JP2024018443A - Solid-liquid separation system - Google Patents

Abstract

To provide a solid-liquid separation system with improved impact resistance and reduced breakage risk.SOLUTION: A solid-liquid separation system 100 includes a settling pond P and an inclined tube settler 10. The inclined tube settler 10 is installed in the settling pond P and includes a plurality of inclined tubes 20. At least one of corners 25-28 on an inner peripheral surface 20a of the inclined tube 20 has an R-shape.SELECTED DRAWING: Figure 5

Description

The present invention relates to solid-liquid separation systems.

In the settling basin of a conventional water treatment plant, an inclined tube sedimentation device in which a plurality of inclined tubes are provided is used in order to improve the settling area (see, for example, Patent Document 1). A system has been developed that purifies water by promoting the settling of flocs (agglomerates formed from fine particles into large aggregates using a flocculant) using the inclined tube sedimentation device.

The tilted tube sedimentation device is manufactured using hard vinyl chloride, which has the property of not floating when installed in water, and also eliminates flocs in suspended water that cannot be treated when passing through the tilted tube sedimentation device during operation. It is designed to be thin and lightweight so that it does not accumulate on the inclined pipe sedimentation device and can be moved by people during construction.

Patent No. 7045608 specification

However, one of the disadvantages of having a thin wall and light weight is that it may be damaged by the pressure of high-pressure cleaning water used during maintenance cleaning. In addition, during construction, a control panel, etc. may be placed on top of the tilted pipe sedimentation device for people to work on the tilted tube sedimentation device, and at this time, the corner of the control panel may come into contact with the sloped pipe, causing damage. There were times when I did.

An object of the present invention is to provide a solid-liquid separation system that can improve impact resistance and reduce damage.

In order to achieve the above object, a solid-liquid separation system according to a first aspect of the present invention includes a settling tank and an inclined tube settling device. The inclined tube sedimentation device is installed within the sedimentation basin and has a plurality of inclined tubes. At least one corner of the inner circumferential surface of the inclined tube has an R shape.

By having at least one of the inner circumferential surfaces have an R shape, impact resistance can be improved, and the strength can be increased against high-pressure washing water during cleaning and impact when the panel is laid during construction. can be improved.

The solid-liquid separation system according to the second invention is the solid-liquid separation system according to the first invention, in which the inclined pipe has a rectangular cylindrical shape. All corners of the inner circumferential surface have a rounded shape.

Thereby, the strength of the inclined tube can be further improved, and the strength of the inclined tube sedimentation device is improved.

The solid-liquid separation system according to the third invention is the first or second solid-liquid separation system, and the radius shape of the inner circumferential surface is formed to be 1R or more and 3R or less.

When the radius is less than 1R, the improvement in strength is small. Furthermore, if the radius is larger than 3R, the weight increases and the area increases, making it easier for flocs to accumulate on the upper end. Therefore, by setting the R shape to 1R or more and 3R or less, strength can be ensured while suppressing an increase in weight.

A solid-liquid separation system according to a fourth invention is the solid-liquid separation system according to the first or second invention, further comprising an inflow section and an outflow section. In the inflow section, water to be treated flows into the settling tank. At the outflow section, treated water flows out from the settling pond. The inclined tube sedimentation device further includes a plurality of plate-shaped support members. The plurality of plate-shaped support members are arranged in parallel to the first direction from the inflow section to the outflow section and the vertical direction. The inclined tube has a pair of inclined sides and a pair of vertical sides. The pair of inclined side portions are arranged parallel to each other and facing each other in the first direction. The pair of vertical side parts face each other in a second direction that is perpendicular and horizontal to the first direction, and are each arranged along the vertical direction. The inclined tube is disposed between the support members, and each of the pair of vertical sides is adhered to the outer support member in the second direction.

Thereby, impact resistance can be improved even when an impact is applied to the inclined portion of the inclined pipe.

The solid-liquid separation system according to the fifth invention is the solid-liquid separation system according to the fourth invention, in which the length of the inclined part in the second direction is longer than the length of the vertical part in the first direction.

By forming a rounded corner at the corner, impact resistance can be improved.

According to the present invention, it is possible to provide a solid-liquid separation system that can improve impact resistance and reduce damage.

1 is a side view showing a solid-liquid separation system according to an embodiment of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the inclined tube sedimentation device in embodiment concerning this invention. FIG. 1 is an exploded view of an inclined tube sedimentation device in an embodiment of the present invention. FIG. 1 is a plan view of an inclined tube sedimentation device in an embodiment of the present invention. (a) A plan view of the inclined pipe according to the embodiment of the present invention, (b) A side view of the inclined pipe according to the embodiment of the present invention, (c) A front view of the inclined pipe according to the embodiment of the present invention. , (d) is an enlarged view of the T section in FIG. 5(a). FIG. 3 is a plan view for explaining when an impact is applied to the inclined pipe. FIG. 3 is a diagram for explaining a method for verifying cracks in an inclined pipe. FIG. 2 is a perspective view showing an example inclined tube sedimentation device.

Hereinafter, a solid-liquid separation system according to an embodiment of the present invention will be described in detail based on the drawings.

<Configuration>
(Solid-liquid separation system 100)
FIG. 1 is a diagram showing a solid-liquid separation system 100 of this embodiment. The solid-liquid separation system 100 of this embodiment is applied to solid-liquid separation of water to be treated W in a sedimentation tank P of a water purification plant.

As shown in FIG. 1, the solid-liquid separation system 100 includes a sedimentation basin P (an example of a sedimentation basin), an inclined tube sedimentation device 10, a baffle plate 11, an overflow weir 12, and a waterway (water collection trough). 13, an inflow section 14, an outflow section 15, a sludge scraper 16, and a sludge hopper 17.

In the inflow part 14, raw water (water to be treated W) flows into the settling tank P. The outflow section 15 is provided on the opposite side of the inflow section 14 in the settling basin P, and the purified water W to be treated flows out from the settling basin P.

The inclined tube sedimentation device 10 is arranged at a portion downstream from the approximate center of the sedimentation tank P (on the outflow portion 15 side). The inclined tube settling device 10 has a plurality of inclined tubes 20.

The inclined tube sedimentation device 10 is supported so that it sinks to a predetermined depth from the surface of the water to be treated W, and a predetermined space is secured between it and the bottom surface of the sedimentation tank P. This support may be suspended by a hanging member 42 supported by the beam member 41, or may be placed on a support (not shown), for example. Details of the inclined tube sedimentation device 10 will be described in detail later.

The baffle plate 11 is provided on the upstream side (inflow section 14 side) of the inclined tube sedimentation device 10 and approximately in the center of the sedimentation tank P. The baffle plate 11 blocks the flow of the water W to be treated downstream (toward the outflow portion 15) within a region from the water surface to a predetermined depth. The baffle plate 11 is arranged such that its main surface is perpendicular to the direction of the water flowing from the inflow portion 14 .

The overflow weir 12 is arranged near the water surface of the water to be treated W on the downstream side (the outflow portion 15 side) of the baffle plate 11 . The overflow weir 12 is formed along the direction from the upstream side to the downstream side.

A waterway (water collection trough) 13 is formed surrounded by an overflow weir 12 and connected to an outflow portion 15. Note that the structure is not limited to the overflow weir 12, and may be a structure in which a hole is formed in a pipe.

The water to be treated W flowing into the sedimentation tank P from the inflow part 14 is blocked in the water flow direction (direction of arrow D) by the baffle plate 11, and the part between the lower end of the baffle plate 11 and the bottom surface of the sedimentation tank P is blocked by the baffle plate 11. descend towards. The water W to be treated that has passed between the bottom of the settling tank P and the lower end of the baffle plate 11 becomes an upward flow J toward the waterway (water collection trough) 13, and flows from the lower part of the inclined pipe sedimentation device 10 to the inclined pipe 20. It flows in and rises during the period.

Then, the sludge of the water to be treated W settles while passing through the inside of the inclined tube sedimentation device 10, and is precipitated on the inner circumferential surface or the outer circumferential surface of the inclined tube 20, whereby the water to be treated W is purified. The sludge that has settled on the inner or outer peripheral surface of the inclined pipe 20 falls under its own weight to be deposited on the slope.

The sludge scraper 16 is arranged near the bottom of the settling tank P. Sedimented sludge M is deposited near the bottom of the sedimentation tank P. The accumulated sludge M is collected in a sludge hopper 17 and drained by the sludge scraper 16 rotating clockwise in FIG. 1 . The sludge scraper 16 passes near the water surface on the upstream side of the baffle plate 11 and also scrapes up floating matter.

The sludge hopper 17 is formed on the bottom of the sedimentation tank P near the inlet 14.

(Inclination tube sedimentation device 10)
FIG. 2 is a perspective view schematically showing the configuration of a part of the inclined tube settling device 10. FIG. 3 is an exploded perspective view of the inclined tube settling device 10 shown in FIG. 2. The inclined tube settling device 10 includes a plurality of inclined tubes 20 and a plurality of sheet members 30 (an example of a support member). As the material for the inclined pipe 20 and the sheet member 30, vinyl chloride can be used, and hard vinyl chloride is particularly preferable, but the material is not limited thereto. The material of the inclined pipe 20 and the sheet member 30 is, for example, a thermoplastic resin, a vinyl resin such as polyvinyl chloride, a carbonate resin such as polycarbonate, an ester resin such as polyethylene terephthalate, or an olefin resin such as polypropylene or polyethylene. , styrene resin such as ABS, or a copolymer or mixed resin thereof.

The sheet member 30 is supported by hanging members 42 and the like extending downward from the girder 1 fixed across both sides of the sedimentation basin.

FIG. 4 is a partial plan view of the inclined tube settling device 10. In FIG. 4, the inclined pipe 20 and the sheet member 30 are hatched for clarity. Note that the hatched portion is solid.

A direction perpendicular and horizontal to the above-mentioned arrow D direction (an example of a first direction) is defined as a width direction E (an example of a second direction). The right side of the width direction E facing the arrow D direction is defined as a right direction E1, and the left side of the width direction E facing the arrow D direction is defined as a left direction E2.

As shown in FIGS. 2 and 3, a plurality of inclined pipes 20 are lined up in a line at predetermined intervals along the direction of the arrow D, and a row of the plurality of inclined pipes 20 is lined up along the width direction E. Arranged in multiple rows. Furthermore, sheet members 30 are arranged on both sides of the row of inclined pipes 20 in the width direction E. For example, in FIG. 2, four rows of a plurality of inclined pipes 20 are arranged, and are numbered L1 to L4 in order from the right end on the E1 side.

As shown in FIG. 3, the inclined pipes 20 in the two central rows L2 and L3 in the width direction E shown in FIG. 2 are inclined so that the upper ends 20c are located closer to the inflow portion 14 than the lower ends 20d. Further, as shown in FIG. 3, the inclined pipes in row L1 at the end on the rightward E1 side and row L4 at the end on the leftward E2 side are inclined so that the upper end 20c is located closer to the outflow portion 15 than the lower end 20d. are doing. Note that the inclined tubes 20 arranged in the rows L2 and L3 and the inclined pipes 20 arranged in the rows L1 and L4 have opposite inclination directions and are arranged symmetrically.

In the figure, only a configuration in which the plurality of inclined pipes 20 are arranged in four rows is shown, but more than four rows may be provided. For example, a further row may be provided on the right E1 side of the row L1, and the inclined pipes 20 in that row are arranged to be inclined so that the upper end 20c is located closer to the inlet portion 14 than the lower end 20d. Good too. For example, a further row may be provided on the left side E2 of the row L4, and the inclined pipes 20 in that row are arranged to be inclined so that the upper end 20c is located closer to the inlet portion 14 than the lower end 20d. Good too. In this way, a plurality of rows of inclined tubes 20 may be arranged so that the inclined directions alternate toward the outside in the width direction E (rightward direction E1 or leftward direction E2).

Furthermore, in the configuration shown in FIG. 2, the two central rows of inclined tubes 20, L2 and L3, are inclined in the same direction, but may be inclined in opposite directions.

As shown in FIG. 4, the inclined pipes 20 are not arranged continuously in the direction of arrow D, and a predetermined space S is provided between adjacent inclined pipes 20. Further, in the width direction E, a predetermined space S is provided between adjacent inclined pipes 20. The plurality of inclined pipes 20 are arranged in a staggered manner. For example, a space S is arranged in the row L3 to the left of the inclined pipes 20 in the row L2 in the width direction E, and a space S in the row L1 is arranged to the right of the inclined pipes 20 in the row L2 in the width direction E. is located. Further, the inclined pipe 20 in the row L3 is arranged to the left of the space S in the row L2 in the width direction E, and the inclined pipe 20 in the row L1 is arranged to the right of the space S in the row L2 in the width direction E. is located.

The inclined pipes 20 arranged in rows L2 and L3 and the inclined pipes 20 arranged in rows L1 and L4 are symmetrically constructed with the only difference in the direction of inclination. An example of the inclined pipe 20 will be described.

5(a) is a plan view of the inclined tube 20, FIG. 5(b) is a side view of the inclined tube 20, and FIG. 5(c) is a front view of the inclined tube 20. FIG. 5(d) is an enlarged view of the T section in FIG. 5(a). Note that in FIGS. 2 to 4 described above and FIGS. 6 and 7 described below, the thicknesses of the inclined tube 20 and the sheet member 30 are exaggerated for clarity.

As shown in FIG. 5(a), the inclined tube 20 has a rectangular cylindrical shape. The inclined pipe 20 includes a first side part 21 (an example of an inclined side part), a second side part 22 (an example of an inclined side part), a third side part 23 (an example of a vertical side part), and a fourth side part. 24 (an example of a vertical side part). The first side surface portion 21 is a plate-shaped portion of the inclined pipe 20 on the inlet portion 14 side. The second side surface portion 22 is a plate-shaped portion of the inclined pipe 20 on the outflow portion 15 side. The first side surface portion 21 and the second side surface portion 22 are arranged to face each other in the direction of arrow D (an example of the first direction). The first side surface portion 21 and the second side surface portion 22 are arranged parallel to each other. The first side surface portion 21 and the second side surface portion 22 are arranged parallel to the width direction E. As shown in FIG. 5(b), if an acute angle among the angles that the first side surface portion 21 and the second side surface portion 22 form with the horizontal direction is α, the angle α is generally set to 60°, for example. However, the angle may be changed by about ±10° depending on the intended use.

The third side surface portion 23 is a plate-shaped portion on the rightward E1 side of the inclined pipe 20. The third side surface portion 23 is arranged to connect the end of the first side surface portion 21 on the right direction E1 side and the end of the second side surface portion 22 on the right direction E1 side. The third side surface portion 23 is arranged perpendicularly to the width direction E.

The fourth side surface portion 24 is a plate-shaped portion on the leftward E2 side of the inclined pipe 20. The fourth side surface portion 24 is arranged to connect the end of the first side surface portion 21 on the left direction E2 side and the end of the second side surface portion 22 on the left direction E2 side. The fourth side surface portion 24 is arranged perpendicularly to the width direction E.

As shown in FIG. 5(a), the length of the first side surface portion 21 and the second side surface portion 22 in the width direction E is longer than the length of the third side surface portion 23 and the fourth side surface portion 24 in the direction of the arrow D. It is set.

The inclined pipe 20 has a corner 25 formed by an end on the right side E1 side of the first side face part 21 and an end on the inlet part 14 side of the third side face part 23, and a corner part 25 on the left side E2 side of the first side face part 21. A corner portion 26 formed by the end and the end of the fourth side surface portion 24 on the inflow portion 14 side, an end of the second side surface portion 22 on the right direction E1 side, and an end of the third side surface portion 23 on the outflow portion 15 side and a corner 28 formed by the end of the second side surface portion 22 on the right E1 side and the end of the fourth side surface portion 24 on the outflow portion 15 side.

Each of the corners 25 to 28 of the inclined tube 20 has an R-shape on its inner circumferential surface 20a. Corners 25 to 28 have a similar rounded shape. In FIG. 5(d), the rounded shape of the corner portion 26 is shown. It is preferable that the radius of the corners 25 to 28 is set to 1R or more and 3R or less. 1R means that it is formed in a circular shape with a radius of 1 mm, and 3R means that it is formed in a circular shape with a radius of 3 mm. In FIG. 5(d), the 0R state is shown by dotted lines N1 and N2. The dotted line N1 is an extension of the first side surface portion 21 of the inner circumferential surface 20a. The dotted line N2 is an extension of the fourth side surface portion 24 of the inner circumferential surface 20a.

If the radius of the corners 25 to 28 is less than 1R, the improvement in strength will be small, and if the radius is greater than 3R, the weight will increase and the cross-sectional area will increase, making it easier for flocs to accumulate at the upper end. Therefore, by setting the R shape to 1R or more and 3R or less, it is possible to maintain a balance between an increase in weight and an improvement in strength.

As shown in FIG. 5(d), each of the corners 25 to 28 also has a rounded shape on the outer circumferential surface 20b of the inclined tube 20, but if the radius is made small for molding, burrs and the like may occur. If the radius is too large, the flocs may get stuck in the gap, so the R should be approximately 0.5 or more and 1 or less.

The sheet member 30 is a plate-shaped member, as shown in FIGS. 2 and 3. The sheet member 30 is arranged vertically and parallel to the direction of arrow D. The sheet members 30 are arranged on the right E1 side of row L1, between rows L1 and L2, between rows L2 and L3, between rows L3 and L4, and on the left E2 side of row L4. has been done. The sheet member 30 has a first main surface 31 on the right side E1 and a second main surface 32 on the left side.

A pair of first side surface portions 21 and second side surface portions 22 on the width direction E side of each inclined pipe 20 are bonded to a sheet member 30 disposed on the outside of each side surface portion 21 and second side surface portion 22 . As shown in FIG. 4, the first side surface 21 is bonded to the second main surface 32 of the sheet member 30, and the second side surface 22 is bonded to the first main surface 31 of the sheet member 30. The third side surface portion 23 and the fourth side surface portion 24 face the space S.

FIG. 6 is a plan view for explaining when an impact is applied to the inclined pipe 20. For example, as shown by arrow F, when an impact is applied to the first side surface portion 21 of the inclined tube 20, the first side surface portion 21 moves inward. At this time, since the third side surface portion 23 and the fourth side surface portion 24 are bonded to the sheet member 30, cracks are likely to occur starting from the bonded portions of the corners 25 and 25 (see circle portions G and H). In this embodiment, since the corners 25 and 26 have a rounded shape, strength can be ensured and the occurrence of cracks can be reduced.

As described above, by having the corners 25 to 28 of the inner circumferential surface 20a of the inclined pipe 20 having a rounded shape, the impact resistance strength can be improved, and high-pressure washing water during cleaning and the control panel during construction can be prevented. It can improve the strength against impact when laid.

Further, by setting the radius of the corners 25 to 28 of the inner circumferential surface 20a to 1R or more and 3R or less, it is possible to suppress an increase in weight and reduce the occurrence of cracks.

<Other embodiments>
Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and can be modified as appropriate without departing from the spirit thereof.

(A)
The number of rows in the inclined tube sedimentation device 10 and the number of inclined tubes 20 in each row need not be limited to the configuration of the above embodiment, and may be changed.

(B)
In the above embodiment, all of the corners 25 to 28 have a rounded shape. From the viewpoint of impact resistance, it is preferable that all of the corners 25 to 28 have a rounded shape, but since at least one corner has a rounded shape, the durability is improved compared to a conventional inclined pipe. Impact resistance can be improved.

(C)
In the embodiment described above, the space S is provided between the inclined pipes 20 in the direction of the arrow D, but it may not be provided. Moreover, although the space S is provided next to the inclined pipe 20 in the width direction E, the inclined pipe 20 may be arranged.

(D)
In the above embodiment, the inclined pipe 20 has a rectangular cross section perpendicular to the direction in which the pipe extends, but it is not limited to a rectangular shape, and may have a polygonal shape with five or more sides. .

(Example)
(Verification of cracks)
The occurrence of cracks in the inclined pipe 20 was verified, and the impact strength was confirmed.

The test was conducted as follows.
- For the test, an inclined tube 20 having corner portions 25 to 28 having an R shape of approximately 1.5R was used.
- As shown in FIG. 7, the inclined pipe 20 was arranged so that the third side part 23 and the fourth side part 24 were vertical, and the guide pipe 51 was arranged at the upper end 20c. An eggplant-shaped weight 52 was dropped through the guide pipe 51 to confirm the height at which the inclined pipe 20 would crack.
- A conventional 0R inclined pipe in which all of the corners 25 to 28 of the inclined pipe 20 are not rounded was used as a comparative example. Note that the corner in the comparative example where the rounded shape is not formed is the corner formed by the extension lines N1 and N2 in FIG. 5.

As a result, in the conventional inclined pipe, the height at which it would not break was 900 mm, and in the inclined pipe of this embodiment, the height at which it would not break was 1300 mm. Thus, it can be seen that the inclined tube 20 of this embodiment has an impact strength approximately 1.45 times higher than that of the conventional inclined tube.

(Weight verification)
We confirmed the difference in weight due to the rounded corners.
- The cross-sectional area of the inclined pipe 20 was determined by subtracting the inner peripheral area from the outer peripheral area.
- The weight (g/piece) of one inclined tube 20 was determined from the product of the volume of the inclined tube 20 and the specific gravity of 1.4.
- Since 107 inclined tubes 20 were used, the total weight (kg/piece) of all inclined tubes 20 was determined by multiplying the weight (g/piece) of one inclined tube 20 by 107.

Compared to the above-mentioned inclined tube sedimentation device in which the corner portions are not rounded, the weight increased by forming the corner portions in the rounded shape as in the inclined tube sedimentation device 10 of this embodiment is as follows ( As shown in Table 1), the weight per piece (W372mm x L3000mm x H530mm) was 0.31kg, which was a slight increase of about 1%. In addition, as shown in FIG. 8, the length of the inclined tube settling device 10 in the width direction E is set to W, the height is set to H, and the length along the direction of arrow D is set to L. "Length" in the following (Table 1) is the length along the inclination of the inclined pipe 20, and is indicated by M in FIG. 8. "Specific gravity" in the following (Table 1) indicates the specific gravity of the material of the inclined tube 20. "Outer peripheral area (cm ² )", "Inner peripheral area (cm ² )", "Cross-sectional area (cm ² )", "Volume (cm ³ )" and "Weight (g/piece)" in the following (Table 1) is shown for one inclined pipe. "Number (pieces/pieces)" indicates the number of inclined tubes 20 used in one inclined tube sedimentation device. "Weight (kg/piece)" indicates the weight of one inclined tube sedimentation device, and is the product of "weight (g/piece)" and "number of tubes (pieces/piece)."

これにより、施工時における傾斜管の持ち運びにも問題がないことが分かる。

This shows that there is no problem in transporting the inclined pipe during construction.

The solid-liquid separation system of the present invention has the effect of improving impact resistance and reducing damage, and is useful as a final settling tank in a sewage treatment facility.

10: Inclined tube sedimentation device 20: Inclined tube 20a: Inner peripheral surface 25 to 28: Corner 100: Solid-liquid separation system P: Sedimentation basin

Claims (5)

a sedimentation pond;
an inclined tube sedimentation device installed in the sedimentation basin and having a plurality of inclined tubes,
At least one corner of the inner circumferential surface of the inclined pipe has an R shape.
Solid-liquid separation system. The inclined pipe has a square cylindrical shape,
All corners of the inner circumferential surface have an R shape,
The solid-liquid separation system according to claim 1. The R shape of the inner circumferential surface is formed with 1R or more and 3R or less,
The solid-liquid separation system according to claim 1 or 2. an inflow portion through which the water to be treated flows into the sedimentation basin;
further comprising an outflow portion through which treated water flows out from the sedimentation pond,
The inclined tube sedimentation device includes:
further comprising a plurality of plate-shaped support members arranged in parallel in a first direction from the inflow part to the outflow part and in a vertical direction;
The inclined pipe is
a pair of inclined side parts that are parallel to each other and are arranged opposite to each other in the first direction;
a pair of vertical side parts facing each other in a second direction perpendicular and horizontal to the first direction, each of which is disposed along the vertical direction;
The inclined pipe is disposed between the support members, and each of the pair of vertical side portions is bonded to the support member disposed on the outside in the second direction.
The solid-liquid separation system according to claim 1 or 2. The length of the inclined side part in the second direction is longer than the length of the vertical side part in the first direction.
The solid-liquid separation system according to claim 4.

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