JP6838087B2 - Inflow unit and settling tank - Google Patents

Description

Embodiments of the present invention relate to an inflow unit and a settling tank.

Sedimentation tanks that settle and separate suspended solids and the like contained in industrial wastewater are known. It is desired for the settling tank to suppress the deterioration of the settling separation performance.

JP-A-2018-79440 Japanese Unexamined Patent Publication No. 2016-159244 Japanese Unexamined Patent Publication No. 2011-101855

An object to be solved by the present invention is to provide an inflow unit and a sedimentation tank capable of suppressing a decrease in sedimentation separation performance.

The inflow unit of the embodiment includes an inflow pipe, an accommodating part, a water supply part to be treated, and a first partition member. The water to be treated supply unit supplies the water to be treated to the settling tank. The inflow pipe is arranged around a rotating shaft that rotates the settling plate of the settling tank. The accommodating portion is connected to the water to be treated unit, surrounds the side end portion of the inflow pipe into which the water to be treated flows, and accommodates the water to be treated. The first partition member is arranged between the outer periphery of the accommodating portion and the inflow pipe in the radial direction of the inflow pipe. The first partition member extends along the circumferential direction of the inflow pipe. The first partition member has a first opening at a position different from the position connected to the water supply unit to be treated. The first partition member forms two flow paths through which the water to be treated flows between the outer periphery of the accommodating portion, and joins the water to be treated that has flowed through the two flow paths in the vicinity of the first opening. Let me.

The side sectional view which shows the whole structure of the settling tank of 1st Embodiment. A side view of the first end of the inflow pipe. The plan sectional view of the inflow part unit of 1st Embodiment. FIG. 3 is a side sectional view of the inflow unit of the first embodiment. FIG. 3 is a plan sectional view of the inflow unit of the second embodiment. FIG. 3 is a side sectional view of the inflow unit of the second embodiment. FIG. 3 is a plan sectional view of the inflow unit of the third embodiment. FIG. 3 is a side sectional view of the inflow unit of the third embodiment. The plan sectional view of the inflow part unit of 4th Embodiment. FIG. 3 is a side sectional view of the inflow unit of the fourth embodiment.

Hereinafter, the inflow unit and the settling tank of the embodiment will be described with reference to the drawings. In the following description, the same reference numerals are given to configurations having the same or similar functions. Then, the duplicate description of those configurations may be omitted.

In the present application, the Z direction, the R direction and the θ direction of the polar coordinate system are defined as follows. The Z direction is the axial direction of the inflow pipe and the distribution part. For example, the Z direction is the vertical direction, and the + Z direction (first direction) is the upward direction. The R direction is the radial direction of the inflow pipe and the distribution part, and the + R direction is the outer direction. The θ direction is the circumferential direction of the inflow pipe and the distribution part, and the + θ direction is the rotation direction of the rotating shaft. For example, the R direction and the θ direction are horizontal directions.

(First Embodiment)
The first embodiment will be described.
The settling tank 1 of the present embodiment is a settling tank that separates minute SS (suspended solids or suspended solids) contained in the water to be treated such as industrial wastewater from the water to be treated, and is used, for example, by the settling separation method. It is a settling tank.

First, the overall configuration of the settling tank 1 will be described with reference to FIG.
FIG. 1 is a side sectional view showing the overall configuration of the settling tank 1 of the present embodiment.
As shown in FIG. 1, the settling tank 1 has a tank body 11, an inflow unit 12, an overflow weir 13, a water discharge unit 14, a scraping unit 15, and a sludge extraction pipe 16. In each figure, the flow of water to be treated is schematically shown by arrows.

The tank body 11 is a container formed in a bottomed tubular shape such as a cylindrical shape or a polygonal tubular shape. The tank body 11 includes, for example, a bottom wall 31 and a peripheral wall 32 that rises upward from the peripheral edge of the bottom wall 31. The tank body 11 has an upper opening 33 at the upper end of the tubular peripheral wall 32. The tank body 11 stores the water to be treated inside and precipitates the flocs. The "flock" means a lump product produced by an agglutinating action or the like, and means, for example, a cotton waste-like lump product formed by adding a coagulant or the like to water to be treated containing suspended solids. The tank body 11 is installed, for example, so that the central axis 11c of the tank body 11 is substantially aligned with the vertical direction. Further, at the central portion of the bottom wall 31 of the tank body 11, a discharge port 31a for discharging the sediment to the outside of the tank body 11 is provided. A sludge extraction pipe 16 is connected to the discharge port 31a.

A coagulation tank (not shown) for pretreating the water to be treated is arranged on the upstream side of the settling tank 1. In the coagulation tank, the coagulant is added to the water to be treated. As a result, specific components in the water to be treated are aggregated to generate flocs. That is, the water to be treated flows into the settling tank 1 in a state containing flocs.

The inflow unit 12 includes, for example, a water supply unit 17 to be treated, a distribution unit (accommodation unit) 18, and an inflow pipe 19. The inflow unit 12 is arranged inside the tank body 11 (that is, inside the settling tank 1). The inflow unit 12 causes the water to be treated, which is supplied from the coagulation tank through the water supply unit 17 to be treated, to flow into the tank body 11 via the distribution unit 18 and the inflow pipe 19. The term "arranged inside the tank body" as used in the present application means that at least a part of the inflow unit 12 is arranged on the upper opening 33 inside the tank body 11.

The water supply unit 17 to be treated is, for example, a supply pipe or an inflow trough extending from the outside of the tank body 11 to the inside of the tank body 11. The term "trough" as used herein means a structure that forms a groove. The water to be treated unit 17 continuously supplies the water to be treated to the inside of the tank body 11. The water to be treated unit 17 is connected to a distribution unit 18 described later to form a water supply port 17a to be treated to the distribution unit 18. The supply port 17a is formed on the inner side surface of the outer peripheral wall 18a of the distribution unit 18 so as to face the central axis 18c of the distribution unit 18. The water to be treated flows in from the supply port 17a toward the central axis 18c of the distribution unit 18.

The distribution unit 18 is also referred to as a "distributed trough" or "inflow pool". In this embodiment, the distribution unit 18 is a trough having a predetermined volume formed by a cylindrical outer peripheral wall 18a and a ring-shaped bottom wall. The distribution unit 18 may have a shape different from that of a cylinder, for example, a polygonal cylinder. The distribution unit 18 is arranged inside the tank body 11. The central shaft 18c of the distribution unit 18 substantially coincides with the central shaft 11c of the tank body 11. The size of the distribution unit 18 can be appropriately set according to the required treatment amount of the water to be treated and the size of the tank body 11.

The inflow pipe 19 is also referred to as a "center well" or a "feed well", and is formed in a tubular shape such as a cylindrical shape or a polygonal tubular shape. The inflow pipe 19 is arranged inside the distribution unit 18. That is, the distribution unit 18 is arranged outside the inflow pipe 19 in the radial direction. The distribution unit 18 surrounds the first end portion 19e of the inflow pipe 19. The distribution unit 18 can accommodate the water to be treated that flows into the inflow pipe 19 from the first end portion 19e. As shown in FIG. 1, the central axis 19c of the inflow pipe 19 substantially coincides with the central axis 18c of the distribution unit 18 and the central axis 11c of the tank body 11. The size of the inflow pipe 19 can be appropriately set according to the required treatment amount of the water to be treated and the size of the tank body 11.

The first end portion 19e of the inflow pipe 19 in the upward direction (first direction) projects upward from the bottom surface of the distribution portion 18 to form a dam 20 in the distribution portion 18. The height of the weir 20 is formed to be at least lower than the outer peripheral wall 18a of the distribution portion 18 and higher than the overflow weir 13.
FIG. 2 is a side view of the first end of the inflow pipe. A plurality of notches 19v, also referred to as "V notches", are formed in the first end portion 19e of the inflow pipe 19. The notch 19v is formed in a V shape that tapers from the upper direction to the lower direction. A plurality of notches 19v are continuously formed in the circumferential direction of the inflow pipe 19.

The water to be treated that has flowed into the distribution unit 18 passes over the weir 20 together with the flocs and flows into the inside of the inflow pipe 19. The water level WL of the water to be treated in the distribution unit 18 is an intermediate position in the height direction of the notch 19v. The plurality of notches 19v evenly distribute the water to be treated flowing from the distribution unit 18 into the inflow pipe 19 in the circumferential direction of the inflow pipe 19.

The lower end 19a of the inflow pipe 19 is separated from the bottom wall 31 of the tank body 11. That is, a flow path through which the water to be treated is dispersed in the horizontal direction is formed between the lower end 19a of the inflow pipe 19 and the bottom wall 31 of the tank body 11. Further, the lower end 19a of the inflow pipe 19 has an opening (inflow port) 19b that allows the inside of the inflow pipe 19 to communicate with the inside of the tank body 11. The water to be treated, which is supplied from the water to be treated 17 to the inflow pipe 19 via the distribution unit 18, flows downward in the inflow pipe 19 and flows from the opening 19b of the lower end 19a of the inflow pipe 19 to the tank body. It is supplied within 11. The water to be treated supplied from the inflow pipe 19 into the tank body 11 slowly rises between the inner wall surface of the peripheral wall 32 of the tank body 11 and the outer peripheral surface of the inflow pipe 19. For example, in this process, a part of the flocs separates from the water to be treated and precipitates.

The overflow weir 13 is provided in the upper part of the tank body 11. The overflow weir 13 is provided in a groove shape in the tank body 11 so that the water to be treated overflowing from the upper end of the overflow weir 13 can be accommodated. For example, the overflow weir 13 is provided along the inner wall surface 32a of the peripheral wall 32 of the tank body 11. The overflow weir 13 causes the water to be treated that has been separated and removed from the flocs to flow out to the water to be treated water discharge unit 14.

The water discharge unit 14 to be treated is, for example, an outflow trough (or a discharge pipe or the like) that communicates with the inside of the overflow weir 13 and extends to the outside of the tank body 11. The water to be treated discharge unit 14 causes the water to be treated overflowing from the upper end of the overflow weir 13 to flow out to the outside of the tank body 11. The water to be treated that has flowed out of the tank body 11 is subjected to further treatment, for example, and is sent to the use point.

The scraping unit 15 includes a rotary shaft 41, a drive motor 42, a support member 43, and a plurality of scraping plates 44. The rotary shaft 41 is arranged at the center of the tank body 11 (the center of the inflow pipe 19). The rotary shaft 41 penetrates the inflow pipe 19 in the axial direction of the central axis 19c of the inflow pipe 19. That is, the inflow pipe 19 is arranged around the rotating shaft 41. The "axial direction of the central axis of the inflow pipe" is a direction substantially parallel to the central axis 19c of the inflow pipe 19. The drive motor 42 is connected to the rotary shaft 41 directly or via a transmission mechanism or the like to rotate the rotary shaft 41. The support member 43 is connected to the lower end of the rotary shaft 41 and extends in the radial direction. The plurality of scraping plates 44 are attached to the support member 43. That is, the rotating shaft 41 rotates the scraping plate 44 of the settling tank 1. The plurality of scraping plates 44 are provided from the support member 43 toward the bottom wall 31 of the tank body 11. According to the scraping unit 15 having such a configuration, the rotation shaft 41 is rotated by the drive motor 42, so that the support member 43 and the plurality of scraping plates 44 are rotated. As a result, the precipitate settled on the bottom wall 31 of the tank body 11 is scraped toward the central portion of the bottom wall 31. The collected sediment is discharged to the outside of the tank body 11 through the discharge port 31a provided in the central portion of the bottom wall 31 and the sludge drawing pipe 16.

The partition plate (partition member, baffle plate) of the distribution unit 18 will be described.
3 and 4 are explanatory views of the inflow unit of the first embodiment. FIG. 3 is a plan sectional view taken along the line III-III of FIG. FIG. 4 is a side sectional view taken along line IV-IV of FIG. As shown in FIG. 3, the distribution unit 18 has a first partition plate 21.

The first partition plate 21 is formed in a cylindrical shape having a first opening 21 g in a part in the θ direction. The first partition plate 21 is arranged coaxially with the central axis 18c of the distribution unit 18. The first partition plate 21 is arranged between the outer peripheral wall 18a of the distribution portion 18 and the inflow pipe 19 in the R direction. The first partition plate 21 extends along the θ direction. As shown in FIG. 4, the first partition plate 21 stands upright from the inner bottom surface 18b of the distribution unit 18 in the + Z direction. The height from the inner bottom surface 18b of the distribution section 18 to the end of the first partition plate 21 in the + Z direction is equal to or higher than the height from the inner bottom surface 18b of the distribution section 18 to the first end portion 19e of the inflow pipe 19. That is, the end portion of the first partition plate 21 in the + Z direction is arranged above the water level of the water to be treated contained in the distribution portion 18.

As shown in FIG. 3, the first partition plate 21 partitions the distribution unit 18 into the first flow path 51 and the second flow path 52 in the R direction. The first flow path 51 is outside in the R direction and is formed between the outer peripheral wall 18a of the distribution portion 18 and the first partition plate 21. The second flow path 52 is formed inside the R direction between the first partition plate 21 and the inflow pipe 19. The first flow path 51 and the second flow path 52 are formed in an annular shape when viewed from the Z direction. The widths of the first flow path 51 and the second flow path 52 in the R direction are equivalent to each other.

The first partition plate 21 has a first opening 21 g. The first opening 21g is formed in a part of the first partition plate 21 in the θ direction. The first opening 21g is formed from the inner bottom surface 18b of the distribution portion 18 to the end portion of the first partition plate 21 in the + Z direction. The first opening 21g is formed at a position different from the supply port 17a of the water to be treated 17 in the θ direction. The first opening 21g is formed on the opposite side of the supply port 17a in the θ direction. The first opening 21g is formed on the opposite side of the supply port 17a with the inflow pipe 19 interposed therebetween. The first opening 21g connects the first flow path 51 and the second flow path 52.

The water to be treated is supplied to the distribution unit 18 from the supply port 17a of the water to be treated 17. The water to be treated comes into contact with the first partition plate 21 and flows into the first flow path 51, and does not directly flow into the inflow pipe 19. The water to be treated is divided into two directions from the supply port 17a in the + θ direction and the −θ direction, and flows through the first flow path 51. The water to be treated, which is divided into two parts and circulated, merges at the first merging portion 51c on the opposite side of the supply port 17a in the θ direction. A first opening 21g of the first partition plate 21 is formed inside the first merging portion 51c in the R direction. The water to be treated flows into the second flow path 52 from the first opening 21 g. The water to be treated is divided into two hands in the + θ direction and the −θ direction from the first opening 21 g, and flows through the second flow path 52. The water to be treated flows through the second flow path 52 along the outer peripheral surface of the inflow pipe 19. In the process of flowing through the second flow path 52, the water to be treated passes over the first end 19e of the inflow pipe 19 and flows into the inside of the inflow pipe 19.

As described above, flocs are generated in the coagulation tank on the upstream side of the settling tank 1. The water to be treated flows into the settling tank 1 in a state of containing flocs. When the water to be treated is supplied to the distribution unit 18, the flocs may be broken and decomposed into fine flocs. In particular, the flocs are fragile when the inflow head from the water to be treated 17 to the distribution unit 18 is large or when the inflow speed to the distribution unit 18 is large. The fine flocs are separated from the water to be treated inside the settling tank 1 and are difficult to settle. Therefore, if the fine flocs flow into the inflow pipe 19, the settling separation performance of the settling tank 1 may deteriorate.

As described above, the water to be treated that has flowed into the distribution unit 18 flows in the first flow path 51 and the second flow path 52 in order. By flowing through a long flow path, the frequency of fine floc association increases. In particular, when the water to be treated merges at the first merging portion 51c, the association of fine flocs becomes remarkable. As a result, the fine flocs are aggregated and the regeneration of flocs is promoted. The regenerated flocs are separated from the water to be treated and settled inside the settling tank 1. Therefore, the deterioration of the quality of the treated water is suppressed.

Some heavy flocs cannot get over the first end 19e of the inflow pipe 19 and stay in the distribution section 18. The stagnant flocs are deposited on the inner bottom surface 18b of the distribution unit 18. If the flocs are unevenly deposited, the flow of water to be treated in the distribution unit 18 becomes non-uniform. Therefore, it becomes difficult to evenly flow the water to be treated into the inflow pipe 19 in the circumferential direction of the inflow pipe 19. When the inflow of the water to be treated into the inflow pipe 19 becomes non-uniform, a local high-speed flow of the water to be treated is generated inside the settling tank 1. As a result, the substantial residence time of the water to be treated inside the settling tank 1 is reduced. As a result, the settling separation performance of the settling tank 1 may deteriorate.

As described above, the first partition plate 21 partitions the distribution unit 18 into the first flow path 51 and the second flow path 52 in the R direction. As a result, the flow path cross-sectional area of the first flow path 51 and the second flow path 52 becomes small. The flow velocity of the water to be treated flowing through the first flow path 51 and the second flow path 52 is so high that floc accumulation does not occur. The flocs flow into the inflow pipe 19 without accumulating in the distribution section 18. Since the accumulation of flocs is suppressed, the flow of water to be treated in the distribution unit 18 becomes uniform. The water to be treated evenly flows into the inflow pipe 19 in the circumferential direction of the inflow pipe 19. Inside the settling tank 1, the water to be treated is evenly distributed at a low speed without locally generating a high-speed flow of the water to be treated. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed.

As described above, the inflow unit 12 has an inflow pipe 19, a distribution unit 18, a water supply unit 17 to be treated, and a first partition plate 21. The inflow pipe 19 is arranged around a rotating shaft 41 that rotates the scraping plate 44 of the settling tank 1. The distribution unit 18 is arranged outside the inflow pipe 19 in the radial direction and surrounds the first end portion 19e of the inflow pipe 19 in the + Z direction. The distribution unit 18 can accommodate the water to be treated that flows into the inside of the inflow pipe 19 from the first end portion 19e. The water to be treated 17 supplies the water to be treated 17a to the distribution unit 18. The first partition plate 21 is arranged between the outer circumference of the distribution portion 18 and the inflow pipe 19 in the θ direction. The first partition plate 21 extends along the θ direction. The first partition plate 21 has a first opening 21g at a position different from that of the supply port 17a.

The first partition plate 21 forms a first flow path 51 and a second flow path 52 in the distribution section 18. The first flow path 51 and the second flow path 52 are connected by a first opening 21g. The water to be treated flows through the first flow path 51 and the second flow path 52 in order and flows into the inflow pipe 19. Since the flow path of the water to be treated in the distribution unit 18 becomes long, the regeneration of flocs from the fine flocs is promoted. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed. In addition, the cross-sectional area of the flow path of the water to be treated in the distribution unit 18 becomes smaller. The flow velocity of the water to be treated is so high that floc accumulation does not occur. Since the accumulation of flocs is suppressed, the water to be treated flows evenly and at a low speed inside the settling tank 1. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed.

The first opening 21g is formed on the opposite side of the supply port 17a in the θ direction.
As a result, the flow path of the water to be treated in the distribution unit 18 becomes the longest. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed.

In the inflow unit 12, the widths of the first flow path 51 and the second flow path 52 in the R direction are equal to each other. On the other hand, the width of the first flow path 51 may be narrower than the width of the second flow path 52. As a result, the flow velocity of the water to be treated in the first flow path 51 becomes high. A part of the water to be treated that has flowed from the water supply unit 17 to the distribution unit 18 flows through the first flow path 51 in a turbulent state. This increases the chances of meeting fine flocs and promotes flocs regeneration.

(Second Embodiment)
5 and 6 are explanatory views of the inflow unit of the second embodiment. FIG. 5 is a plan sectional view of a portion corresponding to lines III-III in FIG. FIG. 6 is a side sectional view taken along the line VI-VI of FIG. The inflow unit 212 of the second embodiment is different from the first embodiment in that it has a second partition plate 22. Of the second embodiment, the description of the same part as that of the first embodiment will be omitted.

As shown in FIG. 5, the distribution unit 18 of the inflow unit 212 has a second partition plate (second partition member) 22 in addition to the first partition plate 21.
The second partition plate 22 is formed in a cylindrical shape having a second opening 22 g in a part in the θ direction. The second partition plate 22 is arranged coaxially with the central axis 18c of the distribution unit 18. The second partition plate 22 is arranged between the first partition plate 21 and the inflow pipe 19 in the R direction. The second partition plate 22 extends along the θ direction. As shown in FIG. 6, the second partition plate 22 stands upright from the inner bottom surface 18b of the distribution unit 18 in the + Z direction. The height of the second partition plate 22 in the Z direction is the same as that of the first partition plate 21.

As shown in FIG. 5, the first partition plate 21 and the second partition plate 22 partition the distribution portion 18 into the first flow path 51, the second flow path 52, and the third flow path 53 in the R direction. The first flow path 51 is formed between the outer peripheral wall 18a of the distribution portion 18 and the first partition plate 21. The second flow path 52 is formed between the first partition plate 21 and the second partition plate 22. The third flow path 53 is formed between the second partition plate 22 and the inflow pipe 19. The widths of the first flow path 51, the second flow path 52, and the third flow path 53 in the R direction are equivalent to each other.

The second partition plate 22 has a second opening 22 g. The second opening 22g is formed in a part of the second partition plate 22 in the θ direction. The second opening 22g is formed at a position different from that of the first opening 21g in the θ direction. The second opening 22g is formed on the opposite side of the first opening 21g in the θ direction. The second opening 22g is formed on the opposite side of the first opening 21g with the inflow pipe 19 interposed therebetween. The second opening 22g connects the second flow path 52 and the third flow path 53.

The water to be treated flows through the first flow path 51 and the second flow path 52 as in the first embodiment. That is, the water to be treated is divided into two hands in the + θ direction and the −θ direction from the first opening 21 g and flows through the second flow path 52. The water to be treated divided into two hands merges at the second merging portion 52c on the opposite side of the first opening 21g in the θ direction. When the water to be treated merges at the second merging portion 52c, the fine flocs are remarkably associated to promote the regeneration of the flocs. A second opening 22g of the second partition plate 22 is formed inside the second merging portion 52c in the R direction. The water to be treated flows into the third flow path 53 from the second opening 22 g. The water to be treated is divided into two hands in the + θ direction and the −θ direction from the second opening 22 g, and flows through the third flow path 53. The water to be treated flows through the third flow path 53 along the outer peripheral surface of the inflow pipe 19. In the process of flowing through the third flow path 53, the water to be treated passes over the first end 19e of the inflow pipe 19 and flows into the inside of the inflow pipe 19.

As described above, the inflow unit 212 has the second partition plate 22. The second partition plate 22 is arranged inside the first partition plate 21 in the R direction. The second partition plate 22 has a second opening 22g on the opposite side of the first opening 21g in the θ direction.
The second partition plate 22 forms a third flow path 53 in the distribution section 18. The second flow path 52 and the third flow path 53 are connected by a second opening 22g. The water to be treated flows through the first flow path 51, the second flow path 52, and the third flow path 53 in this order, and flows into the inflow pipe 19. Since the flow path of the water to be treated in the distribution unit 18 becomes longer, the regeneration of flocs from the fine flocs is promoted. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed. Further, the cross-sectional area of the flow path of the water to be treated in the distribution unit 18 becomes smaller. The flow velocity of the water to be treated is so high that floc accumulation does not occur. Since the accumulation of flocs is suppressed, the water to be treated flows evenly and at a low speed inside the settling tank 1. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed.

In the inflow unit 212, the widths of the first flow path 51, the second flow path 52, and the third flow path 53 in the R direction are equal to each other. On the other hand, the width of the first flow path 51 may be narrower than the width of the second flow path 52 and the third flow path 53. As a result, the flow velocity of the first flow path 51 becomes faster. A part of the water to be treated that has flowed from the water supply unit 17 to the distribution unit 18 flows through the first flow path 51 in a turbulent state. This increases the chances of meeting fine flocs and promotes flocs regeneration.

The inflow unit 212 has two partition plates, a first partition plate 21 and a second partition plate 22. On the other hand, the inflow unit may have a plurality of partition plates of three or more. At this time, the openings of the partition plates adjacent to each other in the R direction are arranged on the opposite sides in the θ direction.

(Third Embodiment)
7 and 8 are explanatory views of the inflow unit of the third embodiment. FIG. 7 is a plan sectional view of a portion corresponding to lines III-III in FIG. FIG. 8 is a side sectional view taken along the line VIII-VIII of FIG. The inflow unit 312 of the third embodiment is different from the first embodiment in that it has an inflow opening 19 g of the inflow pipe 19. Of the third embodiment, the description of the same part as that of the first embodiment will be omitted.

As shown in FIG. 7, the inflow pipe 19 has an inflow opening 19g.
The inflow opening 19g is formed in a part of the inflow pipe 19 in the θ direction. The inflow opening 19g is formed from the inner bottom surface 18b of the distribution portion 18 to the end of the inflow pipe 19 in the + Z direction. The inflow opening 19g is formed at a position different from that of the first opening 21g of the first partition plate 21 in the θ direction. The inflow opening 19g is formed on the opposite side of the first opening 21g in the θ direction. The inflow opening 19g is formed on the opposite side of the first opening 21g with the inflow pipe 19 interposed therebetween. The inflow opening 19g connects the second flow path 52 and the inside of the inflow pipe 19.

The inflow pipe 19 does not have the plurality of notches 19v shown in FIG. 2 at the first end 19e in the + Z direction. The water to be treated does not flow into the inside of the inflow pipe 19 over the first end portion 19e of the inflow pipe 19. The water to be treated flows into the inside of the inflow pipe 19 through the inflow opening 19g.
In the settling tank 1 shown in FIG. 1, the overflow weir 13 is arranged in the + Z direction as compared with the first embodiment. As a result, the water level of the water to be treated inside the distribution unit 18 becomes equal to the water level of the water to be treated inside the inflow pipe 19.

The water to be treated flows through the first flow path 51 and the second flow path 52 as in the first embodiment. That is, the water to be treated is divided into two hands in the + θ direction and the −θ direction from the first opening 21g of the first partition plate 21, and flows through the second flow path 52. The water to be treated divided into two hands merges at the second merging portion 52c on the opposite side of the first opening 21g in the θ direction. When the water to be treated merges at the second merging portion 52c, the fine flocs are remarkably associated to promote the regeneration of the flocs. An inflow opening 19g of the inflow pipe 19 is formed inside the second merging portion 52c in the R direction. The water to be treated flows into the inside of the inflow pipe 19 from the inflow opening 19g.

As described above, the inflow pipe 19 of the inflow unit 312 has an inflow opening 19g. The inflow opening 19g is arranged on the opposite side of the first opening 21g in the θ direction. The inflow opening 19g extends from the inner bottom surface 18b of the distribution portion 18 to the first end portion 19e in the + Z direction.
As a result, the water to be treated flows into the inside of the inflow pipe 19 from the inflow opening 19g without getting over the first end portion 19e in the + Z direction of the inflow pipe 19. Therefore, the flow path of the water to be treated in the distribution unit 18 becomes longer. Further, the flocs contained in the water to be treated flow into the inside of the inflow pipe 19 without being broken. This floc separates from the water to be treated and settles. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed.

(Fourth Embodiment)
9 and 10 are explanatory views of the inflow unit of the fourth embodiment. FIG. 9 is a plan sectional view of a portion corresponding to lines III-III in FIG. FIG. 10 is a side sectional view taken along line XX of FIG. The inflow unit 412 of the fourth embodiment is different from the second embodiment in that it has an inflow opening 19 g of the inflow pipe 19. Of the fourth embodiment, the description of the same part as that of the second embodiment will be omitted.

As shown in FIG. 9, the inflow pipe 19 has an inflow opening 19g.
The inflow opening 19g is formed in a part of the inflow pipe 19 in the θ direction. The inflow opening 19g is formed from the inner bottom surface 18b of the distribution portion 18 to the end of the inflow pipe 19 in the + Z direction. The inflow opening 19g is formed at a position different from that of the second opening 22g of the second partition plate 22 in the θ direction. The inflow opening 19g is formed on the opposite side of the second opening 22g in the θ direction. The inflow opening 19g is formed on the opposite side of the second opening 22g with the inflow pipe 19 interposed therebetween. The inflow opening 19g connects the third flow path 53 and the inside of the inflow pipe 19.

The inflow pipe 19 does not have the plurality of notches 19v shown in FIG. 2 at the first end 19e in the + Z direction. The water to be treated does not flow into the inside of the inflow pipe 19 over the first end portion 19e of the inflow pipe 19. The water to be treated flows into the inside of the inflow pipe 19 through the inflow opening 19g.
In the settling tank 1 shown in FIG. 1, the overflow weir 13 is arranged in the + Z direction as compared with the second embodiment. As a result, the water level of the water to be treated inside the distribution unit 18 becomes equal to the water level of the water to be treated inside the inflow pipe 19.

The water to be treated flows through the first flow path 51, the second flow path 52, and the third flow path 53 as in the second embodiment. That is, the water to be treated is divided into two hands in the + θ direction and the −θ direction from the second opening 22g of the second partition plate 22, and flows through the third flow path 53. The water to be treated divided into two hands merges at the third merging portion 53c on the opposite side of the second opening 22g in the θ direction. When the water to be treated merges at the third merging portion 53c, the fine flocs are remarkably associated with each other to promote the regeneration of flocs. An inflow opening 19g of the inflow pipe 19 is formed inside the third merging portion 53c in the R direction. The water to be treated flows into the inside of the inflow pipe 19 from the inflow opening 19g.

As described above, the inflow pipe 19 of the inflow unit 412 has an inflow opening 19g. The inflow opening 19g is arranged on the opposite side of the second opening 22g in the θ direction. The inflow opening 19g extends from the inner bottom surface 18b of the distribution portion 18 to the first end portion 19e in the + Z direction.
As a result, the water to be treated flows into the inside of the inflow pipe 19 from the inflow opening 19g without getting over the first end portion 19e in the + Z direction of the inflow pipe 19. Therefore, the flow path of the water to be treated in the distribution unit 18 becomes longer. Further, the flocs contained in the water to be treated flow into the inside of the inflow pipe 19 without being broken. This floc separates from the water to be treated and settles. Therefore, the deterioration of the settling separation performance of the settling tank 1 is suppressed.

According to at least one embodiment described above, the inflow unit 12 has a first partition plate 21. The first partition plate 21 is arranged between the outer circumference of the distribution portion 18 and the inflow pipe 19 in the R direction. The first partition plate 21 extends along the θ direction and has a first opening 21 g at a position different from the supply port 17a. As a result, it is possible to suppress a decrease in the sedimentation separation performance of the sedimentation tank 1.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

1 ... Sedimentation tank, 11 ... Tank body, 12, 212, 312, 412 ... Inflow unit, 17 ... Water supply unit to be treated, 17a ... Supply port, 18 ... Distribution unit (accommodation unit), 19 ... Inflow pipe, 19e ... 1st end, 19g ... Inflow opening, 21 ... 1st partition plate (1st partition member), 21g ... 1st opening, 22 ... 2nd partition plate (2nd partition member), 22g ... 2nd opening, 41 ... rotating shaft, 44 ... scraping plate.

Claims (9)

The water to be treated water supply unit that supplies the water to be treated to the settling tank,
An inflow pipe disposed around the rotating shaft for rotating the raking plates of the sedimentation tank,
An accommodating portion that is connected to the water to be treated, surrounds the side end of the inflow pipe into which the water to be treated flows, and accommodates the water to be treated.
Disposed between the inlet pipe and the outer periphery of the receiving portion in the radial direction before Symbol inlet tube, it extends along the circumferential direction of the inlet pipe, a first to a position different from the position to connect with the water to be treated supply unit have a opening, said as to form two flow paths for-treatment water flows, to merge the water to be treated flows through the two flow paths in the first opening vicinity between the outer periphery of the housing part With a first partition member,
Inflow unit. The first opening is formed on the opposite side of the position connected to the water supply portion to be treated in the circumferential direction.
The inflow unit according to claim 1. The water to be treated water supply unit that supplies the water to be treated to the settling tank,
An inflow pipe arranged around a rotating shaft that rotates the settling plate of the settling tank,
An accommodating portion that is connected to the water to be treated, surrounds the side end of the inflow pipe into which the water to be treated flows, and accommodates the water to be treated.
The first opening is arranged between the outer periphery of the accommodating portion and the inflow pipe in the radial direction of the inflow pipe, extends along the circumferential direction of the inflow pipe, and is different from the position connected to the water supply portion to be treated. To form two flow paths through which the water to be treated flows with the outer periphery of the accommodating portion, and to join the water to be treated flowing through the two flow paths in the vicinity of the first opening. It has one partition member and
The inflow pipe has an inflow opening for allowing the water to be treated that has flowed through the accommodating portion to flow into the inflow pipe on the opposite side of the first opening in the circumferential direction.
Inflow unit. The water to be treated water supply unit that supplies the water to be treated to the settling tank,
An inflow pipe arranged around a rotating shaft that rotates the settling plate of the settling tank,
An accommodating portion that is connected to the water to be treated, surrounds the side end of the inflow pipe into which the water to be treated flows, and accommodates the water to be treated.
The first opening is arranged between the outer periphery of the accommodating portion and the inflow pipe in the radial direction of the inflow pipe, extends along the circumferential direction of the inflow pipe, and is different from the position connected to the water supply portion to be treated. The first partition member having
A second that is arranged between the first partition member and the inflow pipe in the radial direction, extends along the circumferential direction of the inflow pipe, and has a second opening on the opposite side of the first opening in the circumferential direction. With a partition member,
Inflow unit. The inflow pipe has an inflow opening for allowing the water to be treated that has flowed through the accommodating portion to flow into the inflow pipe on the opposite side of the second opening in the circumferential direction.
The inflow unit according to claim 4. The first partition member forms two flow paths through which the water to be treated flows between the outer periphery of the accommodating portion, and the water to be treated that has flowed through the two flow paths in the vicinity of the first opening. Join,
The inflow unit according to claim 4. The second partition member forms two flow paths through which the water to be treated flows between the second partition member and the first partition member, and the water to be treated flowing through the two flow paths in the vicinity of the second opening. Join,
The inflow unit according to claim 4 or 5. The first opening is formed on the opposite side of the position connected to the water supply portion to be treated in the circumferential direction.
The inflow unit according to claim 3 or 4. With the tank body
The inflow unit according to any one of claims 1 to 8.
Settlement tank.

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