KR101710821B1 - solid-liquid separation apparatus and solid-liquid separation method - Google Patents

Abstract

The solid-liquid separation device includes a to-be-treated water inlet portion for introducing the for-treatment water, a solid-liquid separation portion for trapping solid matter in the for-treatment water introduced from the to-be treated water inlet portion and having a floc growth zone for growing flocs by the for- A separation zone for separating the floc grown in the floc growth zone from the falling water leaving the floc growth zone in one direction and the floc descended from the falling stream from the untreated water after passing the floc growth zone, So that the flocs have an ascending flow rate which raises the separated water to be treated.

Description

Solid-liquid separation apparatus and solid-liquid separation method [

The present invention relates to a solid-liquid separator and a solid-liquid separator.

BACKGROUND ART Conventionally, an apparatus disclosed in Patent Document 1 below is known as a solid-liquid separator. The solid-liquid separating apparatus includes a cylindrical inner cylindrical water tank having a bottom in a cylindrical outer cylindrical water tank with a bottom, a double water tank having a bottom portion of the outer cylindrical water tank and a bottom portion of the inner cylindrical water tank, . In this solid-liquid separator, a floc growth zone is formed in the inner cylinder water tank by introducing the raw water supplied with the coagulant into the lower portion of the inner cylinder water tank, and the floc overflowing from the inner cylinder water tank is introduced into the inner cylinder water tank So that the concentrated flocs settled on the bottom portion of the outer cylindrical water tank are discharged while the treated water separated and raised from the flocs is discharged from the upper portion of the outer cylindrical water tank.

JP-A-2010-274199 (Fig. 3)

Here, in the above solid-liquid separator, there is a desire to improve the degree of clarification of the treated water because the clarity of the treated water is preferably high.

The present invention has been made to solve these problems, and it is an object of the present invention to provide a solid-liquid separator and a solid-liquid separator which can purify treated water.

A solid-liquid separating apparatus according to one aspect of the present invention includes a to-be-treated water inlet portion for introducing for-treatment water, and a solid-liquid separator for collecting solid matter in the for-treatment water introduced from the for- The flotation apparatus according to any one of claims 1 to 3, further comprising: a flotation zone in which a floc that has grown in the floc growth zone is lowered in one direction from a floc growth zone, And an ascending flow channel for raising the untreated water in which flocs are separated in the separation zone.

According to the solid-liquid separator according to one aspect of the present invention, the flocs grown in the floc growth zone smoothly descend the falling stream from the floc growth zone and are smoothly transported to the separation zone and separated from the for-treatment water. The untreated water in which flocs are separated in the separation zone rises smoothly upwards. As described above, since the flow of the water to be treated by the falling downflow, the separation zone, and the upward flow is formed, the sedimentation of the flood is prevented by the rising flow or the floc is prevented from rising by the upward flow. Therefore, the SS concentration of the treated water can be lowered, and the treated water can be further refined.

In the solid-liquid separating apparatus, the upward flow and the downward flow are formed at different positions when viewed from the up and down direction, and the region at the lower end side of the upward flow and the downstream end region of the downward flow may communicate with each other through the separation zone. With this arrangement, the water to be treated descends and flows from the lower end region of the lower end flow channel to the separation zone through the separation zone, flows from the lower end region to the upward flow channel, . Since the upward flow and the downward flow are formed at different positions when viewed from the up and down direction, it is possible to suppress the settling of the floes due to the rising flow or to prevent the floes from rising due to the rising flow.

The solid-liquid separator may have a double-layer structure including a first bottom portion and a second bottom portion, and the separation zone may be between the first bottom portion and the second bottom portion. With such a configuration, a sufficient space between the first bottom portion and the second bottom portion can be formed as a separation zone.

In the solid-liquid separator, the falling stream and the rising stream may be separated. With this configuration, it is possible to more reliably suppress the settling of the flocs by the rising flow or the rising of the flocs by the rising flow.

In the solid-liquid separating apparatus, the falling stream and the rising stream may be divided. With this configuration, the falling down stream and the upward stream can be separated from each other by a simple structure simply by providing a partition.

In the solid-liquid separator, the falling stream and the rising stream may be spaced apart from each other. By such a constitution, by securing the distance between the falling stream and the rising stream, it is possible to sufficiently secure the transverse flow settling distance in the separation zone.

A solid-liquid separator comprising: a bottomed tubular inner cylinder tank having a bottom portion inside a bottomed tubular outer cylinder tank having a first bottom portion; and a ring-shaped inner cylinder tank between the outer cylinder water tank and the inner cylinder tank A plurality of partition plates which are provided from the upper end to the lower end of the inner cylinder water tank and divide the ring-shaped intermediate region into a plurality of regions along the circumferential direction are provided. With this configuration, a floc growth zone in which flocs grow by the rising flow of the raw water is formed in the inner cylinder water tank, flocs grown in the floc growth zone overflow from the upper end of the inner cylinder tank to the lowered stream, So that the water to be treated accompanied by the flock is separated from the flock at the second bottom portion of the outer tub water tank and is discharged to the lower stream room And the upward flow divided by the partition plate rises smoothly in ascending flow and is transported upward. As described above, the lower fl ow of the fl ow is settled downward by the down stream to be carried to the second bottom part of the outer tub water tank, and the for-treatment water separated from the floc is raised by the upward flow from the second bottom part of the outer tub water tank, The upward flow is divided into the division plates, and the unidirectional flow is formed. Therefore, the settling of the flocs can be prevented by the rising flow, or the flocs can be prevented from rising with the rising flow. Therefore, the SS concentration of the treated water can be lowered, and the treated water can be further refined.

In the solid-liquid separating apparatus, the upper end of the inner cylinder water tank corresponding to the lowering water separated by the partition plate may be set lower than the upper end of the inner cylinder water tank of the adjacent region of the lowering watercolor. With this configuration, flocs can easily flow over from the top of the inner cylinder water tank corresponding to the downflow.

In the solid-liquid separating device, the lower end of the inner cylinder water tank and the lower end of the partition plate corresponding to the lowering water separated by the partition plate may extend downward from the lower end of the upwardly flowing inner cylinder water tank. With this configuration, the float sinking the downflowing water flows upward from the lower end of the inner cylinder water tank and the lower end of the partition plate corresponding to the lowering water stream, So that the treated water can be further refined.

A solid-liquid separation method according to one aspect of the present invention is a solid-liquid separation method in which solid-liquid separation is performed by letting water to be treated pass through a floc growth zone. The solid-liquid separation method includes a descending step of descending the floc in the floc growth zone in one direction, A separation step of separating the floc from the untreated water after passage of the floc growth zone, and an ascending step of ascending the untreated water from which the floc has been separated in the separation step.

The solid-liquid separation method according to one aspect of the present invention can exhibit the same operation and effect as the above-described solid-liquid separation device.

As described above, according to the present invention, it is possible to provide a solid-liquid separator and a solid-liquid separator which can further purify the treated water.

1 is a schematic sectional configuration diagram showing a solid-liquid separator (coagulating sedimentation apparatus) according to a first embodiment of the present invention.
2 is a plan view of the solid-liquid separator (coagulating sedimentation apparatus) shown in Fig.
Fig. 3 is a perspective view showing the inner cylinder water tank and the partition plate in Figs. 1 and 2. Fig.
4 is a plan view showing a solid-liquid separator (coagulating sedimentation apparatus) according to a second embodiment of the present invention.
Fig. 5 is a perspective view showing the inner cylinder water tank and the partition plate in Fig. 4;
6 is a perspective view showing an inner cylinder water tank and a partition plate of a solid-liquid separation apparatus (coagulation sedimentation apparatus) according to a third embodiment of the present invention.
7 is a perspective view showing an inner cylinder water tank and a partition plate of a solid-liquid separator (coagulation sedimentation apparatus) according to a fourth embodiment of the present invention.
8 is a schematic configuration diagram showing a solid-liquid separator according to a fifth embodiment of the present invention.
9 is a schematic cross-sectional view along the line IX-IX shown in Fig.
10 is a schematic cross-sectional view along the line XX shown in Fig.
11 is a schematic structural view showing a solid-liquid separator according to a sixth embodiment of the present invention.
12 is a schematic cross-sectional view along the line XII-XII shown in Fig.
13 is a schematic configuration diagram showing a solid-liquid separator according to a seventh embodiment of the present invention.
14 is a schematic cross-sectional view along the line XIV-XIV shown in Fig.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, preferred embodiments of a solid-liquid separator according to the present invention will be described with reference to the drawings. However, in the embodiments shown in Figs. 1 to 7, the coagulating sedimentation apparatus will be described as an example of a solid-liquid separator. However, the solid-liquid separator is not limited to the coagulating sedimentation apparatus. That is, the solid-liquid separating apparatus includes a to-be-treated water inlet portion for introducing the for-treatment water, and a floc growth zone for capturing solid matter in the for-treatment water introduced from the for- The configuration is not particularly limited.

2 is a plan view of the coagulating sedimentation apparatus shown in Fig. 1, Fig. 3 is a sectional view of the coagulating sedimentation tank shown in Fig. 1 and Fig. 2, FIG.

As shown in Fig. 1, the coagulating sedimentation apparatus (solid-liquid separation apparatus) 100 according to the present embodiment includes a cylindrical outer cylindrical water tank 1 having a bottom, a small diameter lower outer diameter water tank 1, And a bottomed cylindrical inner cylinder (2) accommodated coaxially inside the outer cylinder (1). In this coagulating sedimentation apparatus 100, the bottom portion (second bottom portion) of the inner cylinder water tank 2 is spaced upward from the bottom portion (first bottom portion) of the outer column water tank 1 by a predetermined length, . In this case, the outer cylinder 1 and the inner cylinder 2 are cylindrical, but they may be square.

An introduction pipe 4 for introducing the raw water (for-treatment water) into the bath is inserted into the inner wall of the inner water tank 1 2 into the inner cylinder water tank 2 by inserting the outer circumferential wall. The raw water here is, for example, an organic wastewater mixed with an inorganic coagulant such as PAC (polychlorinated aluminum). The introduction pipe 4 is connected to a flocculant supply line L1 for supplying a polymer flocculant such as an anionic polymer, for example.

1 to 3, a ring-shaped (cylindrical) intermediate region R formed between the outer cylinder water tank 1 and the inner cylinder water tank 2, There are provided a plurality of partitioning plates 3 for dividing into a plurality of regions along the direction. The partition plate 3 is composed of two pieces and the intermediate plate R is divided into one region R1 (falling down stream) and another region (adjacent region, upflow stream) R2 Divided into two. The end of the outer side of each of the partitioning plates 3 and 3 is connected to the inner circumferential surface of the outer cylinder water tank 1 and the end of the inner side thereof is connected to the outer peripheral surface of the inner cylinder water tank 2, To the outer shaft 1. The partitioning plate 3 is provided from the upper end to the lower end of the inner cylinder water tank 2. An inner cylinder water tank upper end U1 corresponding to one region R1 divided by the partitioning plate 3 is provided in the adjacent region R2, Is set to be lower than that of the inner cylinder tank upper end (U2) of the inner tank (1).

According to the coagulating sedimentation apparatus 100 having such a constitution, the raw water including the flocculating agent is uniformly sprayed from the introduction pipe 4 in the inner water tank 2 to the lower portion of the inner water tank 2, It is mixed by agitating force and shearing force to form flocs. Flocs formed in the inner cylinder water tank 2 are deposited from the bottom portion, and the fluidized bed of the floc zone is formed by the further supplied raw water. The raw water containing the flocculant is caught in the floc which was generated earlier so that the generated small flocs are captured in the flotation zone (RX) in which flocs further grow, At the same time, the raw water is refined as if it is filtered in the floc growth zone RX. The collected water that has passed through the floc growth zone (RX) rises in the outer column water tank (1).

However, in the bottom portion of the inner cylinder water tank 2, the disclosed dispersion tube (also referred to as a distributor) including the publication of Japanese Unexamined Patent Publication No. 2010-274199 is disposed and the raw water is discharged from the dispersion tube while rotating the dispersion tube , The raw water may be evenly distributed in the inner cylinder water tank 2 and uniformly raised to form the flocking zone RX.

On the other hand, the flock grown in the floc growth zone RX unilaterally flows from the upper end U1 of the lower inner tank to the corresponding one region R1, So that it is smoothly transported to the bottom of the outer tank 1 and deposited thereon. The water conveyed to the bottom of the outer tainting tank 1 along with the floc is separated from the flock at the bottom of the outer tainting tank 1 and the adjacent region R2 of the one region R1 is set as a separation water rising zone Rises smoothly in ascending flow, and is transported upward. As described above, the flow in one direction from the upper end U1 of the lower inner cylinder tank to the bottom portion in the one region R1, the outer cylinder water tank 1, and the adjacent region R2 is formed, This is due to the fact that the apparent specific gravity is heavier than the water not containing flocs.

The concentrated flocs deposited on the bottom portion of the outer tub 1 are discharged to the outside from the concentrated floc discharge portion 8 provided at the center of the bottom portion of the outer tub 1, The collected water (supernatant water) is discharged from the treated water outlet 9 provided at the upper portion of the outer water tank 1 to the rear end as treated water.

As described above, in the present embodiment, the intermediate region R is divided into a region R1 in which the floc is settled downward by the partition plate 3 to be carried to the bottom portion of the outer shaft 1, The separated water is divided in the circumferential direction into the adjacent region R2 which upwardly conveys the separated water from the bottom portion in the outer shaft 1 by the upward flow and is formed in one direction. The flocs do not rise due to the ascending flow, so that the SS concentration of the treated water can be lowered, and the treated water can be further clarified.

The coagulating sedimentation apparatus (solid-liquid separation apparatus) 100 according to the present embodiment is provided with an introduction pipe 4 for introducing the for-treatment water (a treatment object introducing section) And a flocking growth zone RX for growing flocs by the water to be treated. The flocculation and sedimentation apparatus 100 further comprises a region R1 as a lowering stream for lowering flocs grown in the flocking zone RX in one direction from the flocking zone RX and a region R1 as a lowering streaming region, From the for-treatment water after passing through the floc growth zone (RX), and an adjacent region (R2) as an adjacent upflowing water for raising the for-treatment water in which flocs are separated in the separation zone. However, in this embodiment, the separation zone is formed in the region between the bottom of the inner cylinder water tank 2 and the bottom of the outer cylinder water tank 1. [

According to the flocculation and sedimentation apparatus 100 of the present embodiment, the flocs grown in the floc growth zone RX smoothly descend from the floc growth zone RX to the separation zone, . The untreated water in which flocs are separated in the separation zone rises smoothly upwards. As described above, since the flow of the water to be treated by the falling downflow, the separation zone, and the upward flow is formed, the sedimentation of the flood is prevented by the rising flow or the floc is prevented from rising by the upward flow. Therefore, the SS concentration of the treated water can be lowered, and the treated water can be further refined.

In the flocculation and sedimentation apparatus 100, the upward flow and the downflow flow are formed at different positions when viewed from the up and down direction (the state shown in FIG. 2), and the region at the lower end side of the upward flow and the downstream- It is communicated through the zone. In the present embodiment, as shown in Fig. 2, a falling stream is formed in a part of the area (the right half region of the paper surface) in the circumferential direction of the coagulating sedimentation apparatus 100 and the other region In the region of the upper surface of the substrate. With this arrangement, the water to be treated descends and flows from the region on the lower end side of the lowered stream to the separation zone through the separation zone, flows from the region on the lower end side to the upward stream, . Since the upward flow and the downward flow are formed at different positions when viewed from the up and down direction, it is possible to suppress the settling of the floes due to the rising flow or to prevent the floes from rising due to the rising flow.

The flocculation and sedimentation apparatus 100 has a double bottom structure composed of a first bottom portion and a second bottom portion, and the separation zone is located between the first bottom portion and the second bottom portion. With this configuration, a sufficient space between the first bottom portion and the second bottom portion can be formed as a separation zone.

In the coagulating sedimentation apparatus (100), the falling stream and the rising stream are separated. With this configuration, it is possible to more reliably suppress the settling of the flocs by the rising flow or the rising of the flocs by the rising flow.

In the flocculation and sedimentation apparatus 100, the falling stream and the rising stream are separated. With this configuration, the falling down stream and the upward stream can be separated from each other by a simple structure simply by providing a partition.

The solid-liquid separation method according to the present embodiment is a solid-liquid separation method in which solid-liquid separation is performed by passing the for-treatment water through the floc growth zone RX. The solid-liquid separation method includes a descending step of descending the flock grown in the floc growth zone (RX) in one direction, a separating step of separating the untreated water after passing the floc and the floc growth zone that have descended in the descending step, And raising the separated water to be treated.

The solid-liquid separation method according to the present embodiment can exhibit the same operation and effect as the above-described solid-liquid separation device.

Fig. 4 is a plan view showing a coagulating sedimentation apparatus according to a second embodiment of the present invention, and Fig. 5 is a perspective view showing the inner cylinder water tank and the partition plate in Fig.

The coagulating sedimentation apparatus of the second embodiment is different from the flocculation and sedimentation apparatus of the first embodiment in that the partition plate 3 is divided into four and the intermediate region R is divided into four by the partition plate 3 And the upper end U1 of the inner cylinder water tank corresponding to one region R1 among the plurality of regions divided by the partition plate 3 is made lower than the inner cylinder water tank upper end U2 of the adjacent region R2 of one region R1 The point of setting is the same as that of the first embodiment. The upper end U1 of the lower inner cylinder tank and the upper end U2 of the adjacent inner cylinder higher than the upper end U1 of the inner cylinder water tank are arranged alternately in the circumferential direction between the partitioning plates 3, It is installed in parallel.

Needless to say, also in the second embodiment configured as described above, the same actions and effects as those of the first embodiment are shown.

Fig. 6 is a perspective view showing the inner cylinder water tank and the partition plate of the flocculation and sedimentation apparatus according to the third embodiment of the present invention, and Fig. 7 is a view showing the inner cylinder water tank and the partition plate of the flocculation and sedimentation apparatus according to the fourth embodiment of the present invention It is a perspective view.

The coagulating sedimentation apparatus of the third embodiment is different from the coagulation sedimentation apparatus of the first embodiment and the coagulation sedimentation apparatus of the fourth embodiment is different from the coagulation sedimentation apparatus of the second embodiment in that the upper end The lower end D1 of the inner tub and the lower end D3 of the partition plate 3 corresponding to the lower one region R1 are extended below the lower end D2 of the inner cylinder water tank of the adjacent region R2. However, the inner tank bottom end D1 corresponding to one area R1 and the bottom end D3 of the partition plate 3 extend here by about 1 to 100 cm.

According to the third and fourth embodiments as described above, the inner cylinder water tank bottom end D1 and the bottom end D3 of the partition plate 3 corresponding to the one region R1 are connected to the inner cylinder water tank bottom end D2 The flocs settling in one region R1 can be prevented from being swept up by the separated water rising in the adjacent region R2, and the treated water can be further refined.

8 is a schematic configuration diagram showing a solid-liquid separator according to a fifth embodiment of the present invention. 9 is a schematic cross-sectional view along the line IX-IX shown in Fig. 10 is a schematic cross-sectional view along the line X-X shown in Fig.

The solid-liquid separating apparatus 200 according to the present embodiment is provided with an external water collecting tank 201, And an internal water tank 202. In the solid-liquid separating apparatus 200, the inner side of the inner cylinder water tank 202 is provided with a floc growth zone (not shown) for capturing solid matter in the for-treatment water introduced from the for-treatment water introducing section 14 and for growing flocs by the for- . The solid-liquid separator 200 has a to-be-treated water inlet portion 14 for introducing the for-treatment water into the inner tank 202. In addition, a treatment water outlet 19 for discharging the collected water (symbol water) rising in the outer water cistern 201 is provided at the upper portion of the outer cistern 201.

The outer water tank 201 has a configuration in which a portion (intermediate region R) corresponding to the outer peripheral surface of the inner water tank 202 is divided into a plurality of flow portions 203 in the outer water tank shown in Fig. The distribution portion 203 is provided on the outer peripheral surface of the inner cylinder water tank 202 so as to extend in the vertical direction. The flow dividing sections 203 are provided at positions spaced apart from each other so as to be substantially equally spaced in the circumferential direction of the inner cylinder water tank 202. In the present embodiment, four flow passages 203 are provided, but the amount is not particularly limited. One of the circulating portions 203 facing each other is configured as a falling stream RD and the other is configured as an upward flow RU. Since the plurality of flow passages 203 are formed at different positions in the circumferential direction, the upward flow RU and the downstream flow flow RD are formed at different positions when viewed from the up and down direction. With this configuration, in the solid-liquid separator 200, the falling stream RD and the rising stream RU are separated. However, the term "separation" as used herein means that the compartment in which the falling stream RD is formed and the compartment in which the upward flow RU is formed are independent from each other and the flow of the water to be treated and the like do not interfere with each other . In the present embodiment, since each of the flow dividing sections 203 is spaced apart in the circumferential direction, the falling stream RD and the rising stream RU are separated from each other by being separated from each other. A state in which the falling stream RD and the rising stream RU are spaced apart from each other is a state in which a falling stream RD is formed in one compartment and is provided at a position spaced apart from the one compartment (RU) is formed in the other compartment in which the ascending flow path (RU) is formed. The state in which the falling stream RD and the rising stream RU are separated from each other is one of the states in which the falling stream RD and the rising stream RU are separated.

The solid-liquid separator 200 has a double-layer structure composed of a bottom portion (first bottom portion) 201a of the outer cylinder water bath 201 and a bottom portion (second bottom portion) 202a of the inner cylinder water tank 202 , And the separation zone RS is between the bottom part 201a and the bottom part 202a. The lower end region of each rising stream RU and the lower end region of the lower stream end stream RD communicate with each other through the separation zone RS. The flocs separated from the for-treatment water in the separation zone RS are discharged to the outside from the flock discharge section 18. [

However, the structure of the inner cylinder water tank 202 is not particularly limited, and any inner cylinder water tank described in the first to fourth embodiments may be applied. Namely, as shown in FIG. 9, the upper end U1 of the inner cylinder water tank corresponding to the lowering stream RD may be set lower than the upper end U2 of the inner cylinder water tank corresponding to the upward flow RU.

The solid-liquid separator 200 according to the present embodiment can exhibit the same operation and effect as those of the coagulating sedimentation apparatus 100 according to the first embodiment. Particularly, in the solid-liquid separator 200 according to the present embodiment, the falling stream RD and the rising stream RU are spaced apart from each other. By such a configuration, the distance between the falling stream RD and the rising stream RU can be ensured, and the cross-flow settling distance in the separation zone RS can be sufficiently secured.

11 is a schematic structural view showing a solid-liquid separator according to a sixth embodiment of the present invention. 12 is a schematic cross-sectional view along the line XII-XII shown in Fig. Note that the line XII-XII is a line curving at the central axis of the solid-liquid separator 300.

The solid-liquid separating apparatus 300 according to the present embodiment has a structure in which the falling stream RD and the rising stream RU are divided so that the falling stream RD and the rising stream RU are separated. However, a state in which "the falling stream RD and the upward flow RU are divided" means that a part of the continuous space is divided into a plurality of sections by being partitioned by a wall-shaped member such as a partition plate, (RD) is formed, and an upflow (RU) is formed in another compartment adjacent to the one compartment. The state in which the falling stream RD and the rising stream RU are divided is a state in which the falling stream RD and the rising stream RU are separated from each other. Specifically, the solid-liquid separator 300 includes a bottom (second bottom) 302a (first bottom) 301a inside a bottomed tubular outer tank 301 having a bottom (first bottom) 301a, And a bottomed cylindrical water tank 302 having a bottom. The solid-liquid separator 300 has a double-layer structure including a bottom portion 301a and a bottom portion 302a, and the separation zone RS is between the bottom portion 301a and the bottom portion 302a. The solid-liquid separator 300 has a ring-shaped intermediate region between the outer cylinder water tank 301 and the inner cylinder water tank 302.

The solid-liquid separator 300 is provided from the upper end to the lower end of the inner cylinder water tank 302 and includes a plurality of partition plates 303 that divide the ring-shaped intermediate region into a plurality of regions along the circumferential direction, (RD) and an ascending flow zone (RU). The falling stream RD and the rising stream RU are set to be offset from each other in the circumferential direction in each of the compartments partitioned by the partitioning plate 303. However, the number of sections divided by the partition plate 303 is not particularly limited. Since the plurality of compartments divided by the partition plate 303 are formed at different positions in the circumferential direction, the upward flow RU and the downward flow range RD are formed at different positions when viewed from the up and down direction . With this configuration, in the solid-liquid separator 300, the falling stream RD and the rising stream RU are separated. In the solid-liquid separator 300, the lower end region of each upflow RU and the lower end region of the lower end stream RD communicate with each other through the separation zone RS. Other configurations are the same as those of the solid-liquid separator 200 according to the fifth embodiment.

The solid-liquid separator 300 according to the present embodiment can exhibit the same operation and effect as those of the coagulating sedimentation apparatus 100 according to the first embodiment and the solid-liquid separator 200 according to the fifth embodiment. Particularly, in the solid-liquid separating apparatus 300 according to the present embodiment, the falling stream RD and the rising stream RU are divided by the partition plate 303. With this configuration, the falling down stream and the upward stream can be separated from each other by a simple structure simply by providing a partition.

13 is a schematic configuration diagram showing a solid-liquid separator according to a seventh embodiment of the present invention. 14 is a schematic cross-sectional view along the line XIV-XIV shown in Fig.

The solid-liquid separator 400 according to the present embodiment differs from the solid-liquid separator 300 according to the sixth embodiment mainly in that the falling stream RD and the rising stream RU are not separated from each other. Specifically, the solid-liquid separator 400 includes a bottom portion (second bottom portion) 402a (first bottom portion) 401a, a bottom portion (second bottom portion) 401a, And a bottomed tubular inner cylinder water tank 402 having a bottom. The solid-liquid separator 400 has a ring-shaped intermediate region between the outer tub 401 and the inner tub 402.

Among the intermediate regions constituted as the same section, one portion functions as a falling stream RD and the other portion functions as a rising stream RU. For example, as shown in Fig. 13, a region on the right side of the middle region is configured as a falling stream RD, and a region on the left side of the ground is configured as a rising stream RU. The solid-liquid separator 400 is provided with a water flow forming means for forming a water flow so that a part of the same compartment is a falling stream RD and the other part is an upward flow RU. The constitution of the water flow forming means in which a part of the same compartment is formed as the falling stream RD and the other part is made the riser RU is not particularly limited. For example, the inner cylinder water tank shown in the first to fourth embodiments may be applied as the inner cylinder water tank 202. [ That is, the water flow forming means may be constituted by setting the inner cylinder water tank upper end U1 corresponding to the falling stream RD to be lower than the inner cylinder water tank upper end U2 corresponding to the upward flow RU. Alternatively, as shown in Fig. 14, even if the height of the upper end U1 of the inner cylinder water tank and the upper end U2 of the inner cylinder water are equal to each other do). For example, the for-treatment water introducing portion 14 in which the introduction position and the angle of the for-treatment water are adjusted so that the falling stream RD and the rising stream RU are formed may be configured as the water flow forming means. Alternatively, the water flow forming means may be constituted by providing a mechanism for adjusting the flow of the water to be treated in the inner water tank 402. In the solid-liquid separating apparatus 400 according to the present embodiment, the falling stream RD and the rising stream RU are not separated. In the solid-liquid separator 400, the lower end region of each rising-up stream RU and the lower stream end region RD communicate with each other through the separation zone RS. Other configurations are the same as those of the solid-liquid separator 200 according to the fifth embodiment.

The solid-liquid separator 400 according to the present embodiment can exhibit the same operation and effect as the coagulating sedimentation apparatus 100 according to the first embodiment. Particularly, in the solid-liquid separating apparatus 400 according to the present embodiment, since the falling stream RD and the rising stream RU are not separated, the structure can be simplified.

Although the present invention has been described in detail with reference to the embodiments thereof, the present invention is not limited to the above-described embodiments. For example, in the above embodiment, Although the coagulant is supplied to the raw water, the coagulant may be supplied directly into the internal water tank 2.

In the above-described embodiment, the middle region R is divided into two and four, but the present invention is not limited to these and may be a plurality of divisions. In practice, however, even division is performed. The division of the intermediate region R is not limited to the even division.

In the above-described embodiment, the solid-liquid separating device having the double bottom structure composed of the first bottom portion and the second bottom portion and the separation zone being between the first bottom portion and the second bottom portion has been described. Instead, a solid-liquid separator having a single bottom structure may be employed. For example, the solid-liquid separating device may have a water tank in which the inside is constituted as a floc growth zone and a circulation part provided on the outer peripheral surface of the water tank. The distribution portion is divided into a division plate in the radial direction of the water tank. In the distribution portion, the compartment near the outer circumferential surface of the water tank is configured as a falling airflow, and the compartment far from the outer peripheral surface of the water tank is configured as an upward flow. Further, the partition plate extends in the vertical direction, and the lower end of the partition plate is spaced upward from the bottom of the flow portion. As a result, the for-treatment water which overflows from the upper end of the water tank and descends downward flows through the region between the lower end portion and the bottom portion of the partition plate and flows upward to rise. Therefore, a region between the lower end portion and the bottom portion of the partition plate is configured as a separation zone. In such a solid-liquid separating apparatus, since the rising-flow-side and the falling-flow-side are arranged side by side in the radial direction of the water tank, the rising-flow and the falling-flow are formed at different positions when viewed from the upper and lower directions. A region on the lower end side of the rising stream and a region on the lower end side of the falling stream communicate with each other through the separation zone.

A solid-liquid separator according to one aspect of the present invention includes a tubular inner cylinder tank having a bottom inside a bottomed tubular outer tank tank, a bottom tank of the outer tank tank and a bottom of the inner tank, The flock from the inner cylinder water tank is settled in a ring-shaped intermediate region formed between the outer cylinder water tank and the inner cylinder water tank, and the concentrated flocs are discharged from the bottom of the outer cylinder water tank A plurality of flushing means for flushing the ring-shaped intermediate region from the upper end to the lower end of the inner cylinder tank and dividing the ring-shaped intermediate region into a plurality of regions along the circumferential direction; An upper end of the inner cylinder water tank corresponding to one of the plurality of regions divided by the partition plate is disposed in the inner cylinder water tank Is set lower than the upper end.

According to such a solid-liquid separating apparatus, a floc growth zone in which flocs grow due to the rising flow of raw water is formed in the inner cylinder water tank, and flocs grown in the floc growth zone are formed in the inner cylinder water tank So that the one area is settled smoothly downwardly as a floc settling zone and is smoothly carried and deposited on the bottom of the outer tub water tank and the water accompanying the floc is discharged to the bottom of the outer tub water tank The flock is separated from the flock, and the adjacent region divided by one region and the dividing plate smoothly ascends by upward flow and is transported upward as a separated water ascending zone. As described above, the flock is settled downward by a downward flow to be conveyed to the bottom portion of the outer trough, and the separated region separated from the flock is moved upward from the bottom portion of the outer trough by the upward flow, The flocculation of the flocs is prevented by the rising flow or the floc does not rise by the ascending flow. Therefore, the SS concentration of the treated water can be lowered, and the treated water can be further purified .

Here, it is preferable that the lower end of the inner cylinder water tank and the lower end of the partition plate corresponding to one region are extended below the lower end of the inner cylinder water tank of the adjacent region. When adopting such a configuration, the floc settling in one region is divided into a separated water layer rising up to the adjacent region, and a floc which sinks in one region, in that the lower end of the inner cylinder water tank corresponding to one region and the lower end of the partition plate extend below the lower end of the inner cylinder water tank So that the treated water can be further refined.

Example 1

Hereinafter, Example 1 and Comparative Example 1 conducted by the present inventors will be described in order to confirm the above effect. As an empirical test machine, an inner water tank having a diameter of 25 cm and a height of 80 cm was provided in an outer cylinder water tank having a diameter of 30 cm and a height of 160 cm. The test conditions are as follows. (Raw water SS: 107.5 mg / l) mixed with 100 mg / l of kaolin and 50 mg / l of PAC (polychlorinated aluminum) was used as raw water, and 1.5 mg / l of an anionic polymer was added as a coagulating agent. The enemy water passed 640 l / h.

(Example 1)

The SS concentration of the treated water was measured assuming that the coagulating sedimentation apparatus corresponded to the second embodiment in which the intermediate region between the outer cylinder and the inner cylinder was equally divided into four parts by four partition plates.

(Comparative Example 1)

The SS concentration of the treated water was measured by making the coagulated sedimentation apparatus the same as the conventional one in which the intermediate region was not divided by the partition plate.

The SS concentration of the treated water of Example 1 was 1 mg / l, and the SS concentration of the treated water of Comparative Example 1 was 8 mg / l. Thus, it was confirmed that the SS concentration of the treated water was reduced and the treated water was refined. However, in Example 1, the load area (13 m / h) which is 10 times higher than the surface area load factor (1 to 3 m / h) of the cylindrical high-speed coagulating sedimentation apparatus can be taken, Or more.

1, 201, 301 and 401
2, 202, 302, 402 Internal water tanks
3, 303 partition plate
14 Processed water inlet
100 coagulating sedimentation apparatus
200, 300, 400 Solid-liquid separator
The inner cylinder water tank bottom
D2 The inner tank bottom of the adjacent region
Bottom of D3 partition plate
R intermediate area
R1 area (floc settling zone, falling stream)
R2 adjacent region (separable rising zone, rising lean zone)
RD Downstream
RU Rising Upstream
RX Floc Growth Zone
RS separation zone
The upper part of the inner cylinder tank corresponding to the U1-
Above the inner tank of the U2 adjacent region

Claims (10)

There is provided a solid-liquid separating apparatus having a floc growth zone for capturing solid matter in the for-treatment water introduced from the to-be-treated water introducing section and for growing flocs by the for-treatment water ,
A falling-flow zone in which the flock grown in the flock growth zone is lowered in one direction from the flock growth zone,
A separation zone for separating the floc descended from the falling stream from the for-treatment water after passing through the flock growth zone,
The fl owing water in the separation zone is raised,
And,
A first bottom portion and a second bottom portion,
Said separation zone being between said first bottom and said second bottom,
A bottomed tubular inner cylinder tank having the second bottom portion inside a bottomed tubular outer cylinder tank having the first bottom portion and a ring shaped intermediate region between the outer tub water tank and the inner cylinder tank, And,
A plurality of partition plates provided from the upper end to the lower end of the inner cylinder water tank and dividing the ring-shaped intermediate region into a plurality of regions along the circumferential direction,
Liquid separator. The method according to claim 1,
Wherein the upward flow and the downward flow are formed at different positions when viewed from above and below,
And the region on the lower end side of the ascending stream and the region on the lower end side of the descending stream communicate with each other through the separation zone
Liquid separator. The method according to claim 1 or 2,
Wherein the falling stream and the rising stream are separated from each other
Liquid separator. The method according to claim 1,
And the upper end of the inner cylinder water tank corresponding to the lowered stream water separated by the partition plate is set lower than the upper end of the inner cylinder water tank
Liquid separator. The method according to claim 1,
And the lower end of the inner cylinder water tank and the lower end of the partition plate corresponding to the lowered stream water separated by the partition plate are extended downward from the lower end of the upwardly extending inner cylinder water tank
Liquid separator. A solid-liquid separator for solid-liquid separation of solid matters in water to be treated,
A to-be-treated water inlet portion for introducing the for-treatment water,
A flocculation zone forming unit for capturing the solid material in the for-treatment water introduced from the for-treatment water introducing unit to grow as flocs,
A falling flow-forming section for lowering the flock grown in the flock growth zone formation section in one direction from the flock growth zone formation section;
A separation zone forming section for separating the floc descended from the falling-stream forming section from the for-treatment water after passing through the floc growth zone forming section,
In the separation zone forming part, the upward flow-forming part
And,
The downflow-forming portion and the upflow-forming portion are separated from each other,
Wherein a plurality of flow passages extending in the up-and-down direction and constituted by at least one of the down-flow-stream forming portion and the up-flow forming portion are formed on the outer peripheral side of the flock-
The flow-through portion is provided at a position spaced apart from each other in the circumferential direction of the flock growth zone forming portion
Liquid separator. The method of claim 6,
Wherein the upward flow forming portion and the downward flow forming portion are formed at different positions when viewed from the up and down direction,
And the region on the lower end side of the upflow formation portion and the region on the lower end side of the downflow formation portion communicate with each other through the separation zone formation portion
Liquid separator. The method according to claim 6 or 7,
A first bottom portion and a second bottom portion,
Wherein the separation zone forming portion is between the first bottom portion and the second bottom portion
Liquid separator. The method according to claim 6 or 7,
The lower stream forming portion and the upward flow forming portion are spaced from each other
Liquid separator. delete

Images