JP2020062621A - Stirring tank - Google Patents

Abstract

To provide a stirring tank in which sludge or the like precipitated at a bottom thereof can be stirred.SOLUTION: A stirring tank 2 for stirring received dirty water comprises: a hollow space formation member 7 which extends along a bottom surface 6i formed at a bottom of the stirring tank 2, and has an inlet 7a provided at one end in an extension direction and an outlet 7b provided at the other end in the elongation direction; and a discharge port 81 which discharges a fluid into an internal space S1 defined by an inner face 7i of the space formation member 7. A lower side opening 7d, which is apart from the bottom surface 6i, is formed on a lower side part of the space formation member 7.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a stirring tank for stirring a received liquid.

  In a sewage treatment facility that treats sewage and rainwater and other sewage, aerobic biological treatment is performed to remove nitrogen, phosphorus, and the like from the sewage. Further, in recent years, advanced treatment for efficiently removing nitrogen, phosphorus, etc. by performing anaerobic biological treatment or biological treatment in anoxic state with addition of nitric acid etc. before aerobic biological treatment is also performed. ing. Each biological treatment is performed in a stirring tank having a function of stirring the stored wastewater so that dust and sludge contained in the wastewater do not accumulate at the same position and decompose. Some of the stirring tanks stir the wastewater by discharging a fluid from a discharge port arranged in the stored wastewater to form a circulation flow of the wastewater. Further, in some agitation tanks that perform aerobic biological treatment, there is one that forms a circulating flow of wastewater while mixing air and wastewater by discharging wastewater while supplying air. As a stirring tank for performing such aerobic biological treatment, a discharge port for discharging air and sewage and a cylindrical body having openings at both ends in the discharge direction are installed near the bottom surface of the stirring tank. There is proposed a stirring tank in which the waste water is circulated by the flow of the air and the waste water discharged from the discharge port while mixing the air and the waste water (see, for example, Patent Document 1 and Patent Document 2). In addition to the purpose of biological treatment, the stirring tank may be used for the purpose of mixing two or more kinds of fluids or for uniformly dispersing various powders, chemicals and the like in the fluids.

JP-A-50-98158 Japanese Patent Laid-Open No. 50-107769

  However, in the stirring tank in which the cylindrical body is installed, there is a problem in that the flow of the fluid does not easily enter the gap between the bottom surface of the stirring tank and the cylindrical body, so that a circulation flow is difficult to be formed in the gap. In particular, when sewage and air are discharged from the discharge port, the mixed fluid of air and sewage that has passed through the cylindrical body tends to move upward due to the buoyancy of air contained in the mixed fluid. However, there is a problem that even if a circulating flow is formed, it is difficult to form the circulating flow below the cylindrical body. If the circulation flow is not formed below the cylinder, or if the circulation flow is weak even if it is formed, sludge settled below the cylinder may stay without being stirred and may be decomposed. there were.

  In view of the above circumstances, it is an object of the present invention to provide a stirring tank capable of stirring sludge or the like settled on the bottom.

The stirring tank of the present invention which solves the above object is a stirring tank for stirring the received liquid,
A hollow space extending along the bottom surface formed at the bottom of the stirring tank and having a suction port provided at one end in the extending direction and a discharge port provided at the other end in the extending direction. Members,
A discharge port for discharging a fluid into an internal space defined by the inner surface of the space forming member,
The space forming member is characterized in that a lower side opening separated from the bottom surface is formed in a lower side portion.

  Here, the discharge port may be arranged inside the internal space, or may be arranged outside the internal space. Further, the lower opening may be formed along the extending direction. Further, the lower opening may be formed over the entire length in the extending direction of the space forming member, or may be formed by being divided into a plurality of portions along the extending direction. Good. In addition, the ejection port may eject only liquid or may eject liquid containing bubbles. Further, a second ejection port for ejecting bubbles or a liquid containing bubbles to the internal space may be provided separately from the ejection port. Further, these bubbles may be nanobubbles having a diameter of 1 μm or less. Further, the space forming member may have an arc-shaped cross section. Further, the inner space may have a lower end portion that is connected to the lower opening and is narrowed toward the lower opening.

  According to this agitation tank, the fluid discharged from the discharge port into the internal space is diffused in the radial direction orthogonal to the predetermined direction except the portion where the lower opening is formed, in the space forming member. And a strong flow of fluid is created in the interior space. This flow causes a pressure difference between the inside and the outside of the space forming member, and sludge and the like settled on the bottom of the stirring tank is sucked into the internal space through the lower opening together with the liquid around the lower opening. Then, the sucked sludge or the like moves in the internal space while being mixed with the liquid or the fluid sucked by the flow of the fluid in the internal space, and is discharged from the discharge port together with the liquid or the like. A circulation flow is formed in the stirring tank by the liquid or the like containing the discharged sludge and the sludge circulates in the stirring tank along the circulation flow. Therefore, sludge and the like settled on the bottom of the stirring tank can be surely stirred.

In this stirring tank, a groove provided in the bottom portion and extending in the same direction as the extending direction,
A bottom sloped surface provided on the bottom portion, connected to the edge of the groove, and directed downward toward the edge of the groove;
The lower opening may be arranged in the groove.

  According to this aspect, sludge or the like that is about to settle on the bottom inclined surface easily slides down the bottom inclined surface and easily settles in the groove, so that the sludge and the like can be discharged from the lower opening arranged in the groove. Can be sucked into the internal space. Therefore, it is possible to prevent sludge and the like from settling on the inclined surface of the bottom and staying as it is.

  Further, in this stirring tank, the space forming member may have a shape in which the one end portion gradually expands in a radial direction orthogonal to the extending direction toward the suction port.

  By doing so, a large amount of liquid can be sucked from the suction port, so that a stronger circulating flow can be created. Note that the one end portion does not have to have a shape that spreads in all radial directions, such as a shape that spreads only in the upward direction.

  Further, in this stirring tank, the space forming member may have a shape in which the space is gradually expanded toward the discharge port in a radial direction orthogonal to the extending direction toward the discharge port.

  By doing so, the liquid that has reached the other end portion is discharged from the discharge port while spreading in the radial direction, so that a circulation flow can be formed in a wider range. It should be noted that the other end portion may not have a shape that spreads in all the radial directions, such as a shape that spreads only in the upward direction.

Further, in this stirring tank, the suction port is arranged so as to face the lower end portion of the first wall surface of the stirring tank,
The lower end portion of the first wall surface may have a first inclined surface that approaches the suction port as it goes downward.

  Sludge or the like that tends to settle on the first inclined surface slides down on the first inclined surface and is likely to settle in the vicinity of the suction port. Further, when the fluid is discharged from the discharge port, the flow of the liquid generated in the vicinity of the first inclined surface is directed toward the suction port side along the slope of the first sloped surface, and therefore is deposited in the vicinity of the suction port. The sludge or the like tends to be sucked from the suction port toward the suction port along the liquid flow. Therefore, it is possible to prevent the sludge and the like from settling near the lower end portion of the first wall surface and staying as they are.

Further, in this stirring tank, the discharge port is arranged so as to face the lower end portion of the second wall surface of the stirring tank,
The lower end portion of the second wall surface may have a second inclined surface that approaches the discharge port as it goes downward.

  Since the liquid discharged from the discharge port smoothly rises upward along the second inclined surface, the flow loss is reduced and a stronger circulation flow can be formed above the space forming member. it can.

  According to the present invention, it is possible to provide a stirring tank capable of stirring sludge or the like settled on the bottom.

It is a top view of advanced processing equipment provided with the agitation tank corresponding to one embodiment of the present invention. It is an AA sectional view of the advanced processing equipment shown in FIG. FIG. 1A is an enlarged view showing a portion C of FIG. 1 in an enlarged manner, and FIG. 1B is a sectional view taken along line EE of FIG. FIG. 1A is an enlarged view showing an enlarged part D of FIG. 1, and FIG. 1B is a sectional view taken along line FF of FIG. It is a BB sectional view of the anaerobic tank shown in FIG. It is sectional drawing which shows the aspect corresponding to FIG. 2 in the advanced processing equipment 1 of 2nd Embodiment. 3A is a cross-sectional view showing a modified example of one end portion of the space forming member shown in FIG. 3B, and FIG. 4B is a modified example of the other end portion of the space forming member shown in FIG. 4B. FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The agitation tank which is one embodiment of the present invention is arranged in a sewage treatment facility and performs biological treatment for removing nitrogen, phosphorus and the like from sewage.

  FIG. 1 is a plan view of advanced processing equipment including a stirring tank corresponding to an embodiment of the present invention. In FIG. 1, the high-level processing equipment is shown by omitting the upper part such as the ceiling. Further, FIG. 2 is a cross-sectional view taken along the line AA of the advanced processing equipment shown in FIG. Note that, in FIG. 2, an intermediate portion of a fluid supply pipe described later is shown in a simplified manner.

  As shown in FIG. 1, the advanced treatment facility 1 is a facility having a rectangular shape in a plan view, and includes an anaerobic tank 2 for performing anaerobic biological treatment and an aerobic biological treatment between the left side wall 11 and the right side wall 12. A plurality of aeration tanks 3 are provided. Hereinafter, the lateral direction of the advanced processing equipment 1 (vertical direction in FIG. 1) is referred to as the width direction. The advanced treatment facility 1 is a facility for performing biological treatment on wastewater from which contaminants such as sand have been removed in a wastewater treatment facility. Sewage such as sewage and rainwater treated in a sand basin and a first sedimentation basin, which are not shown, flow into the advanced treatment facility 1. This sewage corresponds to an example of liquid. The advanced treatment equipment 1 receives sewage from the left side in FIG. The sewage received by the advanced treatment facility 1 contains fine dust that cannot be completely removed by a sand basin or the like. In order to perform biological treatment, activated sludge containing a large amount of microorganisms is supplied to the anaerobic tank 2 from a final settling tank (not shown) provided on the downstream side of the advanced treatment facility 1. Hereinafter, the above-mentioned dust and activated sludge are collectively referred to as sludge and the like. The sewage received by the advanced treatment equipment 1 slowly flows toward the right side in FIG. 1 in each of the anaerobic tank 2 and the aeration tank 3 (see the straight line arrow shown in FIG. 1). Hereinafter, the upstream side of the received wastewater flow is simply referred to as the upstream side, and the downstream side of the wastewater flow is simply referred to as the downstream side.

  On the upstream side of the advanced treatment facility 1, eight anaerobic tanks 2 are provided in parallel in the flow direction of the sewage, two rows, four in each row. Each of these anaerobic tanks 2 corresponds to an example of a stirring tank. Further, a total of four aeration tanks 3 are provided on the downstream side of the advanced treatment equipment 1 in parallel with the flow direction of the sewage, in two rows, two in each row. A central wall 13 is formed between each row, and the sewage received by the anaerobic tank 2 and the aeration tank 3 of one row by this central wall 13 flows into the anaerobic tank 2 and the aeration tank 3 of the other row. Is prevented. Partition walls 14 are provided between the anaerobic tanks 2 and between the aeration tanks 3 and between the anaerobic tanks 2 and the aeration tanks 3 in the same row. The partition wall 14 separates the anaerobic tanks 2 from each other, the aeration tanks 3 from each other, and the anaerobic tank 2 and the aeration tank 3 in the same row. However, an inflow opening 14a (see FIG. 2) is formed in the central portion in the width direction of the lower end of the partition wall 14. The sewage received by the most upstream anaerobic tank 2 in each row passes through these inflow openings 14a and flows downstream. The anaerobic tanks 2 and the aeration tanks 3 in each row are formed symmetrically with respect to the central wall 13, and therefore the anaerobic tanks 2 and the aeration tanks 3 in the upper row in FIG. 1 will be described below. The description of the anaerobic tank 2 and the aeration tank 3 in the lower row in FIG. 1 is omitted.

  Each aeration tank 3 has a large number of air diffusers 31 at the bottom thereof. A support 33 is fixed to the bottom surface 32 of the aeration tank 3, and an air pipe 34 is attached to the support 33. Each air diffuser 31 is fixed to its air pipe 34, and air is supplied through this air pipe 34. The air diffuser 31 of the present embodiment is a membrane type air diffuser. However, an air diffuser of another method may be used. The air diffuser 31 is arranged close to the left wall 11 side. In the aeration tank 3, air sent from a blower (not shown) is made into fine bubbles by the air diffuser 31 and blown into the dirty water from the bottom of the aeration tank 3. Since the blown bubbles rise toward the water surface, a force to move the wastewater upward is generated by the air lift effect at this time, and an upward flow of the wastewater is generated on the left side wall 11 side of the aeration tank 3. On the other hand, a downflow occurs on the side of the central wall 13. With these, a circulation flow is formed in the aeration tank 3.

  Each anaerobic tank 2 is provided with a bottom inclined surface 5, a trough 6, a space forming member 7, and a nozzle 8 (see FIG. 3) at the bottom thereof. The nozzle 8 corresponds to an example of a discharge member. The anaerobic tanks 2 from the most upstream to the third are each provided with two troughs 6. The anaerobic tank 2 on the most downstream side includes three troughs 6. The trough 6 is a trough-shaped member extending in the width direction of the advanced treatment equipment 1 from the vicinity of the left side wall 11 to the vicinity of the central wall 13 at the bottom of the anaerobic tank 2. That is, each trough 6 extends in a direction orthogonal to the flow direction of wastewater in the advanced treatment facility 1. Therefore, the width direction of each trough 6 coincides with the flow direction of sewage in the advanced treatment equipment 1. Hereinafter, the width direction of the trough 6 is referred to as the groove width direction. One space forming member 7 and one nozzle 8 are arranged in each trough 6. The trough 6, the space forming member 7, and the nozzle 8 will be described in detail later.

  As shown in FIG. 2, the bottom inclined surface 5 is arranged so as to sandwich the trough 6 on the upstream side of the trough 6 and on the downstream side of the trough 6, respectively. The bottom inclined surface 5 is connected to the edge of the groove 61 (see FIG. 3B) formed by the trough 6. The bottom inclined surface 5 is inclined downward toward the edge of the groove 61. Thereby, a ridge line 51 that is the top of the bottom slope 5 is formed between the adjacent troughs 6. The inclination angle of the bottom inclined surface 5 is 30 degrees with respect to the horizontal. This inclination angle may be 15 degrees or more. When the inclination angle of the bottom inclined surface 5 is 15 degrees or more, sludge and the like settled toward the bottom inclined surface 5 slide down the bottom inclined surface 5 and settle in the groove 61. Further, when the inclination angle is 30 degrees or more, sludge and the like settling toward the bottom inclined surface 5 is more likely to slide down the bottom inclined surface 5, and is accumulated on the bottom inclined surface 5. This is more preferable because it can be reliably prevented. The bottom inclined surface 5 that is in contact with the partition wall 14 is cut at the center portion in the width direction so as not to block the inflow opening 14a. An inflow path surface 52 formed by a horizontal surface extending between the inflow opening 14 a and the groove 61 is provided in the cutout portion.

  Next, the configuration of the trough 6, the space forming member 7, and the nozzle 8 (hereinafter, the space forming member 7 and the nozzle 8 are collectively referred to as a stirring device) will be described with reference to FIGS. 3 to 4. Since the trough 6 and the stirring device provided in each anaerobic tank 2 have the same structure, in the following description, the trough 6 and the stirring device shown in FIG. 2 are provided on the most downstream side. The description of the other troughs 6 and the agitator will be omitted.

  FIG. 3A is an enlarged view showing a portion C of FIG. 1 in an enlarged manner.

  As shown in FIG. 3A, the space forming member 7 is composed of a body portion 70 and one end portion 71. The space forming member 7 is hollow, and one end of the space forming member 7 in the extending direction is open toward the extending direction. This opened portion becomes the suction port 7a. The inner surface S1 (see FIG. 3B) is defined by the inner surface 7i of the space forming member 7. The length of the one end portion 71 in the extending direction (vertical direction in FIG. 3A) is significantly shorter than that of the main body portion 70. The body portion 70 is supported by the support body 65 together with the trough 6. The support body 65 is fixed to the concrete, which is the body of the anaerobic tank 2, by the anchor bolts 21. One end portion 71 of the space forming member 7 is detachably attached to the main body portion 70 with a bolt (not shown). The one end portion 71 has a portion protruding toward one end side from one end of the trough 6. The one end portion 71 of the space forming member 7 has a one end side small diameter portion 711 connected to the main body portion 70, one end side enlarged diameter portion 712, and one end side large diameter portion 713. The one end side small diameter portion 711 has the same cross-sectional shape as the main body small diameter portion 701 described later, and extends along the extending direction so as to be continuous with the main body portion 70 (main body small diameter portion 701). The one end-side expanded diameter portion 712 has a shape that gradually expands in the radial direction orthogonal to the extending direction of the space forming member 7 as it approaches the suction port 7a. The one end side large diameter portion 713 is a portion located closer to the suction port 7a side than the one end side enlarged diameter portion 712, and extends in parallel along the extending direction. The suction port 7a is defined by the large diameter portion 713 on the one end side. Note that the suction port 7a may be defined by one end of the one end side enlarged diameter portion 712 without providing the one end side large diameter portion 713. A pair of support pieces 77 protruding toward the center in the groove width direction are provided inside the large diameter portion 713 on the one end side.

  The nozzle 8 is formed by flattening the tip of a round pipe. A discharge port 81 is formed at the tip of the nozzle 8. The dirty water supplied from the fluid supply pipe 9 is discharged from the discharge port 81. The dirty water discharged from the discharge port 81 corresponds to an example of a fluid. As described above, since the nozzle 8 is formed by crushing a round pipe into a flat shape, it is possible to increase the discharge pressure of dirty water that passes through the nozzle 8 and is discharged from the discharge port 81. Further, since the nozzle 8 can be manufactured only by crushing the round pipe, it is easy to manufacture. A nozzle flange 8a is welded to the rear end of the nozzle 8. A pipe flange 9a is welded to the tip of the fluid supply pipe 9. The nozzle flange 8a and the pipe flange 9a are connected by a bolt (not shown). As a result, the nozzle 8 is detachably attached to the fluid supply pipe 9. Two mounting pieces 83, which respectively project outward in the groove width direction, are fixed to the nozzle 8. The mounting piece 83 is coupled to the support piece 77 of the space forming member 7 with the bolt 95 (see FIG. 3B), so that the nozzle 8 is detachably attached to the space forming member 7. When the connection between the nozzle flange 8a and the pipe flange 9a is released and the connection between the one end portion 71 of the space forming member 7 and the main body portion 70 is released, the nozzle portion 8 together with the one end portion 71 from the main body portion 70 and the fluid supply pipe 9 is released. Can be removed. After that, if the bolt 95 connecting the one end portion 71 and the nozzle 8 is removed, the nozzle 8 alone can be taken out. As a result, for example, when the nozzle 8 is clogged with water stains or sludge, maintenance work such as removing the water stains or sludge can be easily performed.

  The nozzle 8 is held by a support piece 77 formed on the space forming member 7 in a state where the discharge direction of the dirty water discharged from the discharge port 81 and the extending direction of the space forming member 7 are substantially aligned with each other. Further, the tip end side of the nozzle 8 enters into the internal space S1 (see FIG. 3B) formed by the space forming member 7 from the suction port 7a. Therefore, the discharge port 81 is arranged in the internal space S1. That is, the ejection port 81 is formed at the tip end portion of the nozzle 8 that enters the internal space S1 from the suction port 7a of the space forming member 7. As a result, all the dirty water discharged from the discharge port 81 can be discharged into the internal space S1. However, the discharge port 81 does not have to enter the internal space S1 as long as the waste water can be discharged into the internal space S1, and for example, is the same as the suction port 7a on the surface formed by one end of the space forming member. It may be arranged in a position. If the discharge port 81 is arranged at a position outside the inner space S1 and far from the inner space S1, there is a possibility that part of the wastewater discharged toward the inner space S1 may not flow into the inner space S1. It is desirable that the discharge port 81 is arranged in the internal space S1 or close to the suction port 7a.

  FIG. 3B is a sectional view taken along line EE of FIG. In FIG. 3B, in order to make the drawing easy to see, the large-diameter portion on one end side is shown smaller. Further, in FIG. 3B, the nozzle flange and the pipe flange are not shown.

  As shown in FIG. 3B, the trough 6 is formed by bending a stainless steel plate material so that the cross section has an arc shape with the trough center 6c as the center point. A groove 61 is formed in the bottom of the anaerobic tank 2 by the trough 6. In other words, the groove 61 is defined by the inner surface 6i of the trough 6. The trough 6 may be made of concrete or may be made of another material such as resin. Moreover, the cross-sectional shape of the trough 6 is not limited to the arc shape, and may be a U shape, a V shape, or the like. The trough 6 of the present embodiment has a shape in which an upper third of a cylindrical body having an inner diameter of 300 mm is cut out, and is open upward. The upper end side of the groove 61 connected to the opening of the trough 6 becomes narrower as it approaches the opening.

  The space forming member 7 extends along the inner surface 6i reference of the trough 6. Therefore, the space forming member 7 extends in the direction orthogonal to the flow direction of the wastewater in the advanced treatment equipment 1. If the extending direction of the space forming member 7 is made parallel to the flow direction of the sewage, when the sewage is discharged from the discharge port 81, a circulation flow is formed in the flow direction of the sewage in the advanced treatment facility 1, so the sewage is discharged. May be moved to the anaerobic tank 2 or the aeration tank 3 on the downstream side more than necessary. It is desirable that the extending direction of the space forming member 7 in a plan view has an angle with respect to the flow of dirty water of 30 degrees or more and 150 degrees or less. The body portion 70 and the one end portion 71 of the space forming member 7 are formed by bending a stainless steel plate material so as to have an arc-shaped cross section. A lower opening 7d that opens downward is formed in the lower portion of the space forming member 7. The radial center in the cross section of the space forming member 7 coincides with the trough center 6c which is the radial center of the trough 6. Hereinafter, the radial center of the space forming member 7 in the cross section is simply referred to as the center of the space forming member 7. The center of the space forming member 7 may be arranged at a position different from the trough center 6c, but it is preferably arranged so that the lower opening 7d is located below the opening of the trough 6. The center of the discharge port 81 also coincides with the trough center 6c. By matching the center of the space forming member 7 with the center of the discharge port 81, it is possible to prevent the wastewater discharged from the discharge port 81 from colliding with the inner surface 7i of the space forming member 7 and weakening the flow. it can. However, the center of the space forming member 7 and the center of the ejection port 81 may be arranged at different positions. For example, the center of the ejection port 81 may be arranged below the center of the space forming member 7 and above the lower opening 7d. With this arrangement, the force of sucking sewage, settled sludge, and the like, which will be described later, from the lower opening 7d into the internal space S1 can be increased. That is, it is desirable that the center of the ejection port 81 is disposed between the center of the space forming member 7 and the lower opening 7d of the space forming member 7.

  The space forming member 7 partitions the inside of the groove 61 and forms an internal space S1. The internal space S1 is a space in which a portion above the lower end is closed. The body portion 70 of the space forming member 7 is composed of a body small diameter portion 701 and another end side enlarged diameter portion 702 (see FIG. 4) described later. The main body small diameter portion 701 and the one end side small diameter portion 711 have a 5/6 arc cross-sectional shape in which a lower end portion of a cylindrical body having an inner diameter of 150 mm is cut. Further, the lower end of the one end side small diameter portion 711, the lower end of the one end side enlarged diameter portion 712, and the lower end of the one end side large diameter portion 713 are at the same position in the height direction. That is, the one end portion 71 has a shape in which the entire lower end is horizontally cut. As a result, the one end side large diameter portion 713 has a cross-sectional shape of about 2/3 arc in which the lower end portion of the cylindrical body having an inner diameter of 300 mm is cut. The suction port 7a (see FIG. 3A) has a circular shape with a diameter of 300 mm, which is formed in a portion surrounded by one end of the one end side large diameter portion 713 and has a lower end portion cut off. The lower opening 7d formed in the lower end portion of the space forming member 7 acts as a suction port for sucking the dirty water in the groove 61, the settled sludge and the like into the internal space S1. The lower opening 7d is formed in the entire area of the space forming member 7 in the extending direction. Therefore, the lower opening 7d is also formed in the one end side enlarged diameter portion 712 and the one end side large diameter portion 713. Although there may be a part where the lower opening 7d is not formed in a part of the space forming member 7 in the extending direction, sewage and settled sludge cannot be sucked into the internal space S1 at that part, and settled sludge and the like. Therefore, it is desirable that the lower opening 7d be formed over the entire area in the extending direction. The lower opening 7d formed in the main body small diameter portion 701 and the one end portion 71 is formed to have a length of 80 mm in the groove width direction. The lower opening 7d of the one end side large diameter portion 713 is formed to have a length of about 270 mm in the groove width direction. The lower opening 7d is disposed in the groove 61 except for both end portions where the space forming member 7 projects from the groove 61 in a plan view. Therefore, the lower opening 7d is arranged below the upper edge of the groove 61. The lower opening 7d is separated from the inner surface 6i of the trough 6. Specifically, the lower opening 7d is arranged at a position where the distance in the height direction from the lowermost portion 6b of the inner surface 6i of the trough 6 is 84 mm. The distance in the height direction from the lowermost portion 6b to the lower opening 7d is preferably 40 mm or more and 200 mm or less. If it is less than 40 mm, the gap between the edge of the lower opening 7d and the trough 6 becomes too narrow, and a large amount of dust that has passed through the sand basin or the like for some reason may be clogged in the gap. On the other hand, if it is 200 mm or more, the lowermost portion 6b and the lower opening 7d are too far apart from each other, so that sludge and the like settled in the vicinity of the lowermost portion 6b cannot be sucked into the internal space S1 from the lower opening 7d. The relative position of the space forming member 7 with respect to the trough 6 in the height direction may be adjustable. By allowing the position of the space forming member 7 in the height direction to be adjustable, the space forming member 7 can be arranged at an optimum position corresponding to the wastewater treatment facility. The inner surface 6i of the trough 6, the inflow path surface 52, and the bottom inclined surface 5 (see FIG. 2) correspond to an example of a bottom surface. Since the outer surface of the space forming member 7 is arcuate, the upper part of the center of the circle having the arc as a part of the circumference is inclined downward toward the groove width direction outer side. Therefore, sludge settled toward the outer surface of the space forming member 7 easily slides down toward the bottom of the groove 61 along the outer surface of the upper portion of the space forming member 7. By this. It is possible to suppress the accumulation of sludge or the like on the upper portion of the space forming member 7. In addition, the lower portion of the internal space S1 connected to the lower opening 7d is narrowed by the lower portion of the space forming member 7 as it approaches the lower opening 7d. Therefore, sludge and the like once sucked into the internal space S1 are less likely to leak from the internal space S1.

  FIG. 4A is an enlarged view showing an enlarged part D of FIG. 1, and FIG. 4B is a sectional view taken along line FF of FIG. 4A. In FIG. 4B, the outer diameter of the discharge port is shown small in order to make the drawing easy to see.

  As shown in FIG. 4A, the other end portion of the space forming member 7 further projects from the other end of the trough 6 to the other end side. The other end of the space forming member 7 in the extending direction is open in the extending direction. This opened portion becomes the discharge port 7b. On the other end portion of the space forming member 7, there is formed the other end side enlarged diameter portion 702 having a shape gradually expanding in a radial direction orthogonal to the extending direction of the space forming member 7 toward the discharge port 7b. The other end side enlarged diameter portion 702 is formed symmetrically with the one end side enlarged diameter portion 712 with a plane orthogonal to the extending direction of the space forming member 7 as a plane of symmetry. Therefore, as shown in FIG. 4B, the discharge port 7b has a circular shape with a diameter of 300 mm, which is formed in a portion surrounded by the other end of the other end-side expanded diameter portion 702 and whose lower end portion is missing. There is. That is, the discharge port 7b has the same shape as the suction port 7a.

  FIG. 5 is a BB sectional view of the anaerobic tank shown in FIG. In FIG. 5, the intermediate portion of the fluid supply pipe is shown in a simplified manner.

  As shown in FIG. 5, the suction port 7 a faces the lower end portion of the left wall surface 111 which is the inner side surface of the left side wall 11. The left wall surface 111 corresponds to an example of the first wall surface. The discharge port 7b faces the lower end portion of the central wall surface 131 which is the left side surface of the central wall 13. The central wall surface 131 corresponds to an example of the second wall surface. At the lower end portion of the left wall surface 111, a first inclined surface 111a is formed which approaches the suction port 7a as it goes downward. The sludge that has settled toward the first inclined surface 111a slides down the first inclined surface 111a due to the inclination and settles in the vicinity of the suction port 7a. When sewage is discharged from the discharge port 81, in the vicinity of the first inclined surface 111a, the suction port 7a side is formed along the inclination of the first inclined surface 111a, as indicated by the arc-shaped arrow in the lower right of FIG. A flow of sewage toward the water is generated. Due to the flow of the dirty water, sludge and the like settled in the vicinity of the suction port 7a moves toward the suction port 7a side. Due to this flow and the ejector effect of the space forming member 7, the settled sludge or the like is sucked into the internal space S1 (see FIG. 3B) in the space forming member 7, so that the sludge or the like is generated near the lower end portion of the left wall surface 111. It can be prevented from precipitating and staying as it is. Although the first inclined surface 111a of the present embodiment has a circular arc shape that is recessed downward, it may have a planar shape.

  At the lower end of the central wall surface 131, a second inclined surface 131a is formed which approaches the discharge port 7b as it goes downward. When sewage is discharged from the discharge port 81, sewage is discharged from the discharge port 7b. The sewage discharged from the discharge port 7b smoothly rises upward along the second inclined surface 131a as indicated by the arc-shaped arrow at the lower left of FIG. A strong circulation flow is formed above the member 7. The second inclined surface 131a may be planar. However, by forming the second inclined surface 131a in an arc shape that is recessed downward, the flow of the sewage discharged from the discharge port 7b in a generally horizontal direction can be made smoother than in the case of being flat. Since it can be converted upward, there is an effect that the loss of the flow can be made smaller than that of the flat shape.

  The fluid supply pipe 9 extends upward from the bottom of the anaerobic tank 2 along the left wall surface 111. A flow rate adjusting valve 91 and a motor-operated valve 92 are installed on the upper end side of the fluid supply pipe 9. The fluid supply pipe 9 above the flow rate adjusting valve 91 is not shown in FIG. The fluid supply pipe 9 is connected to a pump (not shown) arranged in the advanced processing equipment 1. By opening the motor-operated valve 92, the dirty water sucked up by a pump (not shown) is supplied to the nozzle 8 through the fluid supply pipe 9, and the dirty water is discharged from the discharge port 81 provided in the nozzle 8. It should be noted that, like the inflow opening 14a, two upper inlets 14b through which dirty water can pass are provided in the upper portion of the partition wall 14.

Next, the action when the dirty water is discharged from the discharge port 81 will be described mainly with reference to FIGS. 3 and 5. In the anaerobic tank 2, sewage is always discharged from the discharge port 81 except for a special situation such as maintenance. In the present embodiment, the discharge pressure of the waste water discharged from the discharge port 81 is 0.09 MPa, and the discharge water amount is 1.5 m ³ / min. However, as described later, the discharge pressure may be 0.001 MPa or more, and the discharge water amount may be 0.3 m ³ / min or more. In addition, the discharge flow velocity of sewage is preferably 2 m / sec or more and 32 m / sec or less. If the discharge flow velocity is less than 2 m / sec, the circulation flow in the anaerobic tank 2 formed by the sewage discharged from the discharge port 7b is weak and there is a possibility that sludge or the like cannot be circulated. If the discharge flow velocity exceeds 32 m / sec, the flow of the circulating flow becomes too strong, and the air is entrained on the water surface and the air is supplied to the dirty water. The discharge of sewage into the internal space S1 from the discharge port 81 causes a flow of sewage into the internal space S1. At that time, due to the flow of the dirty water flowing in the internal space S1, a pressure difference due to the flow of the dirty water is generated between the inside of the internal space S1 and the outside of the internal space S1. That is, a negative pressure is generated in the internal space S1 in which the flow of dirty water is generated. The sludge and the like settled in the groove 61 are sucked into the internal space S1 from the lower opening 7d by negative pressure as shown by the curved arrow in FIG. In order to obtain the negative pressure necessary for sucking sludge or the like, it is preferable that the flow rate of the wastewater flowing in the internal space S1 is 0.1 m / sec or more. Further, the wastewater discharged from the discharge port 81 is prevented from diffusing in the radial direction orthogonal to the extending direction of the space forming member 7 by the space forming member 7, so that the flow is maintained in the internal space S1 over a long distance. To be done. The sewage and sludge sucked into the internal space S1 move toward the discharge port 7b side while being mixed with the sewage due to the flow of the sewage generated in the internal space S1, and are discharged from the discharge port 7b. If the discharge pressure is less than 0.001 MPa, sludge or the like moving in the internal space S1 is likely to leak and fall from the lower opening 7d. Similarly, when the discharge water amount is less than 0.3 m ³ / min, sludge or the like moving in the internal space S1 is likely to leak from the lower opening 7d. In consideration of pump capacity and power consumption, the discharge pressure is preferably 0.3 MPa or less, and the discharge water amount is preferably 3.0 m ³ / min or less. As described above, the sewage discharged from the discharge port 7b smoothly rises upward along the second inclined surface 131a and forms a strong circulation flow above the space forming member 7.

  According to this embodiment, by discharging the sewage from the discharge port 81 into the internal space S1, the sludge and the like settled in the groove 61 is sucked into the internal space S1 and moved while being stirred, and discharged from the discharge port 7b. You can Then, the sewage mixed with sludge or the like, which is discharged from the discharge port 7b, can be put on the circulation flow and circulated in the anaerobic tank 2. Therefore, sludge and the like settled in the groove 61 can be stirred.

  Next, the anaerobic tank 2 of the second embodiment will be described. In the following description, the components having the same names as those of the components described above will be denoted by the reference numerals used so far, and redundant description may be omitted.

  FIG. 6 is a sectional view similar to FIG. 2 in the advanced processing equipment 1 of the second embodiment. In FIG. 6, the left side of the figure is the upstream side and the right side is the downstream side.

  The advanced treatment equipment 1 shown in FIG. 6 differs from the advanced treatment equipment 1 shown in the previous embodiment in the shape of the bottom of the anaerobic tank 2. As shown in FIG. 6, in the anaerobic tank 2, the bottom inclined surface 5 and the trough 6 are not formed in the bottom portion, but the bottom surface 50 formed of a flat surface is formed in the bottom portion. Further, in this embodiment, more space forming members 7 are arranged than in the previous embodiment. Specifically, the anaerobic tanks 2 from the most upstream to the third are provided with three space forming members 7, respectively. The anaerobic tank 2 on the most downstream side includes five space forming members 7. The lower opening 7d of the space forming member 7 is separated from the bottom surface 50. Specifically, the lower opening 7d is arranged at a position where the distance from the bottom surface 50 in the height direction is 84 mm. For the same reason as in the previous embodiment, the distance between the lower opening 7d and the bottom surface 50 in the height direction is preferably 40 mm or more and 200 mm or less. Each space forming member 7 is provided with a discharge port 81 for discharging a fluid into the internal space S1.

  Also in the anaerobic tank 2 of this embodiment, by discharging dirty water from the discharge port 81, a circulation flow is formed above the space forming member 7. The sludge accumulated below the space forming member 7 and in the vicinity of the space forming member 7 is discharged from the lower opening 7d into the internal space S1 by negative pressure as shown by the curved arrow in FIG. Is sucked into. Then, the sucked sludge and the like circulate along the circulation flow formed above. However, if the space between the adjacent space forming members 7 is wide, sludge and the like settled on the bottom surface 50 at the intermediate position between the adjacent space forming members 7 may remain deposited. As a measure against this, by arranging a large number of space forming members 7 as described above, the space between the adjacent space forming members 7 is narrowed, and the sludge or the like settled on the bottom surface 50 at the intermediate position remains deposited. It prevents it from becoming. Instead of increasing the number of the space forming members 7, the linear motion mechanism that moves the space forming members 7 and the discharge port 81 in the flow direction of the dirty water by an electric motor such as a motor may be provided. When the direct-acting mechanism is provided, it is preferable to perform an operation of moving the space forming member 7 together with the discharge port 81 from the vicinity of the upstream end of the anaerobic tank 2 to the vicinity of the downstream end while discharging the dirty water from the discharge port 81. Further, a rotation mechanism that rotates the space forming member 7 along the bottom surface 50 by an electric motor may be provided around the center portion of the space forming member 7 in the extending direction. When this rotation mechanism is provided, it is preferable to perform an operation of rotating the space forming member 7 in parallel with the bottom surface 50 while discharging the dirty water from the discharge port 81. In this operation, the space forming member 7 is preferably rotated clockwise and counterclockwise by an angle of less than 150 degrees. If it is rotated 150 degrees or more, a circulation flow is formed in the flow direction of the wastewater, and the wastewater may be moved to the downstream anaerobic tank 2 or aeration tank 3 more than necessary. According to the aspect in which the linear movement mechanism or the rotation mechanism is provided, the entire bottom surface 50 of the anaerobic tank 2 can be covered with the single space forming member 7, and therefore one space forming member 7 is provided for each anaerobic tank 2. All the sludge and the like accumulated on the bottom surface 50 can be sucked up and stirred simply by arranging them. According to this embodiment, sludge and the like settled on the bottom surface 50 can be stirred even if the bottom inclined surface 5 and the trough 6 are not formed in the anaerobic tank 2.

  Next, the modified example of the anaerobic tank 2 described above will be described focusing on the points different from the configuration described above.

  FIG. 7A is a sectional view showing a modified example of one end portion of the space forming member shown in FIG. 3B.

  As shown in FIG. 7A, in the space forming member 7 of this modified example, the one end side enlarged diameter portion 712 and the one end side large diameter portion 713 are grooved as compared with the space forming member 7 shown in FIG. The difference is that the support piece 77 and the mounting piece 83 are not provided in the width direction. That is, the one end side enlarged diameter portion 712 and the one end side large diameter portion 713 are shaped so as to be expanded only upward with respect to the one end side small diameter portion 711. Inside the one end side large diameter portion 713, a support piece 77 protruding downward from the upper end portion is provided. Further, a mounting piece 83 protruding upward from the upper end portion is fixed to the nozzle 8. The mounting piece 83 is coupled to the support piece 77 by the bolt 95, so that the nozzle 8 is detachably attached to the one end portion 71 of the space forming member 7.

  FIG. 7B is a cross-sectional view showing a modified example of the other end portion of the space forming member shown in FIG. 4B.

  As shown in FIG. 7B, in the space forming member 7 of this modified example, the other end side expanded diameter portion 702 is not expanded in the width direction as compared with the space forming member 7 shown in FIG. Is different. That is, the other end side expanded diameter portion 702 has a shape expanded only upward with respect to the main body small diameter portion 701. In this modification, the large diameter portion 713 on the one end side is expanded only upward. Therefore, when sewage is discharged from the discharge port 81, a stronger circulation flow is easily formed above the space forming member 7.

  The present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the claims. For example, in the present embodiment, the stirring tank of the present invention is applied to the anaerobic tank 2, but it may be applied to the aeration tank 3 or the anoxic tank. When applied to the aeration tank 3, another discharge port for supplying dirty water containing air or bubbles is provided around or in the vicinity of the discharge port 81, or air or bubbles is added to the dirty water in the middle of the fluid supply pipe 9. The liquid may be discharged from the discharge port 81. In this case, the bubbles are preferably nanobubbles having a diameter of 1 μm or less. Nanobubbles can supply oxygen efficiently to aerobic bacteria because they have a large total surface area as compared to large-diameter bubbles of the same volume. Further, since the nano bubbles have almost no buoyancy, they can circulate in the aeration tank 3 for a long time. When applied to the aeration tank 3, the flow rate of sewage flowing in the internal space S1 of the aeration tank 3 may be faster than the flow rate of sewage flowing in the internal space S1 of the anaerobic tank 2. When the flow velocity of the sewage flowing in the internal space S1 becomes faster, the flow of the circulation flow becomes stronger and air may be entrained on the water surface to supply the sewage with the air, but it is preferable that the aeration tank 3 is supplied with the air. Because. In other words, the flow velocity of the sewage flowing in the internal space S1 of the anaerobic tank 2 is preferably equal to or lower than the flow velocity of the sewage flowing in the internal space S1 of the aeration tank 3. When applied to an oxygen-free tank, a device for adding nitric acid or the like may be placed in the tank. Furthermore, the stirring tank of the present invention may be used in a facility other than the sewage treatment facility, such as a tank for mixing two or more kinds of fluids and a tank for uniformly dispersing various powders and chemicals in the fluids. .

  According to the above-described embodiments and modifications, the sludge and the like settled on the bottom can be agitated between the sludge and the like by moving the sludge and the like together with the sewage into the internal space S1.

  In addition, even if the constituent requirements are included only in the description of each of the embodiment and each modification described above, the constituent requirements may be applied to another embodiment or another modification.

1 Advanced treatment equipment 2 Anaerobic tank 6 Trough 6i Inner surface 7 Space forming member 7a Suction port 7b Discharge port 7d Lower opening 50 Bottom 81 Discharge port S1 Internal space

Claims (6)

A stirring tank for stirring the received liquid,
A hollow space extending along the bottom surface formed at the bottom of the stirring tank and having a suction port provided at one end in the extending direction and a discharge port provided at the other end in the extending direction. Members,
A discharge port for discharging a fluid into an internal space defined by the inner surface of the space forming member,
The agitation tank, wherein the space forming member has a lower opening formed in a lower portion thereof and spaced from the bottom surface. A groove provided in the bottom portion and extending in the same direction as the extending direction,
A bottom sloped surface provided on the bottom portion, connected to the edge of the groove, and directed downward toward the edge of the groove;
The stirring tank according to claim 1, wherein the lower opening is arranged in the groove.   The agitation tank according to claim 1 or 2, wherein the space forming member has a shape in which the one end portion gradually expands in a radial direction orthogonal to the extending direction toward the suction port. .   The space forming member has a shape in which the other end portion has a shape that gradually expands in a radial direction orthogonal to the extending direction toward the discharge port. The stirring tank as described in 1 above. The suction port is arranged so as to face the lower end portion of the first wall surface of the stirring tank,
The stirring tank according to any one of claims 1 to 4, wherein a lower end portion of the first wall surface has a first inclined surface that approaches the suction port as it goes downward. The discharge port is arranged so as to face the lower end portion of the second wall surface of the stirring tank,
The stirring tank according to any one of claims 1 to 5, wherein a lower end portion of the second wall surface has a second inclined surface that approaches the discharge port as it goes downward.