JP2019155284A - Solid/liquid separation apparatus - Google Patents

Abstract

To provide a solid/liquid separation apparatus that captures solids in discharged water, which can immediately detect a worsening trend of treatment to keep water quality of treated water excellent.SOLUTION: A solid/liquid separation apparatus 100 comprises a treated water introduction part 2, a sludge blanket part 3 that captures solids in treated water separates the solids from the treated water; and a water quality detection part 4. The water quality detection part 4 subjects the solids in the treated water to solid/liquid separation, arranged in an area within 50% or less of a height in a vertical direction from an interface to water level of a clarification layer, on the basis of the interface between the sludge blanket part 3 and the clarification layer formed above the sludge blanket part 3.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a solid-liquid separator.

In general, as one of the means for wastewater treatment, solid-liquid separation treatment for removing impurities such as solid matter in wastewater is performed.
As such a solid-liquid separation process, a process using a solid-liquid separation apparatus that performs coagulation sedimentation by coagulating and precipitating organic substances, suspended substances, etc. as impurities by adding a coagulant to the wastewater. Can be mentioned. For example, a solid-liquid separator having a floc zone type (sometimes called "sludge blanket type" or "flock blanket type") coagulating sedimentation tank in which an inner cylinder for receiving the water to be treated is disposed in the sedimentation tank It has been known.

  Patent Document 1 describes a coagulation sedimentation treatment apparatus that forms a flock blanket layer in a sedimentation tank by injecting an inorganic flocculant and an organic polymer flocculant into raw water (treated water). Patent Document 1 uses the measured values by various measuring instruments (raw water flow meter, interface meter, turbidity meter) provided in the coagulation sedimentation treatment device, and the injection amount of the inorganic coagulant and organic polymer coagulant. A chemical injection control method for determining and injecting an inorganic flocculant and an organic polymer flocculant into raw water is described.

JP-A-2-261505

  In the coagulation sedimentation processing apparatus described in Patent Document 1, a turbidimeter is provided at the upper end of the treated water layer formed above the flock blanket layer in the sedimentation tank. In this way, the turbidity is measured at the upper end of the treated water layer formed above the settling tank, and the injection amounts of the inorganic flocculant and organic polymer flocculant are determined based on the measured values, and the inorganic content relative to the raw water is determined. When chemical injection control for injecting flocculants and organic polymer flocculants is performed, turbidity that is judged to require the addition of flocculants is detected in the treated water layer, so the water quality of the treated water has already deteriorated. Has started, and as a result, there is a problem that the injection of the flocculant is not in time. Therefore, it is required to immediately detect and respond to the deterioration tendency of the processing in the solid-liquid separator.

  An object of the present invention is to provide a solid-liquid separation device capable of immediately detecting a trend of deterioration of treatment and maintaining good quality of treated water in a solid-liquid separation device that captures solid matter in waste water. is there.

As a result of earnestly examining the above problems, the inventor of the present invention, in a solid-liquid separation device including a sludge blanket part, a water quality detection part in the vicinity of the interface between the sludge blanket part and the clarified layer made of treated water formed on the sludge blanket part. The present invention has been completed by finding that it is possible to quickly detect the tendency of deterioration of processing by providing the above.
That is, the present invention is the following solid-liquid separator.

A solid-liquid separation device of the present invention for solving the above-mentioned problem is a solid-liquid separation device for solid-liquid separation of solids in water to be treated, and captures solids in the water to be treated and serves as a flock. Water quality detection comprising a sludge blanket part having a floc growth zone to be grown, a separation zone separating solids formed above the flock growth zone and the treated water, and a water quality detecting part for detecting the quality of the treated water The section is characterized in that it is arranged in an area of 50% or less of the vertical height from the interface to the water surface of the treated water with reference to the interface between the sludge blanket section and the treated water.
The solid-liquid separator of the present invention is a solid-liquid separator having a sludge blanket part, and a water quality detection part is provided in the vicinity of the interface between the sludge blanket part and the clarified layer made of treated water formed above the sludge blanket part. Thereby, the deterioration tendency of the process in a solid-liquid separator can be detected quickly, and the countermeasure for maintaining the quality of treated water satisfactorily becomes possible.

Moreover, as one embodiment of the solid-liquid separator of this invention, a water quality detection part has the characteristic of arrange | positioning between 50-500 mm upper direction from the said interface.
According to this feature, it becomes possible to detect the deterioration tendency of the process in the sludge blanket part with higher accuracy.

Moreover, as one embodiment of the solid-liquid separation apparatus of this invention, it has the characteristics that a water quality detection part is a turbidimeter.
According to this feature, information relating to the floc aggregation state can be obtained as information for determining the tendency of the processing to deteriorate in the sludge blanket section.

Moreover, as one embodiment of the solid-liquid separation device of the present invention, the water quality detection unit is characterized in that the height in the vertical direction is adjustable.
According to this feature, the water quality detection unit can be arranged at an appropriate position according to the height and interface state of the interface between the sludge blanket part and the clarification layer, and highly accurate detection is possible.

Moreover, as one embodiment of the solid-liquid separation apparatus of this invention, it has the characteristic of providing the control part which controls the state of a sludge blanket part based on the result detected by the water quality detection part.
According to this feature, it is possible to improve the treatment capacity by controlling the state of the sludge blanket part based on the information relating to the deterioration tendency of the treatment obtained by the water quality detection part, and to keep the quality of the treated water good. .

Moreover, as one embodiment of the solid-liquid separation apparatus of this invention, a control part has the characteristic of controlling the addition amount of the coagulant | flocculant added to to-be-processed water, or the flow volume of to-be-processed water.
According to this feature, the treatment capacity in the sludge blanket part can be improved, and the quality of the treated water can be kept good.

  ADVANTAGE OF THE INVENTION According to this invention, in the solid-liquid separator which capture | acquires the solid substance in waste_water | drain, the solid-liquid separator which can detect the deterioration tendency of a process immediately and can keep the quality of treated water favorable can be provided. .

It is a schematic explanatory drawing of the solid-liquid separator which concerns on the 1st embodiment of this invention. It is a schematic explanatory drawing of the solid-liquid separator which concerns on the 2nd embodiment of this invention. It is a schematic explanatory drawing of the solid-liquid separator which concerns on the 3rd embodiment of this invention.

  The solid-liquid separation device of the present invention is used for treatment of water to be treated containing solid matter. In particular, it is suitably used for a coagulation sedimentation treatment in which an aggregating agent is added to water to be treated to coagulate and precipitate organic substances.

Hereinafter, embodiments of the solid-liquid separation device according to the present invention will be described in detail with reference to the drawings.
In addition, about the solid-liquid separator described in the following embodiment, a coagulation sedimentation apparatus is demonstrated as an example. However, the following embodiments are merely examples for explaining the solid-liquid separation apparatus according to the present invention, and the solid-liquid separation apparatus according to the present invention is not limited to the coagulation precipitation apparatus.

[First Embodiment]
FIG. 1 is a schematic explanatory diagram of a solid-liquid separation device 100 according to a first embodiment of the present invention.
The solid-liquid separation device 100 according to this embodiment has a coagulation sedimentation tank called a so-called sludge blanket type. In general, a sludge blanket type coagulation sedimentation tank forms a fluidized bed of coagulated flocs by a rising water flow in the tank and allows newly generated flocs to pass through the fluidized tank. At this time, the small flocs are captured and captured by the large flocs in the fluidized bed, and the sedimentation speed is increased. Thereby, the to-be-processed water introduced into the sludge blanket type coagulation sedimentation tank is separated into the treated water and sludge, and each is discharged out of the tank. Hereinafter, the floc is sometimes referred to as agglomerated floc, sludge, or solid matter.

As shown in FIG. 1, the solid-liquid separation device 100 according to this embodiment includes a water to be treated introduction unit 2 that introduces water to be treated W into a coagulation sedimentation tank 1 and solids in the water to be treated W. The sludge blanket part 3 which captures and separates into solid and treated water W1, the water quality detection part 4 of the treated water W1, and the treated water discharge line L1 for discharging the treated water W1 are provided. In addition, the layer which consists of the treated water W1 above the sludge blanket part 3 is called the clarification layer C.
Further, the coagulation sedimentation tank 1 has a concentration section 5 in which flocs aggregated by passing through the sludge blanket section 3 overflow the upper end of the sludge blanket section 3 and precipitate and concentrate on the bottom of the coagulation sedimentation tank 1. And the sludge discharge line L2 which discharges the flock (sludge) settled in the concentration part 5 out of the system is provided. The sludge discharge line L2 may be provided with a sludge treatment facility for treating sludge.

  The coagulation sedimentation tank 1 includes a bottomed cylindrical outer cylinder water tank 11 and a bottomed cylindrical inner cylinder water tank 12 having a smaller diameter and a smaller height than the outer cylinder water tank 11. As shown in FIG. 1, the inner cylinder water tank 12 is erected inside the outer cylinder water tank 11 so as to be concentric with the outer cylinder water tank 11. Moreover, the bottom part of the inner cylinder water tank 12 is spaced apart from the bottom part of the outer cylinder water tank 11 for a predetermined length, and has a double water tank structure. A center shaft 13 that is rotationally driven by a motor M is disposed on the axis L of the outer cylinder water tank 11 and the inner cylinder water tank 12. The center shaft 13 is connected to the bottom of the inner tubular water tank 12 by a rotary joint 14. In addition, the outer cylinder water tank 11 and the inner cylinder water tank 12 are not limited to a cylindrical shape, and may be a rectangular tube shape.

  The treated water introduction unit 2 includes an introduction pipe 21 for introducing the treated water W into the coagulation sedimentation tank 1, and a feed pipe that supplies the treated water W introduced from the introduction pipe 21 into the inner cylindrical water tank 12. 22 is provided. As shown in FIG. 1, the introduction pipe 21 passes through the side wall of the outer tubular water tank 11, protrudes outside the tank, and is connected to a supply source of the water to be treated W. The feed pipe 22 is connected to the introduction pipe 21 so as to allow water to pass therethrough, and is provided outside the center shaft 13 so as to surround the center shaft 13. In the solid-liquid separator according to this embodiment, the outer cylinder water tank 11, the inner cylinder water tank 12, the center shaft 13, and the feed pipe 22 have all the same axis L.

  The feed pipe 22 is divided into an upper part 22a and a lower part 22b in the vertical direction, and the upper part and the lower part are connected by a rotary joint 23 such as a labyrinth structure. An introduction pipe 21 is connected to the side surface of the upper part 22 a of the feed pipe 22, and a dispersion pipe 24 is provided on the lower part 22 b of the feed pipe 22. The dispersion pipe 24 is disposed in the lower part of the inner cylindrical water tank 12 and has a plurality of water discharge ports 24a to be treated. The lower part of the feed pipe 22 rotates with the rotation of the center shaft 13, and at this time, the dispersion pipe 24 rotates with the treated water discharge port 24 a facing the bottom side of the inner cylinder water tank 12. The upper end portion of the feed pipe 22 may be closed or may be opened upward.

  The treated water W introduced from the treated water introduction unit 2 is waste water containing solid matter, and is a mixture of, for example, organic waste water and a flocculant. In this embodiment, in order to mix the organic waste water and the flocculant, FIG. 1 illustrates an example in which the flocculant supply line L3 for supplying the flocculant to the introduction pipe 21 is connected. It is not limited. For example, as will be described later, the water to be treated W obtained by mixing the flocculant with the raw water W0 in advance upstream of the coagulation sedimentation tank 1 may be supplied to the introduction pipe 21.

Examples of the flocculant to be mixed include inorganic flocculants and organic polymer flocculants. The flocculant may use only an inorganic flocculant or an organic polymer flocculant, or may use an inorganic flocculant and an organic polymer flocculant in combination. In addition, when using together an inorganic flocculant and an organic polymer flocculent, it is preferable to add to the to-be-processed water W in order of an inorganic flocculant and an organic polymer flocculent. Thereby, stable flock formation is possible.
Specific examples of the flocculant include, for example, Al-based inorganic flocculants such as sulfuric acid band and PAC, and Fe-based inorganic flocculants such as polyiron sulfate. Alternatively, crystals can be obtained by adding a pH adjuster with an alkali such as NaOH or Ca (OH) ₂ or an acid such as H ₂ SO ₄ or HCl, adding a Ca, Al or Fe compound, or adding an oxidizing agent or a reducing agent. It is good also as what is made to precipitate. Further, as organic polymer flocculants, polyaminoalkyl methacrylate, polyethyleneimine, halogenated polydiallylammonium, chitosan, urea-formalin resin and other cationic polymer flocculants, sodium polyacrylate, polyacrylamide partial hydrolyzate, Anionic polymer flocculants such as partially sulfomethylated polyacrylamide and poly (2-acrylamide) -2-methylpropane sulfate, nonionic polymer flocculants such as polyacrylamide and polyethylene oxide, acrylamide, aminoalkyl methacrylate and acrylic acid Examples include amphoteric polymer flocculants such as sodium copolymer.

The sludge blanket part 3 separates the aggregated floc (solid matter) and the treated water W1 after introducing the treated water W containing the flocculant from the treated water introduction part and growing the aggregated floc.
The separated treated water W1 is discharged out of the system from the treated water discharge line L1 provided in the upper part of the coagulation sedimentation tank 1. Further, the flocs floc overflowed from the upper end of the sludge blanket part 3 settles in the concentrating part 5 provided at the lower part of the sludge blanket part 3 and passes through the sludge discharge line L2 provided at the bottom part of the flocs sedimentation tank 1. It is discharged out of the system.

  As shown in FIG. 1, the sludge blanket portion 3 in the present embodiment indicates an inner region of the bottomed cylindrical inner cylinder water tank 12 in the coagulation sedimentation tank 1. The sludge blanket part 3 has a flock growth zone Z1 and a separation zone Z2 formed above the flock growth zone. The floc growth zone Z <b> 1 forms a fluidized bed of coagulated flocs by the rising water flow of the water to be treated W flowing into the inner cylindrical water tank 12 by the treated water introduction part 2. The separation zone Z2 is for solid-liquid separation of the aggregated floc (solid matter) and the treated water W1.

  The treated water W containing the flocculant is uniformly ejected from the dispersion pipe 24 of the treated water introduction part in the inner cylinder water tank 12 to the lower part in the inner cylinder water tank 12, and the stirring force, shearing force, etc. of this ejected water flow To form a floc. The flocs formed in the inner cylinder water tank 12 accumulate at the bottom of the inner cylinder water tank 12, but a fluidized bed is formed in the flock growth zone Z1 by the treated water W that is further supplied. Small flocs contained in the water to be treated W are captured in contact with the flocs generated earlier in the process of ascending the fluidized bed, so that the particle diameter of the flocs grows large. Thus, the to-be-processed water W grows a floc, raising the floc growth zone Z1.

  Here, since the specific gravity of flocs is greater than that of water, the flocs tend to accumulate at the bottom of the floc growth zone Z1, but rise due to continuous supply of the water to be treated W. In the process in which the water to be treated W rises in the floc growth zone Z1, flocs in the water to be treated W grow and become larger and heavier. Therefore, as shown in FIG. 1, larger and heavier flocs gather in the upper part of the inner cylinder water tank 12, and the ascending force due to the rising flow of the water to be treated W and the sedimentation property (self weight) of the flocs are in an equilibrium state Thus, a virtual boundary layer K in which the floc concentration changes discontinuously is formed. Here, the virtual boundary layer K and the vicinity thereof are defined as a separation zone Z2. In the separation zone Z2, flocs are held at a high concentration. Further, a part of the floc collected in the separation zone Z2 overflows from the upper edge of the inner cylindrical water tank 12 to the outer cylindrical water tank 11 side by the fluidized bed of the water to be treated W. The overflow flocs that flowed over have a specific gravity greater than that of water, and thus settle naturally toward the concentrating part 5 at the bottom of the outer tubular tank 11. The aggregated flocs that have settled and accumulated in the concentration unit 5 are concentrated to become concentrated sludge, and are discharged from a sludge discharge line L <b> 2 provided at the bottom of the outer cylinder water tank 11.

  Further, as shown in FIG. 1, the treated water that has passed through the sludge blanket part 3 rises due to the rising flow of the water to be treated W, and a layer of treated water W1 (clarified layer C) above the sludge blanket part 3. Is formed. That is, the virtual boundary layer K is formed at the boundary between the clarification layer C and the sludge blanket portion 3. The treated water W1 in the clarified layer C is discharged out of the tank via the treated water discharge line L1 provided in the upper part of the outer tubular water tank 11.

  On the other hand, the concentrated sludge accumulated in the concentration unit 5 is scraped by the concentrated sludge scraper 51 provided at the lower end of the center shaft 13 to the center of the bottom surface of the outer tubular water tank 11 provided with the sludge discharge line L2. The concentrated sludge scraper 51 is not particularly limited as long as it has a structure that rotates with the rotation of the center shaft 13 and can scrape the concentrated sludge to the center of the bottom surface of the outer tubular water tank 11. For example, as shown in FIG. 1, in addition to providing a scraping member perpendicular to the center shaft 13, a plurality of scraping members may be provided on a support that intersects the center shaft 13 perpendicularly. The scraping member having a curved surface may be provided on the center shaft 13 so as to form an S shape when viewed from above the tank.

The water quality detection unit 4 is for measuring the quality of the treated water W solid-liquid separated by the sludge blanket unit 3.
Examples of water quality include measurement of turbidity, chromaticity, water temperature, pH, organic substance concentration, and the like. Examples of the detector for detecting the measurement object include a turbidimeter, a chromaticity meter, a water temperature meter, a pH meter, a COD meter, a BOD meter, a TOD meter, and a TOC meter.
As the water quality detection unit 4 in the present embodiment, it is particularly preferable to use a turbidity meter that detects turbidity in order to obtain information on the floc aggregation state in the sludge blanket unit 3 that greatly affects the treatment status. In addition, as a turbidimeter, use a detector based on optical measurement by surface scattering light method, transmission scattering light method, transmission scattering comparison method, etc., or image analysis that analyzes floc aggregation state using camera images. Can do.

Further, the water quality detection unit 4 measures the quality of the treated water in the vicinity of the separation zone Z2 in the sludge blanket unit 3. Thereby, the information for judging the progress state of the process in the sludge blanket part 3 can be obtained, and the deterioration tendency of the process can be detected quickly. Therefore, it is preferable that the water quality detection unit 4 is provided in an area of 50% or less of the vertical height to the water surface of the clarification layer C, based on the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket unit 3. It is particularly preferable to provide in a region of 20% or less.
On the other hand, when the water quality detection unit 4 is arranged in a state where it is substantially in contact with the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket unit 3, It is conceivable that the high-concentration floc contained directly enters the detector of the water quality detection unit 4. At this time, there is a high possibility that detection will be beyond the measurable range of the detector. Therefore, it is preferable to install the water quality detection unit 4 in a region 50 mm or higher above the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket unit 3 as a reference. Further, from the viewpoint of detecting the deterioration tendency of the processing in the sludge blanket part 3, the upper limit position of the water quality detection part 4 is 500 mm or less from the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket part 3. It is preferable to use the region.

  As a specific example of water quality detection, a case where a turbidimeter is used as the water quality detection unit 4 will be described. When a turbidimeter is provided in a region 200 mm above the interface between the virtual boundary layer K and the clarified layer C of the sludge blanket part 3, the measured value of the turbidimeter is several hundred mg / L in a normal processing state. However, when the measured value of the turbidimeter exceeds 1000 mg / L, it can be considered that the flocs are not sufficiently aggregated and the processing efficiency is lowered. In addition, when the turbidimeter contacted the virtual boundary layer K of the sludge blanket part 3, the measured value of the turbidimeter exceeded the measurable range (> 50000 mg / L) and could not be detected.

Furthermore, the water quality detection part 4 arrange | positions the height of a perpendicular direction so that adjustment is possible. The height of the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket portion 3 varies depending on the processing conditions. Therefore, it is preferable to adjust the height of the water quality detection unit 4 according to a change in the height of the interface.
The means for adjusting the height of the water quality detection unit 4 is not particularly limited. For example, a string-like suspension support 41 such as a thread or a chain is directly attached to a detector used as the water quality detection unit 4, or the suspension support 41 is attached to a water permeable container containing a detector. For example, the height of the water quality detection unit 4 can be adjusted by changing the length of the suspension support 41 manually or automatically.
Moreover, the coagulation sedimentation tank 1 of this embodiment is provided with an interface meter for detecting the interface between the virtual boundary layer K and the clarified layer C of the sludge blanket unit 3, and the water quality detection unit 4 The height may be adjustable (not shown). Thereby, highly accurate detection is possible.

  As described above, in the solid-liquid separator 100 according to this embodiment, the water quality detection unit 4 is provided in a specific range in the vicinity of the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket unit 3. It is possible to quickly detect a deterioration tendency of processing in the separation apparatus 100. Thereby, before the water quality of treated water deteriorates, it becomes possible to take measures for maintaining the quality of treated water well.

[Second Embodiment]
FIG. 2 is a schematic explanatory diagram of the solid-liquid separation device 101 according to the second embodiment of the present invention.
As shown in FIG. 2, the solid-liquid separation apparatus 101 according to this embodiment is provided with a reaction tank 6 on the upstream side of the coagulation sedimentation tank 1 in the first embodiment, and adds a flocculant to the reaction tank 6. Addition means 7 is provided. A control unit 8 that controls the flocculant addition means 7 is provided based on the measurement result of the water quality detection unit 4.
In addition, about the structure same as the structure of the solid-liquid separation apparatus 100 of a 1st embodiment among the structures of the solid-liquid separation apparatus 101 in this embodiment, description is abbreviate | omitted.

The reaction tank 6 introduces the raw water W0 and adds a flocculant by the flocculant addition means 7. Thereby, the treated water from the reaction tank 6 is supplied to the coagulating sedimentation tank 1 through the introduction pipe 21 as the water to be treated W containing solid matter.
The reaction tank 6 is composed of one or a plurality of tanks. For example, as shown in FIG. 2, two tanks of a first reaction tank 61 and a second reaction tank 62 are provided, and a flocculant adding means 71 is provided for each. , 72 are provided. At this time, an inorganic flocculant is added to the first reaction tank 61 by the flocculant adding means 71. On the other hand, the organic polymer flocculant is added to the second reaction tank 62 by the flocculant adding means 72. This makes it possible to form a stable coagulation floc in the water to be treated W introduced into the coagulation sedimentation tank 1.
The reaction tank 6 may be provided with a stirring mechanism such as a stirrer. Thereby, it becomes possible to improve the mixing efficiency of raw | natural water and a coagulant | flocculant, and to improve the coagulation effect.

The control unit 8 is for controlling the addition amount of the flocculant by the flocculant addition means 7 based on the measurement result of the water quality detection unit 4. For example, when it is recognized from the measurement result of the water quality detection unit 4 that the floc aggregation state in the sludge blanket unit 3 tends to deteriorate, the addition amount of the flocculant is increased.
The means for controlling the addition amount of the flocculant is not particularly limited. For example, one that controls the opening and closing of a valve provided in the flocculant addition means 7 can be used.

  As described above, in the solid-liquid separation device 101 according to this embodiment, the measurement result of the water quality detection unit 4 provided in a specific range in the vicinity of the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket unit 3 is used. Based on this, the amount of flocculant added is controlled. Thereby, before the quality of treated water deteriorates, it becomes possible to maintain the quality of treated water satisfactorily.

[Third Embodiment]
FIG. 3 is a schematic explanatory diagram of the solid-liquid separation device 102 according to the third embodiment of the present invention.
As shown in FIG. 3, the solid-liquid separation device 102 according to this embodiment is provided with a flow rate adjusting mechanism 9 in the introduction pipe 21 of the coagulation sedimentation tank 1 in the first embodiment. Further, a control unit 80 for controlling the flow rate adjusting mechanism 9 is provided based on the measurement result of the water quality detection unit 4.
Note that, among the configurations of the solid-liquid separation device 102 in this embodiment, the description of the same configurations as those of the solid-liquid separation device 100 of the first embodiment or the solid-liquid separation device 101 of the second embodiment is omitted. To do.

  The flow rate adjusting mechanism 9 is for adjusting the flow rate of the water to be treated W introduced into the coagulation sedimentation tank 1 from the introduction pipe 21. For example, a flow control valve, a valve, etc. are mentioned. Further, the place where the flow rate adjusting mechanism 9 is disposed is not limited to the introduction pipe 21. For example, when the reaction tank 6 is provided on the upstream side of the coagulation sedimentation tank 1, the flow rate adjusting mechanism 9 may be provided in the discharge line from the reaction tank 6.

  The control unit 80 is for controlling the amount of water W to be treated by the flow rate adjusting mechanism 9 based on the measurement result of the water quality detection unit 4. For example, when it is recognized from the measurement result of the water quality detection unit 4 that the floc aggregation state in the sludge blanket unit 3 tends to deteriorate, the flow rate adjusting mechanism 9 of the treated water W introduced into the aggregation sedimentation tank 1 Reduce the flow rate.

  As described above, in the solid-liquid separation device 102 according to the present embodiment, the measurement result of the water quality detection unit 4 provided in a specific range in the vicinity of the interface between the virtual boundary layer K and the clarification layer C of the sludge blanket unit 3 is used. Based on this, the flow rate of the water to be treated W introduced into the coagulation sedimentation tank 1 is controlled. Thereby, before the quality of treated water deteriorates, it becomes possible to maintain the quality of treated water satisfactorily.

  The embodiment described above shows an example of a solid-liquid separator. The solid-liquid separation apparatus according to the present invention is not limited to the above-described embodiment, and the solid-liquid separation apparatus according to the above-described embodiment may be modified without changing the gist described in the claims.

  For example, the solid-liquid separation device of this embodiment uses a double-structure coagulation sedimentation tank composed of an outer cylinder water tank and an inner cylinder water tank, but has a configuration that forms an interface between a sludge blanket part and a clarified layer. If there is no particular limitation. For example, the bottom plate arranged horizontally in the coagulation sedimentation tank and the side wall connected to the peripheral wall of the coagulation sedimentation tank extending upward from a part of the outer peripheral edge of the bottom plate and connected to the peripheral wall of the coagulation sedimentation tank. The floc fluidized bed (sludge blanket part) is formed in the section defined on the inner peripheral side of the water, and the water quality detection part is located near the interface between the sludge blanket part and the clarified layer formed above the sludge blanket part. It is good also as what provides.

  Moreover, although the solid-liquid separation apparatus of this embodiment uses the feed pipe as a to-be-processed water introduction part, if the to-be-processed water can be introduce | transduced in a tank, it will not specifically limit. Without providing the feed pipe shown in this embodiment, the introduction pipe passes through the tank peripheral wall of the outer cylindrical water tank and the tank peripheral wall of the inner cylindrical water tank, and directly introduces the water to be treated into the inner cylindrical water tank. Also good. As a result, the number of parts of the device can be reduced.

  Moreover, the solid-liquid separator of this embodiment is good also as what sends back and circulates a part of sludge discharged | emitted from a sludge discharge line to a coagulation sedimentation tank. Thereby, seed crystals as nuclei on which flocs grow can be supplied to the coagulation sedimentation tank. Growing flocs as large particles using seed crystals as nuclei improves the solid-liquid separation between the solid matter and the treated water in the coagulation sedimentation tank.

  Moreover, the solid-liquid separator of this embodiment is good also as providing a floc extraction part in a sludge blanket part, and returning to the reaction tank provided upstream of the coagulation sedimentation tank or the coagulation sedimentation tank. As a result, flocs grown in the sludge blanket can be circulated, so that the residence time for growing good flocs and the rising flow rate of the water to be treated can be maintained without increasing the capacity of the sludge blanket. And clear treated water can be obtained.

  The solid-liquid separation device of the present invention is used for treatment of water to be treated containing solid matter. In particular, the solid-liquid separation device of the present invention is suitably used as a coagulation sedimentation device that performs coagulation sedimentation treatment by adding a coagulant to the water to be treated.

100, 101, 102 Solid-liquid separation device, 1 coagulation sedimentation tank, 11 outer cylinder water tank, 12 inner cylinder water tank, 13 center shaft, 14 rotary joint, 2 treated water introduction part, 21 introduction pipe, 22 feed pipe, 22a upper part 22b Lower part, 23 Rotary joint, 24 Dispersion pipe, 24a Untreated water discharge port, 3 Sludge blanket part, 4 Water quality detection part, 41 Suspension support, 5 Concentration part, 51 Concentrated sludge scraper, 6, 61, 62 reaction tank, 7, 71, 72 flocculant addition means, 8,80 control unit, 9 flow rate adjusting mechanism, L1 treated water discharge line, L2 sludge discharge line, L3 flocculant supply line, C clarification layer, K virtual boundary layer , L axis, M motor, W treated water, W0 raw water, W1 treated water, Z1 flock growth zone, Z2 separation zone

Claims (6)

A solid-liquid separation device for solid-liquid separation of solids in water to be treated,
A sludge blanket section having a floc growth zone for capturing the solid matter in the introduced water to be treated and growing it as a floc, and a separation zone for separating the solid matter formed above the flock growth zone and the treated water When,
A water quality detection unit for detecting the quality of the treated water;
The water quality detection unit is arranged in an area of 50% or less of a vertical height from the interface to the water surface of the treated water with reference to the interface between the sludge blanket unit and the treated water. , Solid-liquid separator.   The solid-liquid separator according to claim 1, wherein the water quality detection unit is disposed between 50 to 500 mm above the interface.   The solid-liquid separator according to claim 1, wherein the water quality detection unit is a turbidimeter.   The solid-liquid separator according to any one of claims 1 to 3, wherein the water quality detection unit is arranged so that a height in a vertical direction is adjustable.   The solid-liquid separation device according to any one of claims 1 to 4, wherein a control unit that controls a state of the sludge blanket unit is provided based on a result detected by the water quality detection unit. The solid-liquid separation device according to claim 5, wherein the control unit controls an addition amount of a flocculant added to the water to be treated or a flow rate of the water to be treated.

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