JP3169911U - Flock processing device - Google Patents

Abstract

An object of the present invention is to efficiently drain most of the supernatant water without causing the floc precipitated at the bottom of the container to rise into the supernatant water of the upper part. In a container 11 of a floc treatment apparatus 10, a suspension containing a solid content aggregated as floc by adding a flocculant to polluted water is stored. Further, in a state where the flocs of the solid content in the container 11 are settled and separated from the supernatant water 13, the plate 14 can be lowered while being kept in the supernatant water 13 from above the supernatant water 13. 13 and the floc precipitation layer 12 are configured to be able to stop immediately above the boundary surface 36. Further, a supernatant water discharge pump 16 placed on the plate 14 is configured to discharge the supernatant water 13 in the container 11. [Selection] Figure 1

Description

  The present invention relates to an apparatus for separating a solid content aggregated as floc by adding a flocculant to polluted water and supernatant water.

  Conventionally, a solid-liquid separator has a mesh-like filtration section, and the liquid component that has passed through the filtration section is temporarily stored in a storage tank, and the slurry pump again separates the flocs generated in the storage tank into a solid-liquid separation. A wastewater treatment apparatus configured to be transferred to a machine is disclosed (for example, see Patent Document 1). In the wastewater treatment apparatus configured as described above, the wastewater containing fine solids is once guided and stored in a storage tank, and the flocculant is added to the storage tank, so that the solids content becomes fine. Flock is generated and settled in the storage tank. And after stopping drainage containing fine solids in the storage tank for a certain period of time, draining the supernatant water in the storage tank to the outside, transferring the floc precipitated in the storage tank to the solid-liquid separator by the slurry pump, Here, solid-liquid separation is performed. In this way, flocs are generated by adding flocculant to the wastewater discharged to the outside, so that the fine solids contained in the wastewater can be greatly reduced, and the pollution level of the wastewater that adversely affects the environment can be reduced. It has become.

JP-A-10-28975 (Claim 1, paragraphs [0020], [0021], [0031], FIG. 1)

  However, in the wastewater treatment apparatus shown in the above-mentioned conventional Patent Document 1, after the drainage containing fine solids is retained in the storage tank for a certain period of time, the supernatant water in the storage tank is drained to the outside. However, in order to discharge the supernatant water in the storage tank, the pipe is inserted into the storage tank until its tip is located immediately above the flock at the bottom of the storage tank, that is, when the insertion depth of the pipe is deep, the supernatant water is introduced into the pipe. There is a problem that the floc in the lower part of the storage tank rises into the supernatant water with the generation of the sucked flow, and this soared floc is discharged together with the supernatant water. When stopped at a distant position, that is, when the insertion depth of the pipe is shallow, there is a problem that almost no supernatant water can be discharged.

  An object of the present invention is to provide a floc treatment device capable of efficiently discharging most of the supernatant water without causing the floc precipitated in the lower part of the container to rise into the upper supernatant water. Another object of the present invention is to provide a floc treatment device that can reduce the moisture content of the floc sedimentation layer at the bottom of the container by using the container as a filter bag.

  As shown in FIG. 1, the first aspect of the present invention is a container 11 for storing a suspension containing a solid content aggregated as floc by adding a flocculant to polluted water, and a solid content in the container 11. In the state where the flocs of the flocs settled and separated from the supernatant water 13, the flocs can be lowered from above the supernatant water 13 while being kept horizontal in the supernatant water 13, and directly above the boundary surface 36 between the supernatant water 13 and the floc sedimentation layer 12. And a supernatant water discharge pump 16 that is placed on the plate 14 and discharges the supernatant water 13 in the container 11.

  The second aspect of the present invention is based on the first aspect, and as shown in FIG. 1, the container 11 prevents passage of floc in the suspension and the supernatant water in the suspension. It is a filter bag which allows 13 passages.

  The third aspect of the present invention is based on the first aspect, and further, as shown in FIG. 1, the plate 14 is 0 to 20 mm above the boundary surface 36 between the supernatant water 13 and the floc sedimentation layer 12. It is configured to stop at a position.

  The fourth aspect of the present invention is based on the first aspect, and further, as shown in FIG. 1, the speed at which the plate 14 descends in the supernatant water 13 is 10 to 200 mm / second. And

A fifth aspect of the present invention is an apparatus based on the first aspect, and as shown in FIG. 1, the container 11 is formed in a bottomed cylindrical shape or a bottomed rectangular tube shape, and the plate 14 is circular. Alternatively, it is formed in a square shape, and when the bottom area of the container 11 is S ₁ , the area S _{2 of the} plate 14 is set within a range of 0.25S _{1 to} 0.9S ₁ .

  In the floc treatment device according to the first aspect of the present invention, in a state where the floc content in the container has settled and separated from the supernatant water, the plate is lowered while maintaining the supernatant water horizontally from above the supernatant water, Stopping just above the boundary surface between the supernatant water and the floc sedimentation layer, and in this state, the supernatant water is discharged by the supernatant water discharge pump, so that the floc that has settled at the bottom of the container does not rise into the upper supernatant water. , Most of the supernatant water can be discharged efficiently. As a result, the moisture content of the floc sediment layer after the supernatant water in the filter bag is discharged by the supernatant water discharge pump can be reduced.

  In the floc treatment apparatus according to the second aspect of the present invention, since the container is a filtration bag that prevents passage of floc in the suspension and allows passage of supernatant water in the suspension, the container is stored in the filtration bag. The clean water contained in the floc sediment layer passes through the filter bag until the completion of the discharge of the supernatant water by the supernatant water discharge pump after the plate is lowered after the plate is left standing. As a result, the moisture content of the floc precipitation layer can be further reduced, so that the floc can be dried in a relatively short time.

FIG. 4 is a cross-sectional view taken along line AA of FIG. 3 showing a state in which the plate of the floc treatment apparatus of the embodiment of the present invention is lowered to a position just above the boundary surface between the finished liquid and the floc precipitation layer. It is the sectional view on the AA line of FIG. 3 which shows the state before lowering the plate. It is the B section enlarged plan view of FIG. It is CC sectional view taken on the line of FIG. It is a top view of the floc processing apparatus.

Next, embodiments for carrying out the present invention will be described with reference to the drawings. As shown in FIGS. 1 and 2, the floc treatment device 10 includes a bottomed cylindrical filter bag 11 that stores a suspension containing a solid content aggregated as floc by adding a flocculant to contaminated water; A circular plate 14 capable of descending while being kept horizontal in the supernatant water 13 in a state where the flocs of the solid content in the filter bag 11 are settled and the lower floc precipitation layer 12 is separated from the upper supernatant water 13; And a supernatant water discharge pump 16 mounted on the plate 14. The flocculant added to the polluted water is an inorganic flocculant mainly made of natural minerals, and examples thereof include sulfur trioxide, calcium oxide, and sodium oxide. The filtration bag 11 is formed in a bottomed cylindrical shape with a flexible woven or non-woven fabric having a water permeability of 1.0 × 10 ⁻² cm / sec or more and an opening of less than 0.4 mm. The Thus, the filter bag 11 is configured to prevent passage of floc in the suspension and to allow passage of the supernatant water 13 in the suspension. In this embodiment, the filter bag is formed in a bottomed cylindrical shape and the plate is formed in a circular shape. However, the filter bag is formed in a bottomed cylindrical shape, the plate is formed in a square shape, or the filter bag is formed. It may be formed in a bottomed rectangular tube shape, and the plate may be formed in a circular shape or a rectangular shape. In this case, the plate may be formed in a shape corresponding to the shape of the bottom surface of the filtration bag, but if the plate can be submerged in the supernatant water while keeping the plate horizontal, the plate is not in a shape corresponding to the shape of the bottom surface of the filtration bag. Alternatively, it may be formed in a square shape (triangular shape, quadrangular shape, or other polygonal shape).

  The filtration bag 11 includes two cylindrical frames 17 and 17 placed on a first frame 21 having a substantially rectangular frame shape partitioned by a grid, and a second frame having a substantially rectangular frame shape partitioned by a grid. 22 are accommodated in two cylindrical frames 17 and 17 placed on 22 (FIG. 5). These four frame bodies 17 are formed in the same shape by a metal round bar or a round pipe. Further, a substantially rectangular first drain pan 31 is integrally formed on the first frame 21, and a substantially rectangular second drain pan 32 is integrally formed on the second frame 22. A substantially trapezoidal convex portion 21a, 31a that protrudes outward is provided on one side of the first gantry 21 and the first drain pan 31, and a substantially base that retracts inward on one side of the second gantry 22 and the second drain pan 32. Shaped recesses 22a and 32a are provided. By engaging the convex portions 21a, 31a of the first gantry 21 and the first drain pan 31 with the concave portions 22a, 32a of the second gantry 22 and the second drain pan 32, the first and second drain pans 31, 32 are substantially omitted. In addition to being formed in a square shape, the first and second mounts 21 and 22 are formed in a substantially square frame shape partitioned by a lattice. The first and second drain pans 31 and 32 are configured to receive the supernatant water 13 that has passed through the filter bag 11 and clean water of the same quality as the supernatant water 13 (clean water contained in the floc precipitation layer 12). . The first and second drain pans 31 and 32 are formed with first and second discharge ports (not shown) for discharging the supernatant water 13 and clean water stored in these drain pans to the natural world, respectively. The

  On the other hand, a support means 18 that rotatably supports the plate 14 is erected at the center in the longitudinal direction of the side where the convex portion 21a of the first pedestal 21 is formed (FIGS. 3 to 5). The support means 18 extends in the vertical direction so as to be positioned at the center in the longitudinal direction of the convex portion 21a of the upper surface of the lower support plate 18a and the substantially triangular lower support plate 18a fixed to the first frame 21. Lower support pipe 18b erected, three auxiliary pipes 18c erected on the upper surface of each corner of the substantially triangular support plate 18a, and three auxiliary ribs projecting from these auxiliary pipes 18c 18d, a substantially triangular upper support plate 18e extending horizontally so as to be placed on the upper surfaces of the three auxiliary ribs 18d, and a vertical position so as to be positioned above the lower support pipe 18b at a predetermined interval. An upper support pipe 18f that extends in the direction and is held by three auxiliary pipes 18c, three auxiliary ribs 18d, and an upper support plate 18e, a lower support pipe 18b, and an upper support pipe It has a rotary shaft 18g that is inserted rotatably into 8f, an arm portion 18h which is proximal is fitted on top of the rotating shaft 18g is provided to extend in the horizontal direction. The distance between the center line of the lower support pipe 18b and the upper support pipe 18f and the center line of each frame body 17 is the same, that is, on the same circumference around the lower support pipe 18b and the upper support pipe 18f. The lower support pipe 18b and the upper support pipe 18f are erected on the first mount 21 so that the center line of the frame body 17 is located. The arm portion 18h is configured to rotate around the lower support pipe 18b and the upper support pipe 18f together with the rotating shaft 18g.

  On the other hand, the plate 14 is suspended from the arm portion 18h via the lifting means 23 (FIGS. 1 to 4). The lifting / lowering means 23 is a manual winch 24 attached to the lower surface of the front end of the arm portion 18h, a fixed pulley 26 attached to the central lower surface of the arm portion 18h, and drawn out from the manual winch 24 and suspended through the fixed pulley 26. A wire 24a, a guide plate 27 (FIGS. 1 to 3 and 5) attached to the central upper surface of the arm portion 18h and having the same outer diameter as the plate 14, and a lower end with a predetermined interval in the vicinity of the outer peripheral portion of the plate 14. (The central angle of the plate 14 is 90 degrees) and is attached to extend upward and is formed in the vicinity of the outer periphery of the guide plate 27 with a predetermined interval (the central angle of the guide plate 27 every 90 degrees). And four guide rods 28 slidably inserted into the holes 27a (FIG. 3). The manual winch 24 is configured such that the wire 24a is fed out by rotating the handle 24b forward and the wire 24a is wound up by rotating the handle 24b reversely. Further, the tip of the wire 24a is divided into three directions, and is attached to the vicinity of the outer periphery of the plate 14 at a predetermined interval (120 degrees at the central angle of the plate 14) (FIG. 4), so that the plate 14 is kept horizontal. Configured to be held in a state. Further, the supernatant water discharge pump 16 is a submersible pump, and a suction port (not shown) for the supernatant water 13 is formed on the lower side surface thereof, and a discharge port 16a for the supernatant water 13 is formed on the upper surface thereof. One end of a drainage hose 33 is connected to the discharge port 16a of the pump 16, and the drainage hose 33 is routed outside the filtration bag 11 via a hook 34 attached to the lower surface of the arm portion 18h. In addition, by inserting the guide rod 28 through the through hole 27a of the guide plate 27 attached to the arm portion 18h, the function of preventing the shake of the plate 14 attached to the lower end of the guide rod 28 is exhibited. . Moreover, the code | symbol 16b in FIG.1 and FIG.2 is a cable for supplying electric power to the supernatant water discharge pump 16. FIG.

On the other hand, the plate 14 is configured to be able to descend in the supernatant water 13 by the elevating means 23 and stop right above the boundary surface 36 between the supernatant water 13 and the floc sedimentation layer 12. Specifically, the plate 14 is configured to be able to stop at a position 0 to 20 mm, preferably 0 to 5 mm above the boundary surface 36 between the supernatant water 13 and the floc sedimentation layer 12. The descending speed in the supernatant water 13 of the plate 14 by the elevating means 23 is set to 10 to 200 mm / second, preferably 60 to 190 mm / second. Furthermore when the bottom area of the filter bag 11 and S _1, the area S ₂ in the upper or lower surface of the plate 14, 0.25S ₁ ~0.9S _1, preferably in the range of 0.5S ₁ ~0.8S ₁ (FIG. 1). Here, the reason why the stop position of the plate 14 is limited to the range of 0 to 20 mm above the boundary surface 36 between the supernatant water 13 and the floc sedimentary layer 12 is to discharge as much of the supernatant water 13 as possible. This is because it is most effective to arrange the plate 14 at the lower limit level of the water 13. Even if the stop position of the plate 14 is set 0 mm above the boundary surface 36, that is, even if the position of the plate 14 is at the same level as the boundary surface 36, the plate 14 is set to an appropriate size (area). Thus, since it is not affected by the flow rate of the supernatant water discharge pump 16, it is possible to prevent the flocs existing on the boundary surface 36 from rising. Further, the lowering speed of the plate 14 is limited to the range of 10 to 200 mm / sec. If it is less than 10 mm / sec, it takes a long time to lower the plate 14 and the working efficiency is lowered. If it exceeds, the descending speed of the plate 14 is too fast, and a flow is generated at the boundary surface between the supernatant water 13 and the floc sedimentation layer 12, and the flocs may rise in the supernatant water 13. Furthermore when the bottom area of the filter bag 11 and S _1, The reason for limiting the area S ₂ of the plate 14 in the range of 0.25S ₁ ~0.9S ₁ is supernatant water discharge pump 16 is less than 0.25 S ₁ The flow generated in the supernatant water 13 at the time of discharging the supernatant water 13 reaches the boundary surface 36 between the supernatant water 13 where the plate 14 does not exist and the floc sedimentation layer 12, and the flocs in the floc sedimentation layer 12 are in the supernatant water 13. soar fear has, floc rise velocity of the supernatant water 13 is too high in the floc precipitation layer 12 from the plate 14 around with the lowering of the plate 14 exceeds 0.9 S ₁ is possibly soar in the supernatant water 13 Because there is.

  The operation of the floc processing apparatus 10 configured as described above will be described. First, polluted water discharged from a construction site, factory, etc. is stored in a reaction tank (not shown), and a flocculant is added to the polluted water in the reaction tank. As a result, the polluted water in the reaction tank becomes a suspension containing solids aggregated as floc. This suspension is then transferred to a settling tank (not shown) to precipitate the floc. The floc precipitated in the settling tank is put into each filter bag 11 accommodated in the four frame bodies 17 of the flock treatment apparatus 10 by a pump (not shown). At this time, part of the supernatant water also flows into the filter bag 11 together with the floc. Then, after standing for 5 to 120 minutes, the flocs in the filter bag 11 in which the flocs are first added together with a part of the supernatant water are settled and separated into the lower floc precipitation layer 12 and the upper supernatant water 13. Therefore, the arm portion 18h of the support means 18 is rotated around the lower support pipe 18b and the upper support pipe 18f together with the rotation shaft 18g so that the plate 14 is positioned above the filter bag 11. When the handle 24b of the manual winch 24 is rotated forward in this state, the wire 24a is fed out and descends while the plate 14 is kept horizontally in the supernatant water 13 from above the supernatant water 13, and the plate 14 is removed from the supernatant water 13. When the plate descends to just above the boundary surface 36 between the floc precipitation layer 12 and the floc sedimentation layer 12, the plate is stopped. When the supernatant water discharge pump 16 is further operated, the supernatant water 13 in the filter bag 11 is discharged by the pump 16. At this time, the floc precipitated at the lower part of the filter bag 11 is blocked by the plate 14 and does not fly into the supernatant water 13, so that most of the supernatant water 13 containing no floc can be discharged efficiently. As a result, the moisture content of the flock precipitation layer 12 (floc containing clean water) can be reduced.

  Further, after a part of the floc and supernatant water 13 is put into the filter bag 11 and allowed to stand, the plate 14 is lowered, and then the supernatant water 13 is completely discharged by the supernatant water discharge pump 16 until the floc sedimentation layer 12 is discharged. Since the contained clean water passes through the filter bag 11, the moisture content of the floc precipitation layer 12 (floc containing clean water) can be further reduced. When the discharge of the supernatant water 13 is completed, the supernatant discharge pump 16 is stopped, the handle 24b of the manual winch 24 is reversed to raise the plate 14, and the arm 18h of the support means 18 together with the rotary shaft 18g is flocked and the supernatant water 13 Is rotated above another filter bag 11 that is separated. Then, the plate 14 is lowered by the same procedure as described above, and the supernatant water 13 is discharged. As described above, the suspension is sequentially stored in the four filter bags 11 and the plate 14 is sequentially lowered in the order in which the suspension is separated into the floc and the supernatant water 13 to discharge the supernatant water 13, so that the work efficiency can be improved. .

  In the above embodiment, a filtration bag is used as the container. However, a tank that prevents any passage of floc and supernatant water in the suspension may be used. Further, in the above embodiment, four cylindrical frames are provided around the support columns holding the plates, and the filter bags are accommodated in these frames, respectively, one around the support columns holding the plates, Two or three cylindrical or rectangular tube-shaped frames may be provided, and a filtration bag may be accommodated in each frame.

10 Flock processing device 11 Filtration bag (container)
12 Flock Precipitation Layer 13 Supernatant Water 14 Plate 16 Supernatant Water Discharge Pump 36 Interface between Supernatant Water and Frock Precipitation Layer

Claims (5)

A container (11) for storing a suspension containing a solid content aggregated as floc by adding a flocculant to polluted water;
The solid floc in the container (11) settles and separates from the supernatant water (13), and can descend while being kept horizontal in the supernatant water (13) from above the supernatant water (13). A plate (14) configured to be able to stop immediately above the boundary surface (36) between the supernatant water (13) and the floc sedimentation layer (12),
A floc treatment apparatus comprising: a supernatant water discharge pump (16) placed on the plate (14) and discharging the supernatant water (13) in the container (11).   The flock processing apparatus according to claim 1, wherein the container (11) is a filtration bag that prevents the passage of the floc in the suspension and allows the passage of the supernatant water (13) in the suspension.   The floc processing apparatus according to claim 1, wherein the plate (14) is configured to stop at a position 0 to 20 mm above the boundary surface (36) between the supernatant water (13) and the floc sedimentation layer (12). .   The flock processing apparatus according to claim 1, wherein a speed at which the plate (14) descends in the supernatant water (13) is 10 to 200 mm / sec. The container (11) is a bottomed cylindrical or bottomed rectangular cylindrical shape is formed and the plate (14) is formed in a circular or square shape, the bottom area of the container (11) when the S _1, said plate (14) floc processing apparatus according to claim 1, wherein the area S ₂ is set in the range of 0.25 S ₁ ～0.9S ₁ of.

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