JP2018161637A - Flocculation precipitation treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flocculation precipitation treatment apparatus capable of stabilizing water quality of treated water irrespective of a flocculation state in a sludge blanket.SOLUTION: A flocculation conditioner supply part 120 supplies a flocculation conditioner to a supply line L50 based on a flocculation state of a sludge blanket. Because the supply line L50 is a line for supplying raw water to a sludge blanket part 12, the flocculation conditioner supply part 120 supplies the flocculation conditioner to the supply line L50 and, thereby, can directly supply the flocculation conditioner to the sludge blanket. Therefore, even when the flocculation state of the sludge blanket is deteriorated, flocks of the sludge blanket are quickly re-flocculated by the flocculation conditioner. Thereby, the flocculation state of the sludge blanket is recovered and treated water can be maintained in preferable water quality. Accordingly, irrespective of the flocculation state of the sludge blanket, water quality of the treated water can be stabilized.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a coagulation sedimentation processing apparatus.

  For example, a coagulation sedimentation processing apparatus having a sludge blanket as in Patent Document 1 is known as a coagulation sedimentation processing apparatus that coagulates and precipitates organic matter and the like by adding a coagulant to raw water. In this coagulation sedimentation processing apparatus, the coagulation floc contained in the raw water to which the coagulant is added is captured by the sludge blanket formed in the sludge blanket part. Thereby, the aggregation floc and the treated water are separated.

JP 11-47757 A

  However, in the coagulation sedimentation processing apparatus, the aggregation state of the sludge blanket may deteriorate, for example, when the apparatus is started up after the apparatus is stopped. When the water treatment is performed in such a state, the flocs are refined and flow out with the treated water without being captured by the sludge blanket. Therefore, there exists a problem that the quality of treated water falls.

  The present invention has been made in view of the above, and an object of the present invention is to provide a coagulation sedimentation treatment apparatus that can stabilize the quality of treated water regardless of the aggregation state of the sludge blanket.

  A coagulation sedimentation processing apparatus according to an embodiment of the present invention includes a coagulation sedimentation tank including a sludge blanket portion having a sludge blanket that receives raw water and captures solids contained in the raw water to generate treated water, and a coagulation sedimentation tank The supply line for supplying raw water to the sludge blanket section and the aggregation regulator supply section capable of supplying the aggregation regulator that improves the cohesiveness of the sludge blanket are provided. The agglomeration regulator is supplied to at least one of the supply line and the sludge blanket part.

  In this coagulation sedimentation processing apparatus, the coagulation adjusting agent supply unit supplies the coagulation adjusting agent to at least one of the supply line and the sludge blanket unit based on the aggregation state of the sludge blanket. The aggregation adjusting agent supply unit can supply the aggregation adjusting agent directly to the sludge blanket by supplying the aggregation adjusting agent to the sludge blanket unit. Moreover, since the supply line is a line for supplying raw water to the sludge blanket part, the aggregation regulator supply part supplies the aggregation regulator directly to the sludge blanket by supplying the aggregation regulator to the supply line. Can do. Therefore, even if the aggregation state of the sludge blanket is deteriorated, the flocs of the sludge blanket are rapidly re-aggregated by the aggregation regulator. Thereby, the aggregation state of the sludge blanket is recovered, and the treated water can be maintained in a good water quality. As described above, the quality of the treated water can be stabilized regardless of the aggregation state of the sludge blanket.

  In one form, it comprises a reaction tank for reacting raw water and a coagulation regulator, and a switching unit for switching the supply destination of the coagulation regulator by the coagulation regulator supply unit, and the switching unit is based on the aggregation state of the sludge blanket. The supply destination of the aggregation regulator may be switched from the reaction tank to at least one of the supply line and the sludge blanket part. Thus, in a normal operation state, the aggregation regulator supply unit supplies the aggregation regulator to the reaction tank, and after sufficiently reacting the aggregation regulator and raw water in the reaction tank, the sludge blanket unit Can be supplied to. On the other hand, when the aggregation state of the sludge blanket deteriorates, the floc of the sludge blanket can be quickly re-agglomerated by the aggregation regulator by switching at the switching unit.

  In one form, the aggregation regulator supply unit may supply the aggregation regulator to the supply line. When the coagulation adjusting agent is supplied to the supply line, the coagulation adjusting agent can be uniformly supplied to the sludge blanket in the coagulation sedimentation tank by a dispersion supply mechanism such as a distributor together with the raw water.

  In one form, the aggregation regulator supply unit may supply the aggregation regulator to the sludge blanket unit. In this way, the aggregation adjusting agent supply unit directly puts the aggregation adjusting agent into the sludge blanket unit, so that the sludge of the sludge blanket can be immediately re-agglomerated, so that the operation can be performed without deteriorating the treated water quality.

  In one form, the aggregation regulator supply unit may supply the aggregation regulator to the upper layer of the sludge blanket unit. In this case, the aggregation state in the vicinity of the upper layer of the sludge blanket can be intensively recovered. Here, when the agglomeration state deteriorates, the flocs that are not captured flow out together with the treated water from the upper layer of the sludge blanket. Therefore, if the aggregated state in the vicinity of the upper layer of the sludge blanket is intensively recovered, it is possible to quickly prevent small flocs from flowing out.

  ADVANTAGE OF THE INVENTION According to this invention, the coagulation sedimentation processing apparatus which can stabilize the quality of a treated water irrespective of the aggregation state of a sludge blanket is provided.

It is a schematic block diagram of the coagulation sedimentation processing apparatus which concerns on embodiment of this invention. It is a schematic block diagram of the coagulation sedimentation processing apparatus which concerns on a modification. It is a schematic block diagram of the coagulation sedimentation processing apparatus which concerns on a modification. It is a schematic block diagram of the coagulation sedimentation processing apparatus which concerns on a modification.

  Hereinafter, various embodiments will be described in detail with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same or an equivalent part, and the overlapping description is abbreviate | omitted.

  FIG. 1 is a schematic configuration diagram of a coagulation sedimentation processing apparatus according to an embodiment of the present invention. As shown in FIG. 1, the coagulation sedimentation processing apparatus 100 includes a coagulation sedimentation tank 10, a reaction tank 20, an inorganic coagulant supply unit 30, and a polymer coagulant supply unit 40. The coagulation sedimentation treatment apparatus 100 includes a line L1 for supplying raw water to the reaction tank 20, a line L2 for supplying raw water reacted with the inorganic coagulant in the reaction tank 20 to the coagulation sedimentation tank 10, and coagulation sedimentation. Line L3 for removing treated water treated in tank 10, lines L6 and L4 for supplying inorganic flocculant from inorganic flocculant supply unit 30 to reaction tank 20, line L5 branching from line L6 to line L2, and high A line L7 for supplying the polymer flocculant from the molecular flocculant supply unit 40 to the line L2.

  The reaction tank 20 is a tank that stores the raw water supplied via the line L1 and reacts the raw water with the inorganic flocculant supplied from the inorganic flocculant supply unit 30. The reaction tank 20 may include a stirring device 21. Thereby, the raw | natural water and the inorganic flocculant in the reaction tank 20 are stirred with the stirring apparatus 21, and reaction with the solid substance and inorganic flocculant contained in raw | natural water is fully raise | generated. The solids in the raw water are agglomerated by reacting with the inorganic aggregating agent to form small agglomerated flocs. The raw water in the reaction tank 20 is supplied to the coagulation sedimentation tank 10 through the line L2 at a predetermined flow rate. In addition, chemical | medical agents other than an inorganic flocculant may be supplied to the reaction tank 20, for example, you may supply the pH adjuster which adjusts pH (for example, refer FIG. 4).

  The inorganic flocculant supply unit 30 supplies the inorganic flocculant to the raw water. The inorganic flocculant supply unit 30 supplies the inorganic flocculant to the reaction tank 20 via the lines L6 and L4 during normal operation. The inorganic flocculant supply unit 30 temporarily supplies the inorganic flocculant to the line L2 via the lines L6 and L5 based on the aggregation state of the sludge blanket (details will be described later). As the inorganic flocculant, an Al-based inorganic flocculant such as a sulfuric acid band or PAC (polyaluminum chloride) may be used. For example, an Fe-based inorganic flocculant such as polyiron sulfate or iron chloride may be used. The metal components (Al and Fe) of the inorganic flocculant electrochemically react with solids such as organic substances in the raw water.

  The polymer flocculant supply unit 40 supplies the polymer flocculant to the raw water. The polymer flocculant supply unit 40 supplies the polymer flocculant to the line L2 via the line L7 during normal operation. As a result, the polymer flocculant flows along the line L2 together with the raw water, and is supplied into the coagulation sedimentation tank 10 together with the raw water. As the polymer flocculant, for example, a polymer flocculant such as polyacrylamide or an organic coagulant such as polyamine may be used.

  The agglomeration sedimentation tank 10 is a tank for obtaining treated water from which solids have been removed by aggregating the solids of the raw water into which the raw water flows. The coagulation sedimentation tank 10 includes a sludge blanket part 12 and a distributor 11 that supplies raw water to the sludge blanket part 12 in a distributed manner. The sludge blanket section 12 has a sludge blanket that captures solids contained in raw water (reacts with an inorganic flocculant to form a flocs floc) and generates treated water.

  In the sludge blanket of the coagulating sedimentation tank 10, a fluidized bed of coagulated flocs is formed by the rising water flow in the tank, and the coagulated flocs newly generated by the solids contained in the raw water are passed through the fluidized bed. At this time, the small agglomerated flocs are captured by the large flocs in the fluidized bed and become large, and the sedimentation speed increases. Thereby, the raw | natural water supplied to the sludge blanket part of the coagulation sedimentation tank 10 is isolate | separated into a treated water and an aggregation floc. As a result, the supernatant treated water after the flocs are removed by the sludge blanket of the coagulation sedimentation tank 10 is discharged to the outside through the line L3.

  The distributor 11 supplies the raw water supplied from the line L2 to the sludge blanket unit 12. The distributor 11 can supply the raw water so that the raw water is uniformly dispersed in the sludge blanket. Thus, the distributor 11 is a part that can supply raw water to the sludge blanket section 12 by being connected to the line L2. Accordingly, the distributor 11 belongs to the “supply line” in the claims. From the above, the flow path downstream of the reaction tank 20 and capable of supplying raw water to the sludge blanket part 12 may be referred to as a supply line L50. In the present embodiment, it is assumed that the line L2 and the distributor 11 are included in the supply line L50.

  Here, the coagulation sedimentation processing apparatus 100 which concerns on this embodiment is provided with the structure which can recover an aggregation state, when the aggregation state of a sludge blanket deteriorates. Hereinafter, the structure will be described.

  The coagulation sedimentation processing apparatus 100 includes an aggregation adjusting agent supply unit 120. The aggregation regulator supply unit 120 supplies the aggregation regulator to at least one of the supply line L50 and the sludge blanket unit 12 based on the aggregation state of the sludge blanket. The aggregation regulator is an agent that improves the aggregation property of the sludge blanket. The aggregation regulator may be capable of directly improving the aggregation property of the sludge blanket, such as an inorganic aggregation agent or a polymer aggregation agent. Aggregation regulators, like pH adjusters and sedimentation aids, indirectly promote the agglomeration reaction or increase the specific gravity to increase sedimentation, thereby indirectly coagulating and sedimenting the sludge blanket. May be improved. In the example shown in FIG. 1, an inorganic flocculant is employed as the flocculant regulator. In the present embodiment, the inorganic flocculant supply unit 30 and the lines L6 and L5 correspond to the aggregation regulator supply unit 120.

  The supply location of the coagulation regulator by the coagulation regulator supply unit 120 is at least one of the supply line L50 and the sludge blanket unit 12. When the aggregation adjusting agent is supplied to the supply line L50 or the sludge blanket part 12, the aggregation adjusting agent can promptly participate in the aggregation reaction in the sludge blanket. Thus, like the supply line L50 and the sludge blanket part 12, the supply position where the aggregation regulator can be directly and promptly involved in the aggregation reaction of the sludge blanket by supplying the aggregation regulator to the position. May be referred to as “aggregation adjusting agent supply position 110”. As long as the aggregation adjusting agent supply position 110 is used, the aggregation adjusting agent may be supplied to any position, and the aggregation adjusting agent may be supplied to a plurality of positions. In the present embodiment, an inorganic flocculant that is a flocculant adjusting agent is supplied to the line L2.

  In addition, when a coagulation regulator is introduced in the reaction tank 20 and a location upstream from the reaction tank 20, the coagulation regulator is supplied to the sludge blanket after once reacting with the solid matter contained in the raw water. . Therefore, the amount of the coagulation adjusting agent that cannot or cannot contribute directly to the coagulation reaction of the sludge blanket is reduced.

  For example, the coagulation effect of the coagulant in the sludge blanket is lost immediately after the installation of the equipment or at the start-up after the operation is stopped, so that the coagulation state of the sludge blanket is deteriorated. Further, when the cohesiveness of the coagulation flocs is lowered for a predetermined reason during operation, the coagulation state of the sludge blanket is deteriorated. Moreover, also when the water quality of the raw | natural water introduce | transduced changes, the aggregation state of a sludge blanket deteriorates because the aggregation effect of a flocculant falls.

  Therefore, the aggregation regulator supply unit 120 may supply the aggregation regulator to the aggregation regulator supply position 110 by detecting that the aggregation state of the sludge blanket has deteriorated with a sensor or the like. Alternatively, the aggregation adjusting agent supply unit 120 may supply the aggregation adjusting agent to the aggregation adjusting agent supply position 110 based on a situation where the aggregation state of the sludge blanket may be deteriorated or a situation where the aggregation state is deteriorated. . For example, the aggregation regulator supply unit 120 may supply the aggregation regulator to the aggregation regulator supply position 110 based on a change in the quality of the raw water. Alternatively, the aggregation state of the sludge blanket is anticipated to deteriorate at the start of operation, and the aggregation regulator supply unit 120 may uniformly supply the aggregation regulator to the aggregation regulator supply position 110 at the startup.

  The timing at which the coagulation regulator supply unit 120 stops supplying the coagulation regulator to the coagulation regulator supply position 110 is not particularly limited, but after detecting the water quality of the treated water with a sensor and detecting that it has become clear The aggregation regulator supply unit 120 stops supplying the aggregation regulator to the aggregation regulator supply position 110 and returns to the normal operation. Alternatively, the stop timing may be that a predetermined time has elapsed after the supply of the aggregation regulator to the aggregation regulator supply position 110 is started. Alternatively, the timing of stopping may be determined by detecting the aggregation state of the sludge blanket and confirming the recovery.

  During normal operation, the inorganic flocculant that is a flocculant regulator is preferably supplied only to the reaction vessel 20. When the inorganic flocculant is supplied to the aggregation regulator supply position 110, the aggregation reaction of the inorganic flocculant and the aggregation reaction of the polymer flocculant occur simultaneously. Therefore, the inorganic flocculant aggregates with the polymer flocculant before it uniformly reacts with the solid, and the aggregating reaction by the inorganic flocculant is difficult to proceed. In addition, when PAC having strong acidity is used as the inorganic flocculant, the position where PAC is added becomes locally acidic, the molecular structure of the polymer flocculant is changed, and the agglomeration effect is partially reduced. . As described above, when the inorganic flocculant is supplied to the flocculant regulator supply position 110 until the normal operation, a large amount of flocculant is required.

  The coagulation sedimentation processing apparatus 100 includes a switching unit 50 that switches the supply destination of the coagulation adjusting agent by the coagulation adjusting agent supply unit 120. The switching unit 50 switches the supply destination of the aggregation regulator from the reaction tank 20 to at least one of the supply line L50 and the sludge blanket unit 12 based on the aggregation state of the sludge blanket. In this embodiment, the switching part 50 may be comprised by the valve provided in the connection part of the line L6, the line L5, and the line L4. That is, when the switching unit 50 performs switching so as to supply the inorganic flocculant of the inorganic flocculant supply unit 30 to the reaction tank 20, the line L6 and the line L4 are communicated and the line L5 is blocked. When the switching unit 50 performs switching so as to supply the inorganic flocculant of the inorganic flocculant supply unit 30 to the line L2, the line L6 and the line L5 are communicated and the line L4 is blocked.

  Next, an example of the operation | movement aspect of the coagulation sedimentation processing apparatus 100 shown in FIG. 1 is demonstrated.

  During normal operation, the switching unit 50 causes the line L6 and the line L4 to communicate with each other and blocks the line L5. Thereby, the inorganic flocculant supply part 30 supplies an inorganic flocculant to the reaction tank 20 via line L6, L4. As a result, the solid matter in the raw water reacts with the inorganic flocculant in the reaction tank 20 to form small flocculated flocs. The polymer flocculant supply unit 40 supplies the polymer flocculant to the line L2. Thereby, raw | natural water is supplied to the sludge blanket part 12 of the coagulation sedimentation tank 10 with the aggregation floc and the polymer coagulant. Thereby, the treated water with good water quality in which the flocs are captured by the sludge blanket is discharged from the line L3.

  On the other hand, at the time of start-up after the operation is stopped, for example, the aggregation state of the sludge blanket is estimated to be deteriorated, and the switching unit 50 causes the line L6 and the line L5 to communicate with each other and shuts off the line L4. Thereby, the inorganic flocculant supply unit 30 supplies the inorganic flocculant to the line L2 via the lines L6 and L5. The polymer flocculant supply unit 40 supplies the polymer flocculant to the line L2. Thereby, raw | natural water is supplied to the sludge blanket part 12 of the coagulation sedimentation tank 10 with an inorganic flocculant and a polymer flocculent. Thereby, the flocs of the sludge blanket are re-agglomerated by the aggregating effect of the inorganic aggregating agent. As described above, the aggregation state of the sludge blanket is recovered. Thereafter, the coagulation sedimentation processing apparatus 100 returns to the normal operation described above.

  When the inorganic flocculant is supplied to the flocculant regulator supply position 110, a large amount of flocculant is required as described above, but the operation for recovering the flocculent state of the sludge blanket is temporary. Yes, the merit of quickly recovering the aggregated state is greater than the disadvantage of temporarily increasing the flocculant.

  Next, operations and effects of the coagulation sedimentation processing apparatus 100 according to the present embodiment will be described.

  In the coagulation sedimentation processing apparatus 100, the coagulation adjusting agent supply unit 120 supplies the coagulation adjusting agent to the supply line L50 based on the aggregation state of the sludge blanket. Since the supply line L50 is a line for supplying raw water to the sludge blanket unit 12, the aggregation regulator supply unit 120 supplies the aggregation regulator directly to the sludge blanket by supplying the aggregation regulator to the supply line L50. can do. Therefore, even if the aggregation state of the sludge blanket is deteriorated, the flocs of the sludge blanket are rapidly re-aggregated by the aggregation regulator. Thereby, the aggregation state of the sludge blanket is recovered, and the treated water can be maintained in a good water quality. As described above, the quality of the treated water can be stabilized regardless of the aggregation state of the sludge blanket.

  The coagulation sedimentation processing apparatus 100 includes a reaction tank 20 that reacts raw water and a coagulation regulator, and a switching unit 50 that switches a supply destination of the coagulation regulator by the coagulation regulator supply unit 120. The switching unit 50 switches the supply destination of the aggregation adjusting agent from the reaction tank 20 to the supply line L50 based on the aggregation state of the sludge blanket. Thereby, in a normal operation state, the aggregation regulator supply unit 120 supplies the aggregation regulator to the reaction tank 20 so that the aggregation regulator and the raw water are sufficiently reacted in the reaction tank 20, It can be supplied to the sludge blanket section 12. On the other hand, when the aggregation state of the sludge blanket deteriorates, the floc of the sludge blanket can be quickly re-agglomerated by the aggregation regulator by switching at the switching unit 50.

  The aggregation regulator is an inorganic aggregating agent, and the aggregation regulator supply unit 120 may supply the inorganic aggregating agent to the supply line L50. When the coagulation adjusting agent is supplied to the supply line L50, the coagulation adjusting agent can be uniformly supplied to the sludge blanket in the coagulation sedimentation tank 10 by the distributor 11 together with the raw water.

  The present invention is not limited to the above-described embodiment.

  For example, you may employ | adopt the coagulation sedimentation processing apparatus 200 as shown in FIG. In the coagulation sedimentation processing apparatus 200, an inorganic coagulant as a coagulation adjusting agent is directly supplied to the sludge blanket unit 12. Thereby, the aggregation regulator can be supplied directly to the sludge blanket. As described above, by directly adding the coagulation adjusting agent to the sludge blanket, the sludge of the sludge blanket can be immediately re-coagulated, so that the operation can be performed without deteriorating the quality of the treated water.

  Specifically, the coagulation sedimentation processing apparatus 200 includes a line L8 connected from the switching unit 50 to the sludge blanket unit 12 of the coagulation sedimentation tank 10. Thereby, the inorganic flocculant supply part 30 can supply an inorganic flocculant to the sludge blanket part 12 via line L6, L8 by switching of the switching part 50. FIG.

  For example, you may employ | adopt the coagulation sedimentation processing apparatus 300 as shown in FIG. In the coagulation sedimentation processing apparatus 300, the coagulation adjusting agent supply unit 120 may supply the inorganic coagulant to the upper layer of the sludge blanket unit 12. In this case, the aggregation state in the vicinity of the upper layer of the sludge blanket can be intensively recovered. Here, when the agglomeration state deteriorates, the flocs that are not captured flow out together with the treated water from the upper layer of the sludge blanket. Therefore, if the aggregated state in the vicinity of the upper layer of the sludge blanket is intensively recovered, it is possible to quickly prevent small flocs from flowing out.

  Specifically, the coagulation sedimentation processing apparatus 300 includes a line L13 connected from the switching unit 50 to the upper layer portion of the sludge blanket unit 12 of the coagulation sedimentation tank 10. The coagulation sedimentation treatment apparatus 300 includes a line L10 connected to the polymer flocculant supply unit 40, a line L11 branched from the line L10 to the line L2, a line L12 extending from the line L10 to the upper layer portion of the sludge blanket, And a switching unit 60 connected to the lines L10, L11, and L12. Thereby, the inorganic flocculant supply part 30 can supply an inorganic flocculant to the upper layer part of the sludge blanket part 12 via line L6, L13 by switching of the switching part 50. FIG. In addition, the polymer flocculant supply unit 40 can supply the polymer flocculant to the upper layer portion of the sludge blanket unit 12 via the lines L10 and L12 by switching the switching unit 60.

  For example, you may employ | adopt the coagulation sedimentation processing apparatus 400 as shown in FIG. In the coagulation sedimentation processing apparatus 400, a pH adjusting agent is employed as the aggregation adjusting agent. Thus, the cohesiveness can be indirectly improved by adjusting the pH of the sludge blanket. In addition, the coagulation sedimentation processing apparatus 400 includes a detector 80 that can detect the aggregation state of the sludge blanket. The detector 80 is, for example, a turbidimeter. The sensor 81 is arranged in a clarification zone several hundred mm above (100 to 500 mm) above the sludge blanket interface, and the turbidity at that position is measured, thereby aggregating sludge blanket. The state can be detected. Note that the supply amount of the aggregation regulator may be controlled according to the detection result of the detector 80.

  Specifically, the coagulation sedimentation processing apparatus 400 includes a pH adjusting agent supply unit 90 that supplies a pH adjusting agent, a line L20 connected to the pH adjusting agent supply unit 90, and a line that branches from the line L20 to the reaction tank 20. L21, a line L22 extending from the line L20 to the sludge blanket unit 12, and a switching unit 70 connected to the lines L20, L21, and L22. That is, the aggregation adjusting agent supply unit 120 includes a pH adjusting agent supply unit 90 and a line L22 that supplies the pH adjusting agent to the supply line L50. Thereby, the pH adjusting agent supply unit 90 can supply the pH adjusting agent to the sludge blanket unit 12 via the lines L20 and L22 by switching the switching unit 70.

  In addition, although the structure which can recover the aggregation state of a sludge blanket was illustrated like FIGS. 1-4, you may combine a part or all of the structure of FIGS. 1-4.

  Further, a mechanism may be provided that does not operate during normal operation and supplies the aggregation regulator to the aggregation regulator supply position 110 only at a timing at which the sludge blanket aggregation state is recovered.

DESCRIPTION OF SYMBOLS 10 ... Coagulation sedimentation tank, 20 ... Reaction tank, 50, 70 ... Switching part, 100, 200, 300, 400 ... Coagulation precipitation processing apparatus, 120 ... Coagulation regulator supply part, L50 ... Supply line.

Claims (5)

A coagulating sedimentation tank comprising a sludge blanket portion having a sludge blanket into which raw water flows in, captures solids contained in the raw water and generates treated water;
A supply line for supplying the raw water to the sludge blanket part of the coagulation sedimentation tank;
A coagulation regulator supply unit capable of supplying a coagulation regulator that improves the cohesiveness of the sludge blanket, and
The coagulation adjusting agent supply unit supplies the coagulation adjusting agent to at least one of the supply line and the sludge blanket unit based on the aggregation state of the sludge blanket. A reaction vessel for reacting the raw water and the aggregation regulator,
A switching unit that switches a supply destination of the aggregation regulator by the aggregation regulator supply unit,
2. The coagulation sedimentation according to claim 1, wherein the switching unit switches a supply destination of the coagulation regulator from the reaction tank to at least one of the supply line and the sludge blanket unit based on an aggregation state of the sludge blanket. Processing equipment.   The said coagulation regulator supply part is the coagulation sedimentation processing apparatus of Claim 1 or 2 which supplies the said coagulation regulator to the said supply line.   The said coagulation regulator supply part is the coagulation sedimentation processing apparatus of Claim 1 or 2 which supplies the said coagulation regulator to the said sludge blanket part. The said coagulation regulator supply part is the coagulation sedimentation processing apparatus of Claim 4 which supplies the said coagulation regulator to the upper layer part of the said sludge blanket part.

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