상기에서

자형 혼화판(205)의 내부 상층부 일측은 경사판(209)을 구성하여 기포가 배출되지 않고 체류하는 사구역을 줄이기 위한 것이다.Figure 6 is a bubble flow chart of a mixing plate composed of multiple layers in the weir blender applied to the present invention. 6 of the weir type mixer applied to the present invention in FIG.

The magnetic mixing plate 205 is composed of multiple layers, and the treated water dropped into the mixing chamber 201 by the drop of the weir 210 is the above.

It flows between the female mixing plate 205, as described above

Bubbles generated while flowing between the magnetic mixing plates 205 are

Through the lower opening of the magnetic mixing plate 205.

It shows that it flows into the inside of the female mixing plate 205, and collects in an upper layer part. As above

Bubbles gathered in the inner upper layer of the magnetic mixing plate 205 grows to a predetermined size and then flows into the bubble rising passage 204 through the bubble outlet 206 and is discharged to the outside. From above

One side of the inner upper layer of the magnetic compound plate 205 constitutes the inclined plate 209 to reduce the dead zone where bubbles are not discharged.

자형 혼화판의 작용 설명도이다. 상기도 7에서

자형 혼화판(205) 사이를 하부로 흐르는 처리수는 분리와 혼합과정을 거치게 되고, 상기

자형 혼화판(205)의 하부 개방부(230)를 통하여 내부로 유입되고,

자형 혼화판(205)의 내부로 유입된 기포는 상층부(231)로 모이에 되는 것이다. 상기와 같이

자형 혼화판(205)의 내부 상층부(231)에 모인 기포는 일정 크기로 성장한 후 기포 배출구(206)를 통하여 기포 상승통로(204)로 유입되어 외부로 배출되는 구조인 것이다.7 is applied to the present invention

It is explanatory drawing of the operation of a female mixing plate. In FIG. 7 above

The treated water flowing downwards between the magnetic mixing plate 205 is subjected to the separation and mixing process,

Is introduced into the inside through the lower opening 230 of the magnetic mixing plate 205,

Bubbles introduced into the shape-mixing plate 205 are collected at the upper layer portion 231. As above

Bubbles collected in the inner upper layer part 231 of the magnetic mixing plate 205 are grown to a predetermined size and then flow into the bubble upward passage 204 through the bubble outlet 206 and are discharged to the outside.

자형 혼화판(205)이 다층으로 지그 재그로 형성되는 구조이고, 상기

자형 혼화판(205)의 상부 일측에는 기포 배출구(206)가 형성되는 구조이며, 상기 기포 배출구(206)는 기포 상승통로(204)와 연결되는 구조이다. 상기와 같이 구성된 혼화판을 구비한 위어식 혼화기는 혼화 챔버를 통과한 처리수가 상기

자형 혼화판(205) 사이를 통과하며, 이 과정에서 기포는

자형 혼화판(205)의 하부 개방부를 통하여

자형 혼화판(205)의 내부 상층부에 모이게 되고, 이렇게 모인 기포는 일정 크기로 성장한 후 기포 배출구(206)를 통하여 기포 상승통로(204)로 유입되고 상기 기포 상승통로(204)로 유입된 기포는 외부로 배출되는 것이다. 상기에서 기포 배출구(206)는 사각형으로 구성할 수도 있고 원형으로도 구성할 수 있는 것이다.Figure 8 is a cutaway perspective view of a weir mixer with a mixing plate applied to the present invention. In FIG. 8, the weir type mixer is fixedly installed on the support wall 220.

The magnetic mixing plate 205 is a structure formed by zigzag in multiple layers.

The upper one side of the magnetic mixing plate 205 is a structure in which a bubble outlet 206 is formed, the bubble outlet 206 is connected to the bubble rising passage 204. Weir type mixer having a mixing plate configured as described above is treated water that passed through the mixing chamber

Passes between the male and female mixing plate 205, in the process bubble

Through the lower opening of the magnetic mixing plate 205.

Gathered in the upper upper portion of the magnetic mixing plate 205, the collected bubbles grow to a predetermined size and then flows into the bubble rising passage 204 through the bubble outlet 206 and the bubbles introduced into the bubble rising passage 204 is It is discharged to the outside. The bubble outlet 206 in the above may be configured as a square or may be configured in a circular shape.

       9 is an overall configuration diagram of a flocculant admixture system using a weir type mixer and baffle which is the first embodiment of the present invention. In FIG. 9, the flocculant mixing system using the weir type mixer and the baffle pumps the pressurized water using the pressurized water pump 308 in the sedimentation basin and enters each vortex nozzle 101 through the pressurized water supply pipe 309. Will be. In addition, the coagulant is supplied to the drug distribution tank 102 through the coagulant supply pipe 103, and is connected to the plurality of vortex nozzles 101 through the coagulant distribution tube 105 in the drug distribution tank 102, respectively It is to dispense chemicals such as flocculant in the nozzle. In addition, the flocculant introduced into each of the nozzles 101 is sprayed into the treated water together with the pressurized water introduced into the nozzle to rapidly admix with the treated water in the first step. In addition, the flocculant sprayed from each vortex nozzle 101 installed in the sedimentation basin channel as described above may further improve the mixing efficiency through a two-step mixed flocculation process through which the weir type mixer 201 passes. In addition, the treated water passing through the weir type mixer 201 may further improve the mixing efficiency due to passing through the baffles 202 and 203 installed in the sedimentation basin channel, which is the third step of mixing and flocculation. will be. In addition, the coagulant mixing method using a weir mixer and baffle as the first embodiment of the present invention as described above, distributing and supplying the coagulant to each vortex nozzle through the coagulant distribution tube in the chemical distribution tank, and through the pressurized water supply pipe Supplying pressurized water to one side of the vortex nozzle, and injecting coagulant and pressurized water from the vortex nozzle onto the weir type mixer 201 installed in a zigzag on one side of the support wall 220 installed in the sedimentation basin. And aggregating and agglomerating by the weir type mixer installed by the jig jag, and changing the flow path while passing through the plurality of baffles installed by the zig zag vertically or horizontally in the settler channel through the weir type mixer. Is characterized in that it comprises the step of effectively admixing agglomeration in the treated water. In addition, in FIG. 9, one side of the pressurized water supply pipe 309 includes a pressure sensor 302 and a pressure sensor transmitter 303 for transmitting a signal of the pressure sensor to the control panel 307. The flow rate sensor 304 and the flow rate sensor transmission part 305 for transmitting the sensor signal of the flow rate sensor to the control panel 307 are shown.

       10 is an overall configuration diagram of a flocculant admixture system using a baffle of a second embodiment of the present invention. In FIG. 10, the flocculant mixing system using the baffle of the second embodiment of the present invention pumps the pressurized water by using the pressurized water pump 308 in the sedimentation basin and presses each vortex nozzle 101 through the pressurized water supply pipe 309. It will flow into. In addition, the coagulant is supplied to the drug distribution tank 102 through the coagulant supply pipe 103, and is connected to the plurality of vortex nozzles 101 through the coagulant distribution tube 105 in the drug distribution tank 102, respectively It is to dispense chemicals such as flocculant in the nozzle. In addition, the flocculant introduced into each of the nozzles 101 is sprayed into the treated water together with the pressurized water introduced into the nozzle to rapidly admix with the treated water in the first step. In addition, the flocculant sprayed from each vortex nozzle 101 installed in the sedimentation basin channel as described above passes through a plurality of baffles 202 and 203 installed in the sedimentation basin channel, which is a third step of agglomeration flocculation process. Can be further improved. In addition, the flocculant mixing method using a baffle according to the second embodiment of the present invention, dispensing the coagulant to each vortex nozzle through the coagulant distribution tube in the chemical distribution tank, and pressurized water through the pressurized water supply pipe to each vortex Supplying to one side of the nozzle, injecting coagulant and pressurized water from the vortex nozzle to one side of the support wall 220 installed in the sedimentation basin into which sewage treated water flows, and zigzag vertically or horizontally to the sedimentation basin It is characterized in that it comprises a step of changing the flow path while passing through a plurality of baffles installed therein to cause the flocculant to effectively mix and flocculate in the treated water.

The coagulant admixture using the weir type admixture and baffle of the present invention configured as described above is capable of effectively removing substances such as total phosphorus, nitrogen, etc. by maximizing the coagulant admixture by constituting the admixing agglomeration process in multiple stages.

11, 210: weir, 12: porous tube,
13: retention tank, 14: water pipe,
101: vortex nozzle, 102: chemical distribution tank,
110: manifold, 141; Upper cap,
142: inflow path, 144: nozzle,
145: vertical notch, 147: vortex induction furnace,
148: vortex generation chamber, 149: nozzle outlet,
201: mixing chamber, 202, 203: baffle,
205: mixed plate, 206: bubble outlet,
220: support wall, 309: pressurized water supply piping

Claims (7)

In the flocculant admixture method for removing total phosphorus and nitrogen by installing in sedimentation basin of sewage treatment plant,
The flocculant blending method,
Dispensing and supplying the flocculant to the plurality of nozzles through the flocculant dispensing tube in the medicine dispensing tank;
Supplying pressurized water to one nozzle through a pressurized water supply pipe;
Spraying coagulant and pressurized water from the respective nozzles onto the weir type mixer 201 installed in a zigzag on one side of the support wall 220 installed in the sedimentation basin;
Agglomerated by a weir mixer;
And a step of allowing the treated water passing through the weir mixer to pass through a plurality of baffles installed in the sedimentation basin channel.
The method of claim 1,
Many of the baffles installed in the sedimentation channel,
A flocculant admixture method using a weir blender and baffle characterized in that the step of passing through the baffle is installed in a number of zigzag vertically or vertically or left and right in the sedimentation basin.
The method of claim 1,
Injecting the flocculant and the pressurized water in each nozzle,
A vortex mixing method using a weir type mixer and baffle, characterized in that the step of forming and spraying the vortex by the vortex induction furnace and the vortex generating chamber formed in each nozzle.
The method of claim 1,
The step of agglomeration of the admixture by the weir mixer,
The weir type mixer is a coagulant mixing method using a weir type mixer and baffle, characterized in that the support wall 220 is installed in a zigzag.

In the flocculant admixture method for removing total phosphorus and nitrogen by installing in sedimentation basin of sewage treatment plant,
The flocculant blending method,
Dispensing and supplying the flocculant to the plurality of nozzles through the flocculant dispensing tube in the medicine dispensing tank;
Supplying pressurized water to one nozzle through a pressurized water supply pipe;
Spraying coagulant and pressurized water from each nozzle to one side of the support wall 220 installed in the sedimentation basin;
And a step of passing through a plurality of baffles installed in the sedimentation basin channel.
The method of claim 5,
Passing through a plurality of baffles installed in the sedimentation channel,
A coagulant admixture using a weir blender and a baffle, characterized in that it passes through a plurality of baffles installed in a zigzag vertically or horizontally in a sedimentation basin.
The method of claim 5,
Injecting the flocculant and the pressurized water in each nozzle,
A vortex mixing method using a weir type mixer and baffle, characterized in that the step of forming and spraying the vortex by the vortex induction furnace and the vortex generating chamber formed in each nozzle.

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