KR100914690B1 - Microbe reactor - Google Patents

Abstract

The present invention is arranged in parallel to the inside of the main body while indenting the bottom of the main body in a conical or polygonal shape in order to improve the mixing force with the waste water inside the main body when forcedly ejecting the raw water containing air flowing into the main body in the downward direction To increase the residence time of the air through the retention delay member, and by adsorbing the inside of the main body to promote the adsorption of microorganisms to promote the decomposition of organic matter and to filter the grown sludge inside the waste water to maximize the microbial activation It relates to a wastewater treatment device.

Wastewater treatment device, retention delay member, adsorption part, media, impeller

Description

Wastewater Treatment System {microbe reactor}

The present invention relates to a wastewater treatment apparatus, and more particularly, to conical or polygonal shape of the bottom of the main body to improve mixing power with the wastewater inside the main body when forcedly ejecting raw water containing air flowing into the main body in a downward direction. In addition to the depression, the residence time of the air is increased through the retention delay members arranged in parallel to the inside of the body, and the adsorption part is placed inside the body to induce the adsorption of microorganisms, thereby promoting the decomposition of organic matter and promoting the growth of the wastewater. The present invention relates to a wastewater treatment apparatus for maximizing microbial activity by filtering sludge.

Conventionally, only livestock wastewater is removed from the livestock wastewater, and the microbial treatment tank is transferred to the original wastewater for biological treatment, or after removing the contaminants from the livestock wastewater, centrifugation is performed again in a centrifuge to remove considerable amounts of organic matter and nitrogen. The pollution load was reduced and then treated in a microbial treatment tank.

The microbial treatment tank removes organic matter and nitrogen from livestock wastewater by using the metabolic activity of microorganisms. In general, the microbial treatment tank is operated by aerobic and anaerobic operation periods for a predetermined time period. Decomposition and nitrification proceeds, and during the anaerobic operation, denitrification and organic matter decomposition proceed, and the nitrogen component in the livestock wastewater becomes N ₂ gas, which is reduced and removed to the atmosphere, thereby decomposing a part of organic matter.

In the Utility Model Registration No. 0415478 registered by the applicant, a high rate microbial reaction stirrer for purifying wastewater and high concentration organic wastewater has been proposed.

1 to 3 is a view showing the wastewater treatment apparatus.

As shown in the drawing, the conventional wastewater treatment apparatus is shaped into a main body 1 partitioned into a denitrification tank 2, an activation tank 4, and a nitrification tank 6.

The main body 1 includes a raw water inlet pipe 12.

At this time, each of the raw water inlet pipe 12 is provided with a raw water control valve 13 to regulate the flow control and flow amount of the raw water.

In addition, the main body 1 is provided with an internal conveying pipe 14 to convey raw water.

At this time, the inner conveying pipe 14 is provided with an inner conveying liquid control valve 15 to control the return of raw water.

In addition, the main body 1 is provided with an air inlet pipe 16 to inject air into the inside and to activate and purify the waste water inside the main body 1 with microorganisms.

In addition, the air inlet pipe 16 is provided with an air control valve 17 to control the flow state and flow amount of air.

In addition, the main body 1 is provided with a discharge pipe (19).

Then, the ejector 30 is provided at a portion where the raw water inlet pipe 12 and the air inlet pipe 16 are combined.

In addition, the main body 1 includes submersible air pumps 42, 44, and 46 inside the reaction tanks 2, 4, and 6, respectively, and submersible air pumps 42, 44, 46 and air inlet pipes. 16 is connected to the air inlet hoses 52, 54, 56.

And, the main body 1 is provided with a sludge discharge port 60 in the lower portion to discharge the sludge generated and sinking during the purification of the waste water to the outside.

On the other hand, the denitration reaction tank 2, the activation tank 4, and the nitrification reaction tank 6 are provided with the guide plate 100 in all or any one inside.

In addition, between the guide plate 100 and the inner wall of each of the reaction tanks 2, 4 and 6, the upper and lower layers communicate with each other to secure the flow path 102 to allow the wastewater treatment liquid to flow.

In particular, the flow paths 102 formed between the guide plates 100 and the inner walls of the reaction tanks 2, 4, and 6 are alternately provided in the up and down directions, thereby reducing the residence time of the waste water between the guide plates 100. Delayed to increase microbial activity.

On the other hand, the guide plate 100 is installed to be inclined symmetrically to each other in the longitudinal direction.

In addition, the main body 1 is provided with a circulation pipe 110 to circulate the wastewater treatment liquid of each of the denitration reaction tank 2, the activation tank 4 and the nitrification reaction tank 6.

In the conventional wastewater and wastewater treatment system for high concentration organic wastewater purification, since raw water mixed with air is sprayed horizontally with respect to the bottom surface of the main body through a pipe, a relatively low specific gravity of air rises at the same time as the spout and discharges the wastewater. There was a problem that the mixing power is lowered, thereby lowering the microbial activity.

The present invention has been made to solve the above problems, an object of the present invention is to form a conical or polygonal cone shape of the bottom of the main body for easy mixing with the waste water when forced ejection of raw water containing air in the vertical direction By forming the bottom depression of the side, and by placing the retardation member in parallel with the inside of the main body to sufficiently increase the residence time of the air and to provide the adsorption unit inside the main body to further increase the microbial activation by attaching sludge. And, by stirring the raw water and air at least twice to maximize the microbial activation to provide a wastewater treatment apparatus to improve the purification rate of the wastewater inside the body.

The present invention for achieving the above object is to store the waste water and form air inlet pipe at the lower side to inject air, and to connect the raw water inlet pipe to the air inlet pipe if necessary to inject the waste water with air The main body having a drain pipe on the bottom surface and connected to the air inlet pipe located inside the main body to purify and discharge the purified wastewater treatment liquid by providing a discharge pipe on the upper side and to discharge the sludge generated during the purification process. Mixing waste water and air in the interior to form an indentation groove in the lower portion and to interfere with the air moving in the upper direction connected to the inside of the main body to be arranged side by side inside the main body to maximize the degree of air activation Wastewater destination comprising a retention delay member for increasing the residence time of the air inside the main body And the device is characterized.

As described above, the microbial reaction stirrer according to the present invention increases the infiltration amount of air into the sludge by the bottom surface recessed into a cone or polygonal shape when spraying raw water mixed with air in the vertical direction, which is the bottom surface direction of the main body. There is an effect of improving the stirring force.

In addition, the present invention has the effect of maximizing the residence time of the air in the waste water by arranging the retention delay member having the recessed grooves at the bottom in the direction perpendicular to each other in the upper and lower layers.

In addition, the present invention is provided with an adsorption unit inside the main body to filter the sludge contained in the waste water has the effect of improving the organic matter decomposition purification power.

Finally, the present invention has the effect of improving the air activation degree by having an impeller self-rotating by the flow of waste water that is ejected inside the body or flows from the top to the bottom direction.

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

Figure 4 is a front view of the wastewater treatment apparatus according to the present invention, Figure 5 is a side cross-sectional view of the wastewater treatment apparatus according to the present invention.

And, Figure 6 is a perspective view showing the installation of the retention delay member provided in the wastewater treatment apparatus according to the present invention, Figure 7 is a state diagram of the adsorption unit installed in the wastewater treatment apparatus according to the present invention, Figure 8 is It is an enlarged view of the stirring part installed in the wastewater treatment apparatus which concerns on this invention.

4 and 5, the wastewater treatment apparatus according to the present invention is divided into a denitrification tank 102, the activation tank 104, the nitrification tank 106 to gradually purify the waste water stored therein ( 100).

The main body 100 is arranged in the transverse direction in order to the denitration reaction tank 102, the activation tank 104, the nitrification reaction tank 106, and each of the reaction tank (102, 104, 106) is provided with one or more.

At this time, the main body 100 is preferably divided into a denitrification tank 102, the activation tank 104, the activation tank 104, the nitrification reaction tank 106 in order.

In addition, the denitrification reaction tank 102 and the activation tank 104, the activation tank 104 and the activation tank 104, and the activation tank 104 and the nitrification reaction tank 106 are connected to the internal circulation pipe 107. do.

In particular, the inner circulation pipe 107 is preferably to transfer the waste water treatment liquid purified in the reaction tank of the immediately preceding stage to the reaction vessel of the immediate stage.

That is, the inner circulation pipe 107 connects the upper side of the denitration reaction tank 102 and the lower side of the activation tank 104, and connects the upper side of the activation tank 104 and the lower side of the subsequent activation tank 104, The upper side of the activation tank 104 and the lower side of the nitrification tank 106 is connected.

Here, the denitrification reactor 102 is a reaction tank for nitrifying the nitrate nitrogen which is nitrified in the stored waste water and returned inside.

In addition, the activation tank 104 is a reaction tank for decomposing organic matter and nitrifying ammonia nitrogen in wastewater introduced after denitrification in a denitrification reaction 102 through an internal circulation pipe 107 for a predetermined time, and the nitrification reaction tank 106. ) Is a reaction tank that denitrates ammonia nitrogen from the wastewater introduced after nitrifying in the activation tank 104 through the internal circulation pipe 107 for a predetermined time to decompose the remaining organic matter.

Thus, the activation tank 104 preferably connects two consecutively in order to sufficiently nitrify the ammonia nitrogen in the waste water.

Of course, the denitrification tank 102 and the nitrification tank 106 are also preferably connected in series.

At this time, the upper portion of the denitrification tank 102 and the lower portion of the activation tank 104 are connected to each other by the circulation pipe 107, likewise, the upper portion of the activation tank 104 and the lower portion of the nitrification reactor 106 are circulation pipe 107 is connected to each other.

Here, the internal circulation pipe 107 sends the wastewater treatment liquid in a denitrification state for a predetermined time to the activating tank 104 in the denitrification tank 102, and in the wastewater introduced from the activating tank 104 After decomposing the organic material for a certain time and nitrifying the ammonia nitrogen, the remaining organic material is flowed into the nitrification tank 106 to activate microorganisms.

In addition, the denitrification reaction tank 102 and the nitrification reaction tank 106 formed at both outermost sides in the main body 100 are connected to the outer circulation pipe 122.

In particular, as the pump 123 is provided on the outer circulation pipe 122, the wastewater treatment liquid in the upper portion of the nitrification reactor 106 is circulated to the inner lower portion of the denitrification reactor 102.

In this case, the wastewater treatment liquid refers to a liquid purified according to microorganism activation in a state in which wastewater, air and raw water are mixed.

In addition, the main body 100 forms an air inlet pipe 116 in the lower circumference, and forms a discharge pipe 119 in the upper circumference.

At this time, the discharge pipe 119 may be formed on the upper circumferential surface of each reaction tank (102, 104, 106), but is preferably formed only on the upper circumferential surface of the nitrification reactor 106 for finally purifying the waste water.

The air inlet pipe 116 is connected to each of the reaction tanks 102, 104 and 106, respectively, but for convenience, only the denitrification reaction tank 102 is shown in FIG. 5 and will be mainly described.

The air inlet pipe 116 located outside the main body 100 is provided with an air control valve 117 to control the inflow of air into the reaction tank (102, 104, 106).

In addition, the raw water inlet pipe 112 is connected to the air inlet pipe 116 located outside the main body 100.

Therefore, the raw water inlet pipe 112 is connected to each reaction tank (104, 106) including the denitrification reaction tank 102 to supply the raw water.

At this time, the raw water inlet pipe 112 is provided with a raw water control valve 113 to adjust the flow control and flow rate of the raw water.

As a result, since the raw water inlet pipe 116 is connected to the air inlet pipe 116, each reactor (102, 104, 106) is supplied with air and raw water.

In addition, the air inlet pipe 116 is extended to the desorption pipe 118 is inserted into each reaction tank (104, 106) including the denitration reaction tank (102).

The desorption pipe 118 serves to induce the sludge adsorbed to the adsorption unit 400 by directly ejecting the outside air to the adsorption unit 400 which will be described later.

Of course, the desorption pipe 118 is provided with an on-off valve 119 to open and close the desorption pipe 118 as necessary.

The air flowing into the body 100 serves to activate and purify the waste water inside the body 100 as microorganisms.

In addition, the air inlet pipe 116 is provided with an air control valve 117 to control the flow state and flow amount of air.

In addition, the main body 100 has a drain pipe 120 that is opened and closed by a drain valve 121 at the bottom.

The drain pipe 120 is formed under each of the reaction tanks 102, 104, and 106, and serves to discharge the sludge generated during the purification of the waste water to the outside.

The main body 100 connected to each of the reactors 102, 104, and 106 in order to discharge nitrogen in the gaseous state, denitrified nitrogen, and carbon dioxide generated by decomposition of organic matter, which is generated in each reactor, 102, 104, and 106, has a specific gravity lower than that of the liquid. The outlet surface 110 is provided on the circumferential surface.

In particular, the agitator 200 is formed in the air inlet pipe 116 located inside each of the reaction tanks 102, 104, and 106.

The stirring unit 200 serves to improve the degree of air activation by mixing the raw water and the air introduced through the air inlet pipe 116 and the waste water stored in each reaction tank (102,104,106).

As shown in FIG. 8, the stirring unit 200 includes a casing 210, a spacer 220, a flange 230, and an impeller 240.

The casing 210 is connected to the air inlet pipe 116 located inside each of the reaction tanks 102, 104, 106 of the main body 100 to receive external air, and inserts the inlet 212 from the lower side to the upper side to discharge external waste water. Induces inflow, and through the opening 214 to the upper side which is in line with the suction opening (212).

Waste water in each of the reaction tanks 102, 104, and 106 is introduced into the casing 210 through the inlet 212 during the rotation of the impeller 240, and is agitated by being discharged through the opening 214.

In addition, the suction port 212 is formed in a pipe shape, it is preferable to maximize the discharge power of the waste water by inserting the upper end into the casing 210 so as to be close to the opening 214.

When the upper end of the suction port 212 is formed at a relatively far position from the opening 214, the waste water rising through the suction port 212 hits the waste water remaining in the casing 210 and the jet speed is significantly reduced.

In addition, although not shown, the spacer 220 is formed to be spaced apart at regular intervals along the circular trajectory on the upper edge of the casing 210.

The spacer 220 secures a space in which waste water remains by gapping the space between the flange 230 and the upper side of the casing 210.

In addition, the flange 230 is supported together on the entire upper side of the spacer 220, and supports the underwater motor 232 to the upper side, and protrudes below the rotating shaft 234 connected to the underwater motor 232.

In addition, the impeller 240 is fixed to the rotating shaft 234 protruding to the lower portion of the flange 230 is rotated together with the rotating shaft 234 when the underwater motor 232 is driven and is ejected through the spacer 220 Induces gas-liquid mixing to the waste water, and due to the pressure difference serves to induce the inflow of waste water through the outside air and the inlet 212 through the air inlet pipe (116).

That is, the wastewater including the outside air below the flange 230 causes the vortex through the spacers 220 during the rotation of the impeller 240 and is ejected to the outside, and at the same time the central portion of the vortex located under the flange 230 is Due to the relatively low pressure, the waste water including the outside air flows naturally in the direction of the impeller 240 through the inlet 212 and the opening 214 of the casing 210.

In addition, the casing 210 extends the leg 250 so as to be firmly supported on the inner bottom surface of each reaction tank 102, 104, 106 of the main body 100.

On the other hand, each of the reaction tank (102, 104, 106) of the main body 100 forms a bottom depression 170 that recessed the bottom surface into a cone or polygonal shape.

The reason why the bottom depressions 170 are formed is that the waste water including the outside air flows from the upper side to the lower side by rotating the impeller 240 in each of the reaction tanks 102, 104, and 106. This is to increase the microbial activity by supplying air evenly.

At this time, the drain pipe 120 is preferably connected to the bottom of the bottom recess 170.

In addition, the reactor (102, 104, 106) of the main body 100 has a retardation member 300 in parallel with each other or in any one of the interior.

Of course, the retention delay member 300 is preferably provided in all the reaction tank (102, 104, 106).

In addition, the retention delay member 300 partitions the layer for the retention of the wastewater treatment liquid by arranging the plurality of layers in the longitudinal direction of each of the reaction tanks 102, 104, and 106.

In particular, the stay delay member 300 is provided to be connected to the inner end of the reaction tank (102, 104, 106), etc., both ends.

Thus, the stay retardation member 300 guides air and wastewater therebetween as it is arranged spaced apart from each other in the same layer.

As shown in FIG. 6, the retention delay members 300 are formed independently on the same plane, respectively, and sufficiently secure the flow passages of the waste water including the rising air, and recess the lower portion to form the recessed grooves 310. The air residence time inside each reactor (102, 104, 106) is increased.

Thus, microbial activity is enhanced.

On the other hand, each reaction tank (102, 104, 106) of the main body 100 is provided with an adsorption unit 400 to filter the sludge contained in the waste water treatment liquid therein.

The adsorption unit 400 is mounted on at least one of all the reaction tanks 102, 104, 106, and is preferably formed on the inside of each reaction tank 102, 104, 106 corresponding to a position adjacent to the discharge pipe 119 shown in FIG. 4.

Thus, the sludge contained in the wastewater treatment liquid is adsorbed by the external air aeration of the wastewater treatment liquid under the adsorption unit 400 through the air inlet pipe 116 and the desorption pipe 118.

That is, the desorption pipe 118 is inserted into each of the reaction tanks 102, 104, and 106 to aeration external air from the lower portion of the adsorption unit 400.

As illustrated in FIG. 7, the adsorption unit 400 includes a frame 410 having a hexahedron shape, a hanger bar 420 and the hooks disposed in the same direction on the upper and lower sides of the frame 410. It consists of an attachment member 430 for attaching the sludge to the bar 420.

At this time, the hook bar 420 forms a hook groove 422 along the axial direction to allow the attachment member 430 to be hooked.

The hanger 420 may be fixed to the frame 410 by welding or the like, or may be detachably mounted by bolting or the like.

Although not shown, the attachment member 430 is preferably made of a general media consisting of a loop that is a screen and a yarn provided around the loop to attach sludge.

Thus, the loop of the attachment member 430 is wound around the hook groove 422.

Although not shown, both ends of the attachment member 430 may be fixed to the hook groove 422 of the hook bar 420, respectively, or may be fixed by a band cable.

In particular, the frame 410 is provided with a fastening piece 510 having a fastening hole 512 at the upper edge, and the fastening piece 510 is fastened by a fastening member 520 inserted into the fastening hole 512. It is preferable that the main body 100 is detachably fastened.

The reason why the attachment member 430 attaches the sludge is to activate decomposing and purifying organic substances by reducing the detachment of microorganisms in the wastewater treatment liquid.

On the other hand, the main body 100 is preferably to support the frame 410 by forming a support jaw 440 on the inner surface.

In this case, the support jaw 440 preferably supports the lower side of the frame 410.

And, although not shown, in order for the attachment member 430 to be installed in the main body 100, it is preferable to form the upper surface of the main body 100 to be opened and closed.

1 is a front view of a conventional wastewater treatment apparatus.

Figure 2 is a plan view of a conventional microorganism reaction high stage.

Figure 3 is a side cross-sectional view of a conventional wastewater treatment apparatus.

4 is a front view of the wastewater treatment apparatus according to the present invention.

Figure 5 is a side cross-sectional view of the wastewater treatment apparatus according to the present invention.

Figure 6 is a perspective view showing the installation of the retention delay member provided in the wastewater treatment apparatus according to the present invention.

Figure 7 is a state diagram of the adsorption unit installed in the wastewater treatment apparatus according to the present invention.

8 is an enlarged view of the stirring unit installed in the wastewater treatment apparatus according to the present invention.

* Description of the symbols for the main parts of the drawings *

1,100: main body 2,102: denitrification tank

4,104: activator 6,106: nitrification tank

12,112: raw water inlet pipe 16,116: air inlet pipe

108: inlet 110: outlet

130: ejection pipe 160: ejection guide member

170: stirring section 172: case

174: axis of rotation 176: impeller

200: bottom depression 300: retention delay member

400: adsorption part

Claims (8)

The waste water is stored, and the air inlet pipe 116 is formed on the lower side to inject air, and the raw water inlet pipe 112 is connected to the air inlet pipe 116 to inject raw water together with air if necessary. A main body 100 having a drain pipe 120 on the bottom to purify and discharge the purified wastewater treatment liquid with a discharge pipe 119 on the upper side and to discharge the sludge generated during the purification process; A casing 210 connected to the air inlet pipe 116 located in the main body 100 to mix waste water and air in the main body 100 to maximize an air activation degree; And The main body 100 is stacked in the up and down direction and arranged in parallel with each other so as to interfere with the air moving in the upper direction to be connected to the inside of the main body 100 and to form a recessed groove 310 in the lower portion of the flow. Waste water treatment apparatus comprising a retardation member 300 to increase the residence time of the air in the main body 100 by temporarily receiving the air. The method of claim 1, The main body (100) partitions the interior such that one or more denitrification tank (102), activation tank (104), and nitrification tank (106) are connected to each other in order; The denitrification reactor 102, the activation tank 104, and the nitrification reactor 106 are provided with the stirring unit 200 and the retention delay member 300 together; The denitrification reactor (102) and the activation tank (104), the activation tank (104) and the nitrification reactor (106) is a wastewater treatment apparatus, characterized in that connected to the inner circulation pipe (107). The method of claim 2, The denitrification reactor (102) and the nitrification reactor (106) located at both outermost sides of the main body (100) are connected to an external circulation pipe (122). The method according to claim 1 or 2, The main body 100 is a wastewater treatment apparatus, characterized in that to form a bottom depression 170 in the bottom recessed conical or polygonal shape. The method of claim 1, wherein the stirring unit 200, The casing 210; Spacers 220 formed on the upper edge of the casing 210 to be spaced apart at regular intervals along a circular trajectory; A flange 230 which is supported together on the entire upper side of the spacer 220, supports the underwater motor 232 on the upper side, and protrudes downward from the rotation shaft 234 connected to the underwater motor 232; And It is fixed to the rotating shaft 234 protruding to the lower portion of the flange 230 is rotated with the rotating shaft 234 when the underwater motor 232 is driven to the waste water discharged through the spacer 220 And an impeller 240 for inducing gas-liquid mixing and introducing waste water through the air inlet pipe 116 and external air through the inlet port 212 due to the pressure difference. The casing 210 is, Connected to the air inlet pipe 116 located inside the main body 100 receives external air, and inserts the inlet 212 in the upper direction from the lower side to induce external waste water, and the inlet 212 and Waste water treatment apparatus characterized in that through the opening 214 through the upper side to be in a straight line. The method of claim 5, The casing 210 is a wastewater treatment apparatus, characterized in that extending legs (250) to be firmly supported on the inner bottom surface of the main body (100). The method according to claim 1 or 2, The main body (100) is equipped with an adsorption unit (400) inside the upper portion of the retention retardation member (300) to filter out sludge contained in the wastewater treatment liquid that is purified and raised. The method of claim 7, wherein The adsorption unit 400 is a hexahedral frame-shaped frame 410 is fixed to the inside of the main body 100; Hanger bars 420 disposed on the upper and lower sides of the frame 410 in parallel in the same direction; And Wastewater treatment apparatus comprising an attachment member (430) for attaching sludge alternately to the hook bar (420) on the surface.

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