JP2017087196A - Settling tank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a settling tank in which a solid content such as a flock in treated water can be precipitated with good efficiency.SOLUTION: A settling tank has a tank body, a shell, a feed part and a discharge part. The shell is located inside the tank body, and an upper end and a lower end thereof are opened. The feed part feeds treated water inside the tank body and outside the shell. An overflow part is located inside the shell and overflows treated water from an upper end thereof. The discharge part recovers treated water overflown from the overflow part and discharges the same outside the tank body.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to a settling tank.

In the conventional sedimentation tank, the water to be treated is supplied to the upper side of the feed well. The feed well is disposed at the center of the tank body. The water to be treated descends in the feed well. The water to be treated that has reached the bottom of the tank rises over time in the flow path outside the feed well. The water to be treated rises to the upper end of the overflow weir provided outside the feed well. The treated water overflows from the overflow weir.
While the water to be treated reaches the upper end of the overflow weir from the bottom of the tank body, the floc in the water to be treated sinks by its own weight. Flock settles at the bottom of the tank. The floc is separated from the treated water. As a result, the treated water that overflows from the upper end of the overflow weir is clarified water from which flocs have been removed.

However, in the flow path outside the feed well, the floc settles against the rising flow of the water to be treated, so that a long time is required for the precipitation.
Furthermore, the water to be treated ejected downward from the feed well disturbs the flow of the flow path outside the feed well.
For example, the water to be treated ejected from the feed well toward the bottom of the tank body hits sludge on which flocs are precipitated. Sludge is rolled up by the jet of water to be treated. The rolled up sludge diffuses into the flow path outside the feed well.
The water to be treated ejected downward from the feed well flows along the bottom of the tank body while the water to be treated in the vicinity of the feed well is wound downward. The flow of water to be treated along the bottom of the tank body collides with the inner wall of the tank body. Such a flow in the vicinity of the bottom of the tank body induces a circulating flow that rises a little along the inner wall of the tank body and then returns toward the feed well. For this reason, a uniform upward flow is not formed near the bottom of the flow path outside the feed well, and the sedimentation of the floc is difficult to stabilize.

Japanese Patent No. 4696646

  The problem to be solved by the present invention is to provide a sedimentation tank capable of efficiently precipitating solids such as floc in the water to be treated.

  The sedimentation tank of the embodiment has a tank body, a pipe body, a supply part, an overflow part, and a discharge part. The pipe body is arrange | positioned inside the tank body, and an upper end and a lower end open. The supply unit supplies the water to be treated inside the tank body and outside the tube body. An overflow part is arrange | positioned inside a pipe body, and makes to-be-processed water overflow from an upper end. A discharge part collects the to-be-processed water which overflows from an overflow part, and discharges it to the exterior of a tank.

The typical longitudinal section showing the example of composition of the sedimentation tank of a 1st embodiment. The typical top view showing the example of composition of the sedimentation tank of a 1st embodiment. A view in FIG. B view in FIG. CC sectional drawing in FIG. The schematic diagram explaining the sedimentation speed of a flock. The typical longitudinal section showing the example of composition of the sedimentation tank of a 2nd embodiment. DD sectional drawing in FIG. The typical enlarged view of E view in FIG. The schematic diagram explaining the effect | action of the inclined plate of the sedimentation tank of 2nd Embodiment. Operation | movement explanatory drawing of the inclination board of the sedimentation tank of 2nd Embodiment. The schematic diagram which shows the 1st modification of the inclination board which can be used for the sedimentation tank of 2nd Embodiment. The schematic diagram which shows the 2nd modification of the inclination board which can be used for the sedimentation tank of 2nd Embodiment. The typical longitudinal section showing the example of composition of the sedimentation tank of a 3rd embodiment. The typical longitudinal section showing the example of composition of the sedimentation tank of a 4th embodiment. The typical longitudinal section showing the example of composition of the sedimentation tank of a 5th embodiment. The typical longitudinal section showing the example of composition of the sedimentation tank of a 6th embodiment. The typical longitudinal section showing the example of composition of the sedimentation tank of a 7th embodiment.

  Hereinafter, the sedimentation tank of an embodiment is explained with reference to drawings. In addition, in each figure, the same code | symbol is attached | subjected about the same structure.

(First embodiment)
FIG. 1 is a schematic longitudinal sectional view showing a configuration example of a sedimentation tank according to the first embodiment. FIG. 2 is a schematic plan view illustrating a configuration example of the sedimentation tank according to the first embodiment. FIG. 3 is a view A in FIG. FIG. 4 is a B view in FIG.

As shown in FIG. 1, the sedimentation tank 50 of the present embodiment is a device that precipitates and removes the solid content in the water Wf to be treated supplied from outside the device. The to-be-processed water Wf from which the solid content has been removed by precipitation is discharged to the outside of the precipitation tank 50 as clarified water. Hereinafter, when it is clearly indicated that the water to be treated Wf is clarified water, it is expressed as clarified water Wc.
The sedimentation tank 50 has a tank body 1 (tank body), a supply path 6 (supply part), a drainage receiving part 7 (discharge part), a center well 8 (tubular body), and a scraping mechanism 10. .

The tank body 1 is filled with the water to be treated Wf in order to precipitate and remove the solid matter. The shape of the tank body 1 is a bottomed cylindrical shape that opens upward. The bottom surface portion 1b of the tank body 1 has a mortar shape that gently slopes from the outer edge portion toward the center portion.
A sediment extraction tube 15 is connected to the center of the bottom surface portion 1b.
The sediment extraction pipe 15 extracts the sediment that precipitates on the bottom surface portion 1 b to the outside of the tank body 1.
A wall 1a extends upward at the outer edge of the bottom 1b.
An inflow trough 2 is connected to the upper part of the wall 1a. The inflow trough 2 allows the water to be treated Wf to flow into the tank body 1 through the opening 2a that opens to the wall 1a.

The shape of the wall 1a in plan view can be various shapes such as a circular shape and a polygonal shape. In this embodiment, as shown in FIG. 2, the planar view shape of the wall part 1a is circular.
Inside the wall portion 1a, a supply path 6, a drainage receiving portion 7, and a center well 8 are arranged in this order from the outer peripheral side toward the center portion.

In the following description, the axial direction, the circumferential direction, and the radial direction may be used when describing the relative positions of the axial and cylindrical members that can identify the central axis.
The axial direction is a direction along the central axis. The circumferential direction is a direction that goes around the central axis. The radial direction is a direction along a line intersecting the central axis in a plane orthogonal to the central axis.

The supply path 6 supplies the water to be treated Wf introduced from the inflow trough 2 to a region inside the tank body 1 and outside the center well 8.
The supply path 6 has an outer peripheral supply path 6A and a plurality of radial supply paths 6B.

The outer peripheral supply path 6 </ b> A has a supply path bottom surface portion 4 and a circumferential supply weir 5.
The supply path bottom surface portion 4 is an annular plate member in plan view. The supply path bottom surface portion 4 is disposed horizontally. The outer edge portion of the supply path bottom surface portion 4 is fixed to the inner peripheral surface of the wall portion 1a. A circumferential supply weir 5 is erected on the inner edge of the supply path bottom surface portion 4. The circumferential supply weir 5 is a cylindrical member arranged so as to be concentric with the wall portion 1 a of the tank body 1.

As shown in FIG. 1, the supply channel bottom surface portion 4 is disposed below the opening 2 a in the tank body 1 of the inflow trough 2.
The height of the circumferential supply weir 5 from the supply path bottom surface portion 4 is substantially constant over the circumferential direction. The supply weir upper end 5 a of the circumferential supply weir 5 is located above the opening 2 a in the tank body 1 of the inflow trough 2. The supply weir upper end 5 a is located below the upper end of the wall portion 1 a of the tank body 1.
In the cross section along the radial direction, the outer peripheral side supply path 6 </ b> A is a rectangular groove portion that is opened upward by the wall portion 1 a, the supply path bottom surface portion 4, and the circumferential supply weir 5. The groove depth of the outer periphery side supply path 6 </ b> A is defined by the height of the circumferential supply weir 5 on the supply path bottom surface portion 4.

As shown in FIG. 3, in the present embodiment, a large number of notches N are formed at the upper end of the circumferential supply weir 5 so as to be spaced apart in the circumferential direction. However, the notch N is not shown in FIG.
The notch N penetrates in the plate thickness direction (radial direction) of the circumferential supply weir 5. For example, the shape of the notch N may be a V shape, a U shape, a rectangular shape, or the like when viewed from the radial direction. In FIG. 3, as an example, a V-shaped notch N is drawn as viewed from the radial direction.
The depth of the notch N from the supply weir upper end 5a is equal to or greater than the amount of deviation from the horizontal plane of the supply weir upper end 5a that may be caused by an installation error of the tank body 1 or a manufacturing error of the circumferential supply weir 5. For this reason, even if the supply weir upper end 5a is inclined from the horizontal plane and the supply weir upper end 5a is higher than the surface of the treated water Wf in the outer peripheral supply path 6A, the treated water Wf flows through the notch N. Can do.

As shown in FIG. 3, a radial supply path 6 </ b> B is connected to the upper end portion of the circumferential supply weir 5. In the present embodiment, the radial supply path 6 </ b> B is formed by the flange 9. The eaves 9 are rectangular grooves that are formed by the eaves bottom surface portion 9a and the supply weir 9b and open upward. The eaves 9 are extended from the circumferential supply weir 5 to the drainage receiving part 7 described later along the radial direction (the depth direction in FIG. 3).
The bottom surface portion 9 a has a flat plate shape elongated in the radial direction of the circumferential supply weir 5. The collar bottom surface portion 9a is disposed substantially horizontally at a position higher than the supply path bottom surface portion 4 and lower than the lower end of the notch N.
The supply weir 9b is erected along the longitudinal direction of the bottom surface portion 9a at both ends of the bottom surface portion 9a in the short direction (lateral direction in FIG. 3). The supply weir upper end 9 c in each supply weir 9 b is flush with the supply weir upper end 5 a of the circumferential supply weir 5.
One end of the flange 9 is open at the connection with the circumferential supply weir 5. For this reason, the radial supply path 6B formed by the flange 9 is in communication with the outer peripheral side supply path 6A.
The other end of the trough 9 is closed by a drain receiving part 7 described later.

  As shown in FIG. 4, in this embodiment, a notch N similar to that formed in the circumferential supply weir 5 is spaced apart in the longitudinal direction of the supply weir 9b at the upper end of each supply weir 9b. Many are formed.

  As shown in FIG. 2, the cage | basket 9 in this embodiment is each provided in four places which divide the inner peripheral surface of the circumferential supply weir 5 and the outer peripheral surface of the drainage receiving part 7 mentioned later into four equal parts.

As shown in FIG. 2, the drainage receiving part 7 has a bottom face part 7a and a wall part 7b.
The bottom surface part 7a is a disk-shaped member arranged horizontally. A center well 8 described later passes through the center of the bottom surface portion 7a.
The wall portion 7b is a cylindrical member arranged so as to be concentric with the wall portion 1a of the tank body 1. The wall portion 7b is erected upward from the outer edge portion of the bottom surface portion 7a. The edge part of each ridge 9 is connected to the outer peripheral surface of the wall part 7b.

As shown in FIG. 1, the bottom surface portion 7a is disposed at a position below the supply weir upper end 5a.
The upper end of the wall 7b is located above the supply weir upper end 5a and below the upper end of the wall 1a of the tank body 1.
The drainage receiving part 7 accommodates the to-be-processed water Wf overflowing from the center well 8 mentioned later.
The outflow trough 3 (discharge part) is connected to the lower end side of the wall part 7b. The outflow trough 3 is a tubular member that causes the treated water Wf overflowing the drainage receiving portion 7 to flow out of the tank body 1.
The outflow trough 3 extends from the wall 7 b to the outside of the tank body 1 along the radial direction of the tank body 1. The outflow trough 3 opens inside the drainage receiving portion 7 at the connection portion with the wall portion 7b. The outflow trough 3 penetrates the circumferential supply weir 5 and the wall 1a.

As shown in FIG. 1, the center well 8 is a tubular body that is disposed inside the tank body 1 and has an upper end 8 a (upper end, overflow portion) and a lower end 8 b (lower end) of the well.
As shown in FIG. 2, the center well 8 in the present embodiment is a cylindrical member having an outer diameter smaller than the inner diameter of the wall portion 7 b of the drainage receiving portion 7. The center well 8 is arranged so as to be concentric with the wall 1a of the tank body 1.
As shown in FIG. 1, the center well 8 passes through the bottom surface portion 7 a of the drainage receiving portion 7.
The upper end 8a of the well is along a horizontal plane. The well upper end 8 a is located below the supply weir upper end 5 a of the circumferential supply weir 5.
The notch N described above may be provided at the upper end of the center well 8.
The center well 8 extends from the bottom surface portion 7a to a lower half side region in the tank body 1. A gap is provided between the well lower end 8b and the bottom surface portion 1b so that a scraping mechanism 10 described later can be disposed.

As shown in FIG. 2, a plurality of flow paths and a plurality of openings are formed in the upper part inside the tank body 1 by the above-described configuration.
In the annular region along the inner peripheral surface of the wall portion 1a, an annular flow path in plan view by the outer peripheral supply path 6A is formed. The treated water Wf can flow from the inflow trough 2 into the outer peripheral side supply path 6A.
Between the circumferential supply weir 5 and the drainage receiving part 7, four radial supply paths 6B communicating with the outer peripheral supply path 6A are formed.
For this reason, inflow openings Si1, Si2, Si3, and Si4 are formed between the circumferential supply weir 5 and the wall portion 7b of the drainage receiving portion 7 along the circumferential direction.

The inflow opening Si <b> 1 is formed in a region sandwiched between the inflow trough 2 and the drainage receiving portion 7. The inflow openings Si2, Si3, Si4 are arranged in this order clockwise from the inflow opening Si1. In the present embodiment, the outflow trough 3 crosses the inflow opening Si3.
Except for the crossing of the outflow trough 3, the inflow openings Si1, Si2, Si3, and Si4 have the same shape. Hereinafter, when the inflow openings Si1, Si2, Si3, and Si4 are collectively referred to, or when the description applies to any of the inflow openings Si1, Si2, Si3, and Si4, the inflow opening Si may be simply referred to.

The inflow opening Si is an opening surrounded by the supply weirs 9b of the two reeds 9 adjacent to each other in the circumferential direction, and the supply weir upper end 5a and the wall part 7b between the two reeds 9. The shape of the inflow opening Si in plan view is a fan shape.
When the treated water Wf is filled in the supply path 6, the treated water Wf that has passed over the supply weir upper end 5a and the supply weir upper end 9c can flow into the inflow opening Si.

A well opening So that is a circular opening is formed inside the well upper end 8 a of the center well 8. The well upper end 8a is lower than the supply weir upper end 5a. The well lower end 8b is opened inside the tank body 1. For this reason, the to-be-processed water Wf inside the tank main body 1 can be spouted to the spout opening So.
In the present embodiment, the opening area of the spring opening So is smaller than the sum of the opening areas of the inflow openings Si1, Si2, Si3, and Si4.
Between the outer peripheral surface of the center well 8 protruding into the drainage receiving part 7 and the wall part 7 b of the drainage receiving part 7, an annular flow path in plan view communicating with the outflow trough 3 is formed.

The scraping mechanism 10 shown in FIG. 1 scrapes the solid sediment that has settled at the bottom of the tank body 1 to the center of the bottom surface portion 1b.
The scraping mechanism 10 includes a scraping portion 17, a scraping shaft 13, and a drive motor 14.

The scraping portion 17 is disposed along the bottom surface portion 1 b at the lower end portion inside the tank body 1. With reference to FIG. 5, the detailed structure of the scraping part 17 is demonstrated.
5 is a cross-sectional view taken along the line CC in FIG.
The scraping portion 17 has a support portion 11 and a scraping plate 12.
The support part 11 has a first support member 11A and a second support member 11B.
The first support member 11 </ b> A is a rod-like member that is slightly shorter than the inner diameter of the tank body 1.
The second support member 11B is a rod-like member that is shorter than the first support member 11A.
The first support member 11A and the second support member 11B are joined to each other so as to cross the cross in a plan view.
A scraping shaft 13 to be described later is connected to the intersection between the first support member 11A and the second support member 11B.

A plurality of scraping plates 12 are respectively fixed to the lower side of the first support member 11A and the second support member 11B. The scraping plate 12 scrapes the precipitate on the bottom surface portion 1b as the support portion 11 is rotated.
Each scraping plate 12 below the first support member 11A is inclined in the same direction at a fixed angle with respect to the extending direction of the first support member 11A in plan view.
The scraping plates 12 on the lower side of the second support member 11B are inclined in the same direction at a fixed angle with respect to the extending direction of the second support member 11B in plan view. The inclination direction of each scraping plate 12 with respect to the extending direction of the second support member 11B is the same as the inclination direction of each scraping plate 12 with respect to the extending direction of the first support member 11A.

As shown in FIG. 1, the lower end portion of each scraping plate 12 is extended to a position where a substantially constant gap is formed between the bottom surface portion 1b. Although FIG. 1 illustrates the scraping plate 12 fixed to the first support member 11A, the same applies to the scraping plate 12 fixed to the second support member 11B.
The scraping shaft 13 is disposed at a position that is coaxial with the central axis of the tank body 1. The scraping shaft 13 is supported by a bearing (not shown) so as to be rotatable around the central axis of the tank body 1.
The scraping shaft 13 is inserted through the center portion of the center well 8. The upper end portion of the scraping shaft 13 protrudes upward from the upper end of the tank body 1.

The upper end portion of the scraping shaft 13 is connected to a drive motor 14 fixed to a support member (not shown).
The drive motor 14 rotationally drives the scraping shaft 13. The rotation direction of the drive motor 14 is a direction in which the sediment moves to the center portion of the bottom surface portion 1b as the scraping plate 12 fixed to the support portion 11 rotates. For example, in the example shown in FIG.

Operation | movement of the precipitation tank 50 mentioned above is demonstrated.
First, with reference to FIG. 1, FIG. 2, the whole flow of the to-be-processed water Wf in the sedimentation tank 50 is demonstrated.
As shown in FIG. 1, in the sedimentation tank 50, the to-be-processed water Wf is continuously introduce | transduced from the inflow trough 2 in the state with the to-be-processed water Wf filled in the tank main body 1. As shown in FIG. The treated water Wf introduced from the inflow trough 2 contains a solid content such as floc to be removed by precipitation.
The scraping unit 17 of the scraping mechanism 10 is always driven to rotate by the drive motor 14. However, since the rotation speed is slow, in the explanation of the precipitation phenomenon, the circumferential speed component of the water to be treated Wf in the tank body 1 due to the rotation of the scraping portion 17 can be ignored.

As shown in FIG. 2, the for-treatment water Wf introduced from the opening 2a of the inflow trough 2 flows into the outer peripheral side supply path 6A. When the water to be treated Wf fills the entire circumference of the outer peripheral supply path 6A, the water level in the outer peripheral supply path 6A rises.
When the water level in the outer peripheral side supply path 6A exceeds the bottom surface portion 9a, the water to be treated Wf flows into the radial supply path 6B.
Since the radial supply path 6B communicates with the outer peripheral supply path 6A, the water level in the outer peripheral supply path 6A and the water level in the radial supply path 6B after the water level in the outer peripheral supply path 6A exceeds the bottom surface portion 9a. Is the same.

When the water level of the outer peripheral supply path 6A exceeds the height of the supply weir upper end 5a, the water to be treated Wf gets over the supply weir upper end 5a in the radial direction. The treated water Wf is supplied to the inside of the inflow openings Si1, Si2, Si3, Si4 from a position along the supply weir upper end 5a.
However, in the present embodiment, a notch N (not shown) is formed in the upper part of the circumferential supply weir 5. When the water level of the outer peripheral supply path 6A exceeds the lower portion of the notch N of the circumferential supply weir 5, the water to be treated Wf is also supplied from the notch N.
Similarly, when the water level in the radial supply path 6B exceeds the height of the supply weir upper end 9c, the water to be treated Wf gets over the supply weir upper end 9c in the circumferential direction. The treated water Wf is supplied to the inside of the inflow openings Si1, Si2, Si3, Si4 from a position along the supply weir upper end 9c.
However, in this embodiment, a notch N (not shown) is formed in the upper part of the supply weir 9b. When the water level of the radial supply path 6B exceeds the lower portion of the notch N of the supply weir 9b, the water to be treated Wf is also supplied from the notch N.

In the present embodiment, by design, the supply weir upper end 5a and the supply weir upper end 9c are located on a horizontal plane having the same height. For this reason, if there is no installation error and no component error, the water to be treated Wf is evenly supplied to the inflow openings Si1, Si2, Si3, Si4 beyond the supply weir upper end 5a and the supply weir upper end 9c.
When the supply weir upper end 5a and the supply weir upper end 9c are inclined with respect to the horizontal plane due to an installation error or a component error, there is a possibility that the supply amount varies depending on the place. However, in this embodiment, since the notch N is formed in the circumferential supply weir 5 and the supply weir upper end 9c, the variation in the supply amount depending on the location is reduced.
In this way, the inflow openings Si1, Si2, Si3, and Si4 are supplied with the water Wf to be treated from the supply weir upper end 5a extending in the circumferential direction and the supply weir upper end 9c extending in the radial direction substantially evenly.

As shown in FIG. 1, the for-treatment water Wf supplied to the inflow openings Si1, Si2, Si3, Si4 is gradually outside the center well 8 in a region between the wall 7b and the supply weir upper end 5a. A descending flow is formed.
When the to-be-processed water Wf reaches below the tank body 1, it flows toward the center. The water to be treated Wf that has reached the center forms a flow that rises through the well lower end 8 b of the center well 8.
This is because the well upper end 8a of the center well 8 is located below the supply weir upper end 5a and the supply weir upper end 9c, so that the water to be treated Wf in the center well 8 overflows beyond the well upper end 8a to the outside of the well opening So. It is because it will flow.
The overflowing treated water Wf is stored inside the drainage receiving part 7 and flows to the outflow trough 3 through the flow path between the center well 8 and the wall part 7b. The treated water Wf is discharged to the outside of the settling tank 50 through the outflow trough 3.

The upper part of the center well 8 protruding from the bottom surface part 7a is disposed inside the center well 8, and is an overflow part that overflows the water to be treated Wf from the well upper end 8a.
The drainage receiving part 7 and the outflow trough 3 are discharge parts that collect the treated water Wf overflowing from the overflow part and discharge it to the outside of the tank body 1.

The volume of the solid content contained in the water to be treated Wf can be ignored as a minute amount. In the sedimentation tank 50, the flow rate flowing into the inflow openings Si1, Si2, Si3, Si4 and the flow rate flowing out from the well opening So are the same.
Vd = (Ao / Ai) · Vu, where Vd is the average flow velocity of the downflow near the inflow openings Si1, Si2, Si3, Si4 and Vu is the average flow velocity of the upflow near the outlet opening So. Here, Ao is the opening area of the spring opening So, and Ai is the sum of the opening areas of the inflow openings Si1, Si2, Si3, and Si4.
In this embodiment, since Ai> Ao, Vd <Vu.

In the tank body 1, a substantially uniform downward flow is formed as a whole in the flow path between the outside of the center well 8 and the wall portion 1 a. Since the outer peripheral surface of the center well 8 is inside the wall portion 7b of the drainage receiving portion 7, the horizontal channel cross-sectional area is slightly larger than the sum of the opening areas of the inflow openings Si. Therefore, the average flow velocity of the downward flow of the flow path between the outer peripheral surface of the center well 8 and the wall portion 1a is Vd ′, which is smaller than Vd.
In the flow path inside the center well 8, a substantially uniform upward flow is formed as a whole. In the present embodiment, since the center well 8 is a cylindrical member having a constant pipe cross-sectional area, the average flow velocity of the upward flow is also Vu.
In the tank body 1, in the region below the well lower end 8 b of the center well 8, the flow toward the center portion from the outer peripheral side on the scraping portion 17 and the bottom surface portion 1 b and the inside of the center well 8 in the vicinity of the well lower end 8 b Flow is generated. The flow velocity of the water to be treated Wf is gradually accelerated from the outer peripheral side toward the center.
In the vicinity of the well lower end 8b, the flow rate of the flow of the water Wf to be treated that is drawn around the well lower end 8b increases. For this reason, the flow velocity of the upward flow rising right above the center of the bottom surface portion 1b is lower than the flow flowing around the well lower end 8b. As a result, the deposit on the bottom surface portion 1b is hardly sucked up.

Next, the precipitation phenomenon in the tank body 1 will be described.
FIGS. 6A and 6B are schematic diagrams for explaining the sedimentation speed of flocs. FIG. 6A shows the sedimentation speed of the floc during the downward flow. FIG. 6B shows the sedimentation speed of the floc in the upward flow.

The solid content dispersed in the water to be treated Wf is, for example, granular or lump like the floc f schematically shown in FIGS. 6 (a) and 6 (b). It has a downward speed corresponding to the speed Vf.
For this reason, the floc f sinks at a speed of V = Vf + Vd during the downward flow of the flow velocity Vd. On the other hand, the floc f sinks at a speed of V = Vf−Vu in the upward flow at the flow velocity Vu.
Accordingly, the floc f settles in the bottom portion 1b earlier because the frock f settles in a shorter time than in the upward flow.
Here, in order to realize precipitation in an upward flow, it is necessary that Vf> Vu.
In this embodiment, the speed of the downward flow is low enough to prevent the precipitate from being rolled up even when the downward flow hits the deposit layer.

In the sedimentation tank 50, the floc f in the water to be treated Wf settles downward along with the downward flow in the flow path between the center well 8 and the wall 1a. When adjacent flocks f come into contact with each other during settling, the flocks f unite and grow into a lump. The floc f that has reached the bottom surface portion 1b is deposited and deposited on the bottom surface portion 1b or the sediment layer on the bottom surface portion 1b.
The floc f settles in a substantially uniform downward flow along the downward flow, and thus settles quickly and stably.
Since the flow path of the downward flow has a larger cross-sectional area than the flow path of the upward flow in the center well 8, much of the water to be treated Wf is contained in the water to be treated Wf before entering the center well 8. The floc f will settle out.
Since the average flow velocities Vd and Vd ′ of the water to be treated Wf in this region are low, the coalescence of the flocks f easily proceeds. In addition, even if the to-be-processed water Wf reaches the bottom surface portion 1b, the precipitate is difficult to roll up.
As described above, the flow sucked up by the center well 8 becomes high speed in the vicinity of the well lower end 8b, so that the sediment precipitated just below the well lower end 8b is hardly sucked up.

Thus, the to-be-treated water Wf that rises in the center well 8 has a solid content in the to-be-treated water Wf precipitated and removed before entering the center well 8. However, some precipitation proceeds even in the process of ascending the center well 8.
The treated water Wf overflowing from the well upper end 8a is clarified water Wc.

In the conventional sedimentation tank, water to be treated is supplied to a feed well disposed at the center of the tank body, and the flow path between the feed well and the inner peripheral surface of the tank body is raised to overflow the upper part of the tank body. I was allowed to flow. For this reason, the flow in the tank is opposite to the settling tank 50 of the present embodiment.
For this reason, the downward flow descending the feed well becomes an ejection flow toward the bottom of the tank body, and the reliable landing of the solid matter that settles is hindered. Furthermore, the sediment that has already been deposited is rolled up to reduce the effect of the sedimentation in the downflow.
In prior art settling tanks, the main precipitation takes place in the upward flow channel outside the feed well. For this reason, the efficiency of precipitation will deteriorate unless the flow rate of the upward flow is sufficiently low. As a result, the time required for precipitation becomes longer.
Furthermore, it is difficult to stabilize the low-speed upflow compared to the downflow. For this reason, the precipitation performance and the precipitation efficiency are also inferior in that a partial circulation flow tends to occur in the flow path outside the feed well.

According to the sedimentation tank 50 of this embodiment, since the flow in the tank main body 1 is reversed, the problems of these conventional sedimentation tanks are solved.
Furthermore, since the center well 8 is disposed at the center of the tank body 1 in the sedimentation tank 50, the sum of the opening areas of the inflow openings Si can be made larger than the opening area of the outlet opening So. As a result, it is easy to reduce the average flow velocities Vd and Vd ′ in the downward flow path.

  As described above, according to the sedimentation tank 50 of the present embodiment, it is possible to provide a sedimentation tank capable of efficiently precipitating solids such as floc in the water to be treated.

(Second Embodiment)
FIG. 7 is a schematic longitudinal sectional view showing a configuration example of the sedimentation tank according to the second embodiment. 8 is a cross-sectional view taken along the line DD in FIG. FIG. 9 is a schematic enlarged view of E view in FIG.

As shown in FIG. 7, the sedimentation tank 51 of this embodiment has an inclined plate 20 added to the sedimentation tank 50 of the first embodiment.
Hereinafter, a description will be given centering on differences from the first embodiment.

As shown in FIGS. 7 and 8, the inclined plate 20 is a flat plate protruding radially from the inner peripheral surface of the wall portion 1 a toward the center well 8. A plurality of the inclined plates 20 are arranged apart from each other along the circumferential direction of the wall portion 1a. The inner peripheral end 20 c of each inclined plate 20 is separated from the outer peripheral surface of the center well 8 by a certain distance.
As shown in FIG. 9, each inclined plate 20 obliquely intersects the vertical axis Ov when viewed in the radial direction from the center well 8 toward the wall portion 1 a. The inclination angle of each inclined plate 20 with respect to the vertical axis Ov is θ (where θ is an acute angle). The inclination directions of the inclined plates 20 are the same.
The length of each inclined plate 20 along the inclination direction is L.
The horizontal interval between the inclined plates 20 can be set to an appropriate interval. In the example shown in FIG. 9, the horizontal interval X is determined so that the inclined plates 20 overlap in the vertical direction when viewed from the direction along the vertical axis Ov. That is, X <Lsin θ. However, they may be separated to such an extent that the inclined plates 20 do not overlap when viewed from the direction along the vertical axis Ov. That is, it is good also as X> = Lsin (theta).

The operation of the sedimentation tank 51 of the present embodiment will be described focusing on differences from the operation of the first embodiment.
FIG. 10 is a schematic diagram for explaining the operation of the inclined plate of the sedimentation tank according to the second embodiment. FIG. 11 is an operation explanatory view of the inclined plate of the sedimentation tank according to the second embodiment.

As shown in FIG. 9, each inclined plate 20 is arrange | positioned in the area | region where the downward flow of the to-be-processed water Wf of the average flow velocity Vd approachs.
The treated water Wf entering between the upper ends 20 a of the inclined plates 20 adjacent to each other in the circumferential direction flows at a flow velocity U along the inclined direction of the inclined plates 20 between the inclined plates 20. For this reason, the floc f that descends in the vertical direction from the upper side of the inclined plate 20 is inclined between the inclined plates 20 by a shallower angle θf (where θf <θ) with respect to the vertical axis Ov. Settling at a speed Uf.

In the example shown in FIG. 9, the flock f that descends near the upper end 20 a of one inclined plate 20 lands near the lower end 20 b of the adjacent inclined plate 20, like a flock f ′.
In this case, as shown in FIG. 10, the flocks f that descend between the upper ends 20 a of the adjacent inclined plates 20 land on any surface of the inclined plate 20 like the flock f ″.
The floc f ″ that has landed on the inclined plate 20 moves downward while rolling on the inclined plate 20.

FIG. 11 schematically shows the deposits between the inclined plates 20 during the operation of the sedimentation tank 51.
A large number of flocks f are already attached to the surface of each inclined plate 20. On the upper side of this flock layer, the water to be treated Wf flows downward along the inclination direction of the inclined plate 20. For this reason, the floc f in the floc layer is swept down and moves on the surface of the inclined plate 20. During this movement, the floc f grows into a larger lump by repeating contact with other flocs on the inclined plate 20. For this reason, the flock fd at the lower end 20b is larger than the flock fu near the upper end 20a.
The grown flock fd is less susceptible to the flow of the water to be treated Wf, and thus quickly settles on the bottom surface portion 1b below the inclined plate 20.

In the sedimentation tank 51, since the inclined plate 20 is disposed in the flow path of the downward flow between the center well 8 and the wall portion 1a, the flock f of the water to be treated Wf descending between the inclined plates 20 is the inclined plate. 20 makes it easier to land on. For this reason, sedimentation of floc f from the water to be treated Wf is promoted.
The sedimentation tank 51 of the present embodiment can precipitate solids such as flocks in the water to be treated even more quickly and efficiently than the sedimentation tank 50 of the first embodiment.

(First modification)
FIG. 12 is a schematic diagram illustrating a first modified example of an inclined plate that can be used in the settling tank of the second embodiment. FIG. 12, like FIG. 9, is a schematic enlarged view seen in the radial direction from the center well 8 (not shown) toward the wall 1a.

  A first inclined plate 21 and a second inclined plate 22 shown in FIG. 12 are a first modification of the inclined plate 20 in the second embodiment. The first inclined plate 21 and the second inclined plate 22 of this modification can be used in place of the inclined plate 20 in the second embodiment settling tank 51.

Like the inclined plate 20, the first inclined plate 21 and the second inclined plate 22 are flat plates protruding in the radial direction from the inner peripheral surface of the wall portion 1 a toward the center well 8. A plurality of the first inclined plates 21 and the second inclined plates 22 are arranged apart from each other along the circumferential direction of the wall portion 1a.
The first group composed of the plurality of first inclined plates 21 is arranged above the second group composed of the plurality of second inclined plates 22.

Each first inclined plate 21 is inclined by an angle θ1 (where θ1 is an acute angle) with respect to the vertical axis Ov when viewed in the radial direction from the center well 8 toward the wall portion 1a.
The direction of the inclination of each first inclined plate 21 is the same direction. In the present modification, each first inclined plate 21 is inclined in a first direction (downward direction in the drawing) from the right to the left in the drawing as it goes from the upper side to the lower side.
The length of each first inclined plate 21 along the inclination direction is L1.
The horizontal interval X1 of each first inclined plate 21 can be set to an appropriate interval. In the example illustrated in FIG. 12, the interval X <b> 1 is an interval at which each first inclined plate 21 does not overlap when viewed from the direction along the vertical axis. However, the interval X1 may be an interval at which the first inclined plates 21 overlap when viewed from the direction along the vertical axis.

Each second inclined plate 22 is inclined by an angle θ2 (where θ2 is an acute angle) with respect to the vertical axis Ov when viewed in the radial direction from the center well 8 toward the wall portion 1a.
The direction of the inclination of each second inclined plate 22 is the same direction. In the present modification, each second inclined plate 22 is inclined in a second direction (downward direction in the drawing) from the left to the right in the drawing as it goes from the upper side to the lower side. For this reason, the inclination direction of the second inclined plate 22 is a direction intersecting the inclination direction of the first inclined plate 21. The direction of inclination of each second inclined plate 22 is opposite to the direction of circumferential direction in which each first inclined plate 21 is lowered with respect to the direction of the circumferential direction.
The length of each second inclined plate 22 along the inclination direction is L2.
The horizontal interval between the second inclined plates 22 is X1 which is the same as the horizontal interval between the first inclined plates 21.
Each second inclined plate 22 protrudes above the extended surface S21 of the upper surface of the first inclined plate 21 directly above the second inclined plate 22.

  As the length L1 and the inclination angle θ1 of the first inclined plate 21, and the length L2 and the inclination angle θ2 of the second inclined plate 22, appropriate values that can obtain the required sedimentation performance can be used.

The operation of the first inclined plate 21 and the second inclined plate 22 of the present modification will be described with a focus on differences from the operation of the second embodiment.
Each of the first inclined plate 21 and the second inclined plate 22 has an action of promoting the precipitation of the floc f contained in the water to be treated Wf, just like the inclined plate 20 in the second embodiment.
Further, in the present modification, the direction in which the water to be treated Wf flows is switched while the water to be treated Wf descends through the first inclined plate 21 and the second inclined plate 22. That is, between each 1st inclination board 21, the to-be-processed water Wf inclines in the 1st direction, and falls. When the water to be treated Wf enters between the second inclined plates 22 from between the first inclined plates 21, the treated water Wf is inclined in a second direction that is a direction intersecting the first direction. And descend.
For this reason, the floc f that descends obliquely from the lower end 21 b of the first inclined plate 21 hits the upper end portion of the second inclined plate 22 or another floc located at the upper end portion, and then the second inclined plate 22. Along the diagonal direction opposite to the first inclined plate 21 and descend. That is, the circumferential component in the moving direction of the flock f is reversed.
As described above, in the present modification, the flow of the water to be treated Wf greatly changes when the water to be treated Wf and the flock f transfer from the first inclined plate 21 to the second inclined plate 22. In addition, since the chance of contact with other flocs on the second inclined plate 22 also increases, the agglomeration of the floc f is promoted. For this reason, sedimentation of floc f from the water to be treated Wf is promoted.
The sedimentation tank 51 to which this modification is applied can precipitate solids such as flocks in the water to be treated more rapidly and efficiently than the sedimentation tank 51 of the second embodiment.

(Second modification)
FIG. 13 is a schematic diagram showing a second modification of the inclined plate that can be used in the sedimentation tank of the second embodiment. FIG. 13 is a schematic enlarged view as seen in the radial direction from the center well 8 toward the wall 1a, as in FIG.

As shown in FIG. 13, in this modification, a first inclined plate 23 is used instead of the first inclined plate 21 of the first modified example. The first inclined plate 23 and the second inclined plate 22 of this modification can be used in place of the inclined plate 20 in the second embodiment settling tank 51.
Hereinafter, a description will be given focusing on differences from the first modification.

The first inclined plate 23 is different from the first inclined plate 21 of the first modified example in that the bent portion 23c is provided at the lower end and the arrangement position with respect to the second inclined plate 22.
The bent portion 23c is bent vertically downward. For this reason, the bending part 23c and the vertical axis Ov are parallel.
In the present modification, the first group composed of the plurality of first inclined plates 23 is disposed above the second group composed of the plurality of second inclined plates 22.
In the example shown in FIG. 13, the extended surface S <b> 23 on the upper surface of each first inclined plate 23 is positioned above the upper end 22 a of the second inclined plate 22 immediately below the first inclined plate 23. Further, the bent portion 23c of each first inclined plate 23 faces the second inclined plate 22 directly below.

The operation of the first inclined plate 23 and the second inclined plate 22 of the present modification will be described focusing on differences from the operation of the first modification.
In the present modification, the direction in which the water to be treated Wf flows is switched while the water to be treated Wf descends through the first inclined plate 23 and the second inclined plate 22 as in the first modified example. It is done.
In this modification, the flock f moved to the lower end of the first inclined plate 23 descends downward along the bent portion 23c. The flock f lands on the second inclined plate 22 facing the bent portion 23 c and rolls down along the inclination of the second inclined plate 22.
For this reason, the transfer from the first inclined plate 23 to the second inclined plate 22 is performed smoothly.
Further, since the bent portion 23c has a function of a guide plate that changes the flow direction of the water to be treated Wf flowing on the back surface side, the flow direction of the water to be treated Wf is smoothly switched. In addition, since the second inclined plate 22 does not need to protrude beyond the extended surface S23 by providing the bent portion 23c, the water Wf to be treated on the upper surface of the first inclined plate 23 is prevented from being disturbed. The
Thus, in this modification, since the moving direction of the floc f and the direction of the flow of the water to be treated Wf are switched smoothly, the floc f is less likely to be scattered when the direction is changed.
The sedimentation tank 51 to which this modification is applied can precipitate solids such as floc in the water to be treated more rapidly and efficiently than the first modification.

  In the example described above, the upper end 22a of the second inclined plate 22 immediately below the extended surface S23 of the first inclined plate 21 is on the lower side. However, even if the position of the upper end 22a of the second inclined plate 22 is the same as the position of the extension surface S23 directly above, the disturbance of the flow of the water to be treated Wf is prevented. If the disturbance of the flow of the water to be treated Wf is within an allowable range, the upper end 22a of the second inclined plate 22 may protrude above the extended surface S23 directly above.

(Third embodiment)
FIG. 14 is a schematic longitudinal sectional view showing a configuration example of the sedimentation tank of the third embodiment.
As shown in FIG. 14, the sedimentation tank 52 of this embodiment has a center well 28 (tubular body) instead of the center well 8 of the sedimentation tank 51 of the second embodiment.
Hereinafter, a description will be given focusing on differences from the second embodiment.

The center well 28 has a first cylindrical portion 28A (overflow portion) and a second cylindrical portion 28B.
The first cylindrical portion 28 </ b> A constitutes the upper portion of the center well 28. The upper end of the first cylindrical portion 28A is a well upper end 8a similar to the center well 8 in the second embodiment. For this reason, the planar view shape of the first cylindrical portion 28A is the same as that of the center well 8 in the second embodiment. The first cylindrical portion 28 </ b> A penetrates the bottom surface portion 7 a of the drainage receiving portion 7, similarly to the upper portion of the center well 8. The height relationship between the well upper end 8a and the supply weir upper end 5a is the same as that in the second embodiment.
The center well 28 is a member obtained by replacing the lower portion of the center well 8 of the second embodiment with a second cylindrical portion 28B.

The second tubular portion 28B is a tubular portion (a diameter-enlarged portion) in which the pipe cross-sectional area gradually increases from the lower end portion of the first tubular portion 28A toward the well lower end 28b (lower end). FIG. 14 shows an example of a conical shape whose diameter is increased at a constant rate of change as the second cylindrical portion 28B. However, the rate of change in the diameter expansion of the second cylindrical portion 28B may not be constant. For example, various diameter-expanded shapes such as a paraboloid, a shell shape, and a bell shape are possible. A portion having a constant opening diameter may be formed in the vicinity of the well lower end 28b.
The outer diameter at the well lower end 28b of the second cylindrical portion 28B is an outer diameter at which the outer peripheral surface of the second cylindrical portion 28B comes into contact with the inner peripheral end portion 20c of each inclined plate 20.

The operation of the sedimentation tank 52 of this embodiment will be described focusing on differences from the operation of the second embodiment.
The sedimentation tank 52 is different only in that the lower portion of the center well 8 of the second embodiment is replaced with the second cylindrical portion 28B. Thereby, the flow of the to-be-processed water Wf in the vicinity of the 2nd cylindrical part 28B differs from the said 2nd Embodiment.
The inner diameter of the second cylindrical portion 28B is maximum at the well lower end 28b. The inner diameter of the second cylindrical portion 28B is reduced to the inner diameter of the first cylindrical portion 28A as it goes upward. For this reason, the upward flow of the to-be-processed water Wf passing through the second cylindrical portion 28B is slower at the well lower end 28b than the flow velocity at the well lower end 8b of the center well 8 of the second embodiment. The upward flow is gradually accelerated up to the connecting portion between the second cylindrical portion 28B and the first cylindrical portion 28A.
As a result, the flow of the water to be treated Wf below the well lower end 28b becomes low speed, and further, the winding of the sediment in the bottom surface portion 1b is suppressed as compared with the sedimentation tank 51 of the second embodiment.
Since the upward flow is gradually accelerated between the second cylindrical portions 28 </ b> B, the turbulence of the flow in the center well 28 is reduced, and the precipitation proceeds smoothly in the center well 28.

Further, in the present embodiment, the second cylindrical portion 28B is in contact with the inner peripheral end portion 20c of each inclined plate 20. That is, the gap between the outer peripheral surface of the center well 28 and the inner peripheral end 20c on the upper side of the center well 28 is closed on the lower side.
As a result, since the flow of the water to be treated Wf in the gap between the outer peripheral surface of the center well 28 and the inner peripheral end 20c is suppressed, all downward flows from the inflow openings Si pass between the inclined plates 20. , Sinks below each inclined plate 20. Thereby, since the rate of descending through each inclined plate 20 in the descending flow of the water to be treated Wf increases, precipitation proceeds more efficiently.
The sedimentation tank 52 of the present embodiment can precipitate solids such as flocks in the water to be treated more rapidly and efficiently than the sedimentation tank 51 of the second embodiment.

(Fourth embodiment)
FIG. 15 is a schematic longitudinal sectional view showing a configuration example of the sedimentation tank of the fourth embodiment.
As shown in FIG. 15, the sedimentation tank 53 of this embodiment has a center well 38 (tubular body) instead of the center well 8 of the sedimentation tank 51 of the second embodiment.
Hereinafter, a description will be given focusing on differences from the second embodiment.

The center well 38 has a first tubular portion 38A (overflow portion) and a second tubular portion 38B.
The first tubular portion 38A constitutes the upper portion of the center well 38.
The first cylindrical portion 38A has the same shape as the cylindrical portion protruding from the wall portion 7b in the center well 8 in the second embodiment.
The second cylindrical portion 38B is a cylindrical portion having the same outer diameter as the inner diameter of the inner peripheral end 20c of each inclined plate 20. The vertical position of the well lower end 38b, which is the lower end of the second cylindrical portion 38B, is the same as the vertical position of the well lower end 8b of the center well 8 of the second embodiment.
A flat step portion 38c extending in the horizontal direction is provided at the connection portion between the first cylindrical portion 38A and the second cylindrical portion 38B.

The first cylindrical portion 38A of the center well 38 is located inside the wall portion 7b of the drainage receiving portion 7 in the second embodiment. In the example shown in FIG. 15, since the outer diameter of the wall 7b of the drainage receiving part 7 and the outer diameter of the second cylindrical part 38B are the same diameter, the bottom surface of the drainage receiving part 7 in the second embodiment. The part 7a is replaced with a step part 38c.
However, the configuration shown in FIG. 15 is an example. For example, if the wall 7b surrounds the first tubular portion 38A, the outer diameter of the wall 7b may be smaller than the outer diameter of the second tubular portion 38B. In this case, the wall portion 7b is erected on the stepped portion 38c.
For example, the outer diameter of the wall 7b may be larger than the outer diameter of the second cylindrical portion 38B. In this case, the stepped portion 38c has a shape fitted into the central portion of the bottom surface portion 7a having a larger diameter than the stepped portion 38c.

  The center well 38 is a member obtained by replacing the lower side of the drain receiving part 7 of the center well 8 of the second embodiment with the second cylindrical part 38B.

The operation of the sedimentation tank 53 of this embodiment will be described focusing on differences from the operation of the second embodiment.
The sedimentation tank 53 is different only in that the lower side of the drain receiving part 7 of the center well 8 of the second embodiment is replaced with the second cylindrical part 38B. Thereby, the flow of the to-be-processed water Wf in the vicinity of the 2nd cylindrical part 38B differs from the said 2nd Embodiment.
The outer peripheral surface of the second cylindrical portion 38B is in contact with the entire inner peripheral end 20c of each inclined plate 20. That is, no gap is formed between the outer peripheral surface of the center well 38 and each inner peripheral end 20c.
As a result, all the downward flows from the inflow openings Si pass between the inclined plates 20 and settle below the inclined plates 20. For this reason, precipitation is more efficiently promoted by the inclined plates 20 with respect to the downward flow of the water to be treated Wf.

The opening diameter at the well lower end 38b is larger than the opening diameter at the well lower end 8b of the center well 8 of the second embodiment. For this reason, the upward flow in the vicinity of the well lower end 38b is slower than in the second embodiment. The flow rate of the upward flow is constant in the second cylindrical portion 38B.
A part of the upward flow collides with the stepped portion 38c and is sucked into the first cylindrical portion 38A having a smaller diameter. At this time, since the pipe cross-sectional area changes according to the opening diameter of the first cylindrical portion 38A, the upward flow is accelerated.

In the sedimentation tank 53, since the flow velocity in the second cylindrical portion 38B is lower than that in the center well 8 of the second embodiment, the second cylindrical portion 38B has a flow velocity higher than that of the second embodiment. Precipitation is promoted.
Further, in the center well 38, the upward flow hits the stepped portion 38c, so that the solid content precipitation is also promoted in terms of promoting the adhesion and growth of the solid content.

  The sedimentation tank 53 of the present embodiment can precipitate solids such as floc in the water to be treated more rapidly and efficiently than the sedimentation tank 51 of the second embodiment.

(Fifth embodiment)
FIG. 16 is a schematic longitudinal sectional view showing a configuration example of the sedimentation tank of the fifth embodiment.
As shown in FIG. 16, the sedimentation tank 54 of this embodiment is replaced with a center well 48 (tubular body) and a drainage receiving part instead of the center well 38 and the drainage receiving part 7 of the sedimentation tank 53 of the fourth embodiment. 47 (discharge section).
Hereinafter, a description will be given focusing on differences from the fourth embodiment.

The center well 48 is a cylindrical member having an outer diameter that is the same as the outer diameter of the second cylindrical portion 38B in the fourth embodiment. The tube length of the center well 48 is equal to the length from the upper end of the drain receiving part 7 to the well lower end 38b of the center well 38 in the fourth embodiment.
The well upper end 48a of the center well 48 is disposed at the same position in the vertical direction as the upper end of the drainage receiving portion 7 in the fourth embodiment.

The drainage receiving part 47 is a bottomed container that opens upward. The drainage receiving portion 47 has an outer shape that can be accommodated inside the center well 48. In this embodiment, the drainage receiving part 47 has a cylindrical overflow weir part 47c (overflow part) and a bottom part 47b that closes the overflow weir part 47c downward. The overflow weir portion 47c can have various cylindrical shapes such as a cylindrical shape and a polygonal shape. In the present embodiment, the overflow weir portion 47c is cylindrical as an example.
The overflow weir upper end 47a (upper end) of the overflow weir portion 47c is arranged at the same position as the well upper end 8a of the center well 8 in the second embodiment in the vertical direction.
In this embodiment, the outflow trough 3 penetrates the overflow weir portion 47 c of the drainage receiving portion 47. The outflow trough 3 opens into the drainage receiving portion 47. The outflow trough 3 also penetrates the center well 48.

  In the present embodiment, in the gap between the overflow weir portion 47 c and the center well 48 of the drainage receiving portion 47, a spring opening So having an annular shape in plan view is formed. The opening area of the spring opening So is smaller than the sum of the opening areas of the inflow openings Si1, Si2, Si3, and Si4.

The operation of the sedimentation tank 54 of the present embodiment will be described focusing on differences from the operation of the fourth embodiment.
In the sedimentation tank 54, only the flow of the water to be treated Wf in the upper part of the center well 48 is different from the flow of the fourth embodiment.
In the center well 48 of the settling tank 54, a low-speed upward flow similar to that in the fourth embodiment is generated below the drainage receiving portion 47.
This upward flow rises in the gap between the overflow weir portion 47 c and the inner peripheral surface of the center well 48. The as-treated water Wf that has risen springs out from the spring opening So. The treated water Wf overflows the overflow weir upper end 47 a of the overflow weir 47 c and flows out into the drain receiving part 47. The treated water Wf inside the drain receiving part 47 is discharged to the outside of the settling tank 54 through the outflow trough 3.

The ascending flow in the lower portion of the center well 48 is low in average flow velocity, but has flow path resistance, so the flow velocity in the center is faster than the flow velocity along the inner peripheral surface of the center well 48.
However, in the sedimentation tank 54, since the bottom surface portion 47b of the drainage receiving portion 47 is disposed at the center of the center well 48, an upward flow having a relatively high flow velocity hits the bottom surface portion 47b.
For this reason, compared with the said 4th Embodiment, precipitation removal of solid content is accelerated | stimulated more.

  The sedimentation tank 54 of the present embodiment can precipitate solids such as floc in the water to be treated even more quickly and efficiently than the sedimentation tank 53 of the fourth embodiment.

(Sixth embodiment)
FIG. 17 is a schematic longitudinal sectional view showing a configuration example of the sedimentation tank of the sixth embodiment.
As shown in FIG. 17, the sedimentation tank 55 of this embodiment has a center well 58 (tubular body) instead of the center well 28 of the sedimentation tank 52 of the third embodiment.
Hereinafter, a description will be given focusing on differences from the third embodiment.

  The center well 58 has a second cylindrical portion 58B and a third cylindrical portion 58C instead of the second cylindrical portion 28B of the center well 28 in the third embodiment.

The second cylindrical portion 58B has an inner diameter that is larger than the inner diameter of the first cylindrical portion 28A of the third embodiment and smaller than the inner diameter of the well lower end 28b. The second tubular portion 58B is connected to the lower end portion of the first tubular portion 28A.
A flat plate-shaped step portion 58c extending in the horizontal direction is provided at a connection portion between the first cylindrical portion 28A and the second cylindrical portion 58B.
The third cylindrical portion 58 </ b> C is a cylindrical portion having the same outer diameter as the inner diameter of the inner peripheral end 20 c of each inclined plate 20. The third cylindrical portion 58C is connected to the lower end portion of the second cylindrical portion 58B. The vertical position of the well lower end 58b, which is the lower end of the third cylindrical portion 58C, is the same as the vertical position of the well lower end 28b of the center well 28 of the third embodiment.
A flat step portion 58d extending in the horizontal direction is provided at a connection portion between the second cylindrical portion 58B and the third cylindrical portion 58C.

The operation of the sedimentation tank 55 of the present embodiment will be described focusing on the differences from the operation of the third embodiment.
In the center well 58 of the sedimentation tank 55, since the second cylindrical portion 58B and the third cylindrical portion 58C are connected to the lower side of the first cylindrical portion 28A, the inner diameter of the lower tubular body Is expanded in two steps from the inner diameter of the first cylindrical portion 28A. As a result, a diameter-expanded portion is formed that gradually increases in diameter as the pipe cross-sectional area of the center well 58 is directed downward from above.
As a result, the flow of the to-be-processed water Wf below the well lower end 58b becomes low speed, and like the sedimentation tank 52 of the third embodiment, the winding of the sediment in the bottom surface portion 1b is suppressed.

The third cylindrical portion 58C is in contact with the inner peripheral end portion 20c of each inclined plate 20, similarly to the second cylindrical portion 28B in the third embodiment. That is, the gap between the outer peripheral surface of the center well 58 and the inner peripheral end 20c on the upper side of the center well 58 is closed on the lower side.
As a result, as in the third embodiment, the rate of descending through each inclined plate 20 in the descending flow of the water to be treated Wf increases, so that precipitation proceeds efficiently.
Furthermore, in the sedimentation tank 55, the upward flow on the lower end side in the center well 58 is more easily settled by colliding with the step portions 58d and 58c.

  The sedimentation tank 55 of the present embodiment can precipitate solids such as floc in the water to be treated more rapidly and efficiently than the sedimentation tank 52 of the third embodiment.

(Seventh embodiment)
FIG. 18 is a schematic longitudinal sectional view showing a configuration example of the sedimentation tank of the seventh embodiment.
As shown in FIG. 18, in the sedimentation tank 56 of the present embodiment, an inclined plate 24 is added to the center well 8 of the sedimentation tank 51 of the second embodiment.
Hereinafter, a description will be given focusing on differences from the second embodiment.

The inclined plate 24 is a flat plate projecting radially from the inner peripheral surface of the center well 8 toward the center of the center well 8. Similar to the inclined plate 20, a plurality of inclined plates 24 are arranged apart from each other along the circumferential direction of the inner peripheral surface of the center well 8. The inner peripheral end 24 c of each inclined plate 24 is separated from the scraping shaft 13 inserted through the center well 8 by a certain distance.
Although illustration of the inclined posture of each inclined plate 24 is omitted, the inclined posture similar to that of each inclined plate 20 is possible. The specific inclination angle, the horizontal arrangement interval, the length in the inclination direction, and the like may be set to appropriate values that improve the sediment removal characteristics in the upward flow in the center well 8.

The operation of the sedimentation tank 56 of the present embodiment will be described focusing on differences from the operation of the second embodiment.
In the sedimentation tank 56, the inclined plate 24 is added in the center well 8 where the ascending flow of the water to be treated Wf is generated.
Between the inclined plates 24 adjacent to each other in the circumferential direction, the flow of the treated water Wf differs from the flow in the inclined plate 20 in that the treated water Wf is inclined in the upward direction from below along the inclination of the inclined plate 24.
Solid content such as floc in the water to be treated Wf moves downward obliquely along the inclined plate 24, but sinks downward due to its own weight. For this reason, a part of solid content lands on the inclined plate 24. The landed solid content descends while rolling along the inclination of the inclined plate 24 and settles on the bottom surface portion 1b.

  In the settling tank 56, in addition to the settling effect by the inclined plate 20, the settling effect by the inclined plate 24 can be obtained. Therefore, the settling tank 56 can be more rapidly and efficiently contained in the treated water than the settling tank 51 of the second embodiment. Solids such as floc can be precipitated.

Hereinafter, modifications of the above-described embodiment will be described.
In the description of each of the above-described embodiments, an example in which the supply path 6 has a radial supply path 6B has been described. However, the supply path 6 may be only the outer peripheral supply path 6A.

  In the description of each of the above embodiments, an example in which the notch N is provided at the upper ends of the circumferential supply weir 5 and the supply weir 9b of the supply path 6 has been described. However, if the circumferential supply weir 5 and the supply weir 9b are arranged substantially horizontally, the deviation of the supply amount of the water Wf to be treated from the circumferential supply weir 5 and the supply weir 9b is within the allowable range. The notch portion N may be omitted.

  In the above description of each embodiment, an example in which the opening of the tubular body such as the center well 8 and the cross-sectional shape of the inner peripheral surface are circular has been described. However, the cross-sectional shape of the opening of the tubular body and the inner peripheral surface is not limited to a circle. For example, the cross-sectional shape of the opening and inner peripheral surface of the tubular body may be a polygonal shape, an elliptical shape, or the like.

In the description of the first modification and the second modification of the second embodiment, an example in which the inclined plate is composed of a total of two groups of the first group and the second group has been described.
However, three or more groups of inclined plates having different inclination directions may be used. That is, the group of the plurality of inclined plates may be three or more as the group in which the inclination direction sequentially changes from the upper side to the lower side.

  In the description of the second modification of the second embodiment, an example in which the bent portion 23c is bent in parallel to the vertical axis Ov has been described. However, the bent portion 23c does not have to be strictly parallel to the vertical axis Ov. The bent portion 23c may be bent in an oblique direction with respect to the vertical axis Ov at an angle smaller than the angle θ1.

  In the description of the second to seventh embodiments, an example in which the inclined plate 20 protrudes radially inward from the inner peripheral surface of the wall portion 1a of the tank body 1 has been described. However, the inclined plate 20 may be disposed between the wall portion 1a and the outer peripheral surface of the tube so as to be separated from the inner peripheral surface of the wall portion 1a. That is, there may be a gap between the outer peripheral end of the inclined plate 20 and the wall 1a.

In the description of the third to seventh embodiments, an example in which the outer peripheral surface of the tubular body is in contact with each inner peripheral end 20c of the inclined plate 20 has been described. In this case, the flow of the for-treatment water Wf between the outer peripheral surface of the tubular body and each inner peripheral end 20c of the inclined plate 20 is suppressed in the contact portion.
However, in the third to seventh embodiments, a part or all of the outer peripheral surface of the tube and the inner peripheral end 20c of the inclined plate 20 may not be in contact with each other. In this case, if the gap between the outer peripheral surface of the tubular body and each inner peripheral end 20c of the inclined plate 20 is small to some extent, the flow of the treated water Wf is suppressed according to the degree of the gap.

In the description of the seventh embodiment, an example in which the inclined plate 24 is provided in the center well 8 of the precipitation tank 51 of the second embodiment has been described. However, the inclined plate 24 may be provided inside any tubular body of the first to sixth embodiments.
Furthermore, the inclined plate arranged inside the tubular body where the upward flow is generated may be an inclined plate having a different inclination direction similar to that in the first modified example or the second modified example of the second embodiment.

In the description of the seventh embodiment, an example in which the inclined plate 24 protrudes inward from the inner peripheral surface of the center well 8 has been described. However, the inclined plate 24 may be disposed at any position within the center well 8.
For example, the outer peripheral end of the inclined plate 24 may be arranged away from the inner peripheral surface of the center well 8. In this case, the inner peripheral end 24 c of the inclined plate 24 may be fixed to the scraping shaft 13.

  According to at least one embodiment described above, the pipe disposed inside the tank body, the supply unit that supplies the water to be treated from the outside of the pipe body inside the tank body, and the inside of the pipe body By having the overflow portion disposed in the solid water, it is possible to efficiently precipitate solids such as floc in the water to be treated.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example 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 spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Tank main body (tank body), 1a ... Wall part, 2 ... Inflow trough, 3 ... Outflow trough (discharge part), 5 ... Circumferential supply weir, 5a ... Supply weir upper end, 6 ... Supply path (supply part), 6A ... outer periphery side supply path, 6B ... radial supply path, 7 ... drainage receiving part (discharge part), 8 ... center well (tubular body, overflow part), 8a ... well upper end (upper end), 8b, 28b, 38b, 58b Well lower end (lower end), 9b ... supply weir, 9c ... supply weir upper end, 10 ... scraping mechanism, 20, 24 ... inclined plate, 20c, 24c ... inner peripheral end, 21, 23 ... first inclined plate ( (First group), 22 ... second inclined plate (second group), 28, 38, 48, 58 ... center well (tubular body), 28A, 38A ... first cylindrical part (overflow part), 28B , 38B, 58B ... second cylindrical portion, 38c, 58c, 58d ... stepped portion, 47 ... drainage receiving portion (cylinder whose lower end is closed) Member, discharge portion), 47a ... upper end of overflow weir (upper end), 47b ... bottom surface portion, 47c ... overflow weir portion (overflow portion), 48a ... upper end of well (upper end), 50, 51, 52, 53, 54 55, 56 ... sedimentation tank, 58C ... third cylindrical part, f, f ', f' ', fd, fu ... flock, Ov ... vertical axis, Si, Si1, Si2, Si3, Si4 ... inflow opening, So ... well opening, Wc ... clear water, Wf ... treated water

Claims (8)

Tank body,
It is arranged inside the tank body, and a pipe body whose upper end and lower end are open,
A supply section for supplying water to be treated inside the tank body and outside the tubular body;
An overflow portion that is disposed inside the tube, and overflows the water to be treated from an upper end;
A discharge part for recovering the treated water overflowing from the overflow part and discharging it to the outside of the tank body;
A sedimentation tank comprising: An opening area of the inflow opening of the water to be treated between the supply unit and the pipe body is
Larger than the opening area of the spring opening from which the treated water springs out inside the tubular body,
The sedimentation tank according to claim 1. It is arrange | positioned between the said tank body and the said pipe body in the flow path of the to-be-processed water from the said supply part to the opening of the lower end of the said pipe body, The inner peripheral surface of the said tank body from the said pipe body With a plurality of inclined plates that obliquely intersect the vertical axis as viewed from the direction toward
The sedimentation tank according to claim 1 or 2. The outer peripheral surface of the tubular body is in contact with each of the plurality of inclined plates,
The sedimentation tank according to claim 3. The inclined plate is
A first group that inclines in a first direction as it goes downward from above and a second group that inclines in a second direction intersecting the first direction;
The sedimentation tank according to claim 3 or 4. The tube is
The opening area of the lower end is larger than the opening area of the upper end, and the horizontal pipe cross-sectional area is non-increasing as it goes from the lower end to the upper end.
The sedimentation tank according to any one of claims 1 to 5. The horizontal pipe cross-sectional area of the pipe body is gradually reduced from the lower end toward the upper end.
The sedimentation tank according to claim 6. Provided inside the tubular body is a cylindrical member whose lower end is closed,
The tubular member is disposed away from the inner peripheral surface of the tubular body,
The overflow portion is formed at an upper end of the tubular member, and overflows the water to be treated from the outside to the inside of the tubular member.
The sedimentation tank according to any one of claims 1 to 7.

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