JP2007229708A - Filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a superior filter capable of reducing occurrence of channeling or clogging, by mixing and agitating suspension. <P>SOLUTION: Filter vessels 11, 12, 13 have structure wherein filtrate of suspension injected from inlets 11a, 12a, 13a is discharged from filter vessel side wall parts 11b, 12b, 13b, and suspension with particles substantially in a dispersed state is discharged from filter vessel discharge ports 11c, 12c, 13c. A first suspension storing part 14 storing suspension is provided between the filter vessel discharge port 11c of an upper stage group and the filter vessel inlet 12a of a middle stage group. A second suspension storing part 15 storing suspension is provided between the filter vessel discharge port 12c of the middle stage group and the filter vessel inlet 13a of a lower stage group. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a suspension filtration apparatus, and in particular, is an apparatus suitable for concentrating and filtering a large amount of suspension continuously.

Conventionally, a flocculant has been added in the solid-liquid separation operation. However, the moisture content of the cake is increased by the addition of the flocculant, which places a heavy load on the transportation / drying process following filtration. The inventor has demonstrated that a slurry concentrated to a higher concentration than the filter cake can be continuously discharged by gravity or centrifugal force by adding a dispersant instead of the flocculant. (Patent Document 1)
JP 2005-66384 A

However, the apparatus of Patent Document 1 has a problem that channeling (short circuit) and blockage are likely to occur because there is no region for mixing and stirring the suspension while the particle suspension flows from the inlet to the outlet. .
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an excellent filtration device that can reduce the occurrence of channeling and blockage by mixing and stirring a suspension. To do.

According to the filtering device of the first aspect of the present invention, the suspension filtrate injected from the filter container inlet is discharged from the filter container side wall, and the suspension in which the particles are substantially dispersed is filtered. A filtration device in which a plurality of filter containers discharged from a container discharge port are arranged in a vertical direction, and a suspension is stored between an outlet of the upstream filter container and an inlet of the downstream filter container. A suspension storage unit is provided.
In such a filtering device, the suspension reservoir between the upstream filter container outlet and the downstream filter container inlet promotes mixing and stirring of the suspension.

According to the filtering device of the invention of claim 2, in the filtering device of claim 1, a plurality of the upstream filter containers are arranged in the lateral direction, and a plurality of downstream filter containers are arranged in the lateral direction. The position of the upstream filter container is shifted in the lateral direction from the position of the downstream filter container.
In such a filtration device, the position of the upstream filter container is shifted laterally from the position of the downstream filter container. Agitation is promoted.

According to the filtering device of the third aspect of the present invention, the suspension filtrate injected from the filter container inlet is discharged from the filter container side wall, and the suspension in which the particles are substantially dispersed is filtered. A filtration device in which a plurality of filter containers discharged from a container discharge port are arranged in a vertical direction, wherein the filtrate is discharged from the upstream side of the filter container and the downstream side of the filter container. The upstream filter container and the downstream filter container are arranged so that the filtrate discharge direction intersects.
In such a filtering device, the upstream filter container and the filtrate discharge direction discharged from the upstream filter container side wall and the filtrate discharge direction discharged from the downstream filter container side wall intersect each other. Since the downstream filter container is disposed, a deviation occurs in the flow path of the suspension, facilitating the mixing and stirring of the suspension.

According to the filtration device of the invention of claim 4, the suspension filtrate injected from the filter container inlet is discharged from the filter container side wall, and the suspension in which the particles are substantially dispersed is filtered. A filtration device in which a plurality of filter containers discharged from a container discharge port are connected in the vertical direction, the discharge direction of the particles in the upstream filter container, and the discharge direction of the particles in the downstream filter container Are formed so that the particle discharge passages of the upstream and downstream filter containers are formed so as to intersect with each other.
In such a filtering device, the particles in the upstream and downstream filter containers are crossed so that the discharge direction of the particles in the upstream filter container intersects the discharge direction of the particles in the downstream filter container. Since the discharge path is formed, a deviation occurs in the flow path of the suspension, facilitating the mixing and stirring of the suspension.

According to the present invention, the occurrence of channeling and blockage can be reduced by mixing and stirring the suspension. Further, since there are no movable parts, channeling and blockage can be prevented with a simple structure.
In addition, the apparatus can be unitized and can flexibly cope with the processing amount and suspension concentration. In addition, if basic data is taken for a single unit, the device can be easily designed.

First, the background to the present invention will be described.
Conventionally, in these solid-liquid separation operations, a flocculant is added, and the quality of the flocculant has a dominant influence on the separation performance and efficiency. The flocculant is added to increase the sedimentation rate of particles during sedimentation and to prevent clogging by fine particles during filtration and to reduce the filtration resistance of the cake. However, a decrease in cake filtration resistance means that the moisture content of the cake increases and the solid-liquid separation efficiency decreases. It is not uncommon for the particle filling rate in the cake to fall below 10%. The high moisture content of the cake places a heavy load on the transport and drying process following filtration. Particularly in the drying process, it is eagerly desired to reduce the water content as much as possible in order to save energy. The cake is a particle layer which is trapped and deposited on the surface of the filter medium when the particle suspension is filtered with a filter medium, and has a characteristic of acting as a fragile solid without fluidity.
The inventor has developed a device that can evaluate the aggregation state of particles by measuring the hydrostatic pressure at the bottom of the sedimentation tube in which the particles are suspended. With this evaluation device, it became possible to specify slurry preparation conditions that can maintain fluidity even when the particle concentration is concentrated to nearly 40 vol%. If the suspension to be treated is prepared under such conditions by adding a dispersant, the slurry concentrated to a high concentration can be continuously discharged by gravity or centrifugal force. This means that not only the moisture content is lowered but also a scraping mechanism is not required, so that the apparatus can be downsized and continuously operated. Furthermore, the inventor made a prototype of a filtration device based on this principle, and continuously produced a 1 vol% (3 mass%) suspension of mica (sericite), a typical difficult-to-filter material, up to 35 vol% (60 mass%) in one pass. Has been successfully concentrated.

  The principle of evaluating the dispersion / aggregation state of particles by measuring the hydraulic pressure is as follows. As the particles settle freely in the liquid, the mass of the particles is supported by the viscous resistance of the liquid. Therefore, the hydrostatic pressure at the bottom of the container is the sum of the mass of water and the mass of particles per unit area. However, if particles are deposited on the bottom of the container, the mass of the particles is supported by the bottom of the container, so that the hydrostatic pressure is only the mass of water. Therefore, if the particles are well dispersed and the particles have settled individually, the hydrostatic pressure at the bottom of the container will increase, and if the particles are aggregated and connected to the bottom of the container, the hydrostatic pressure will decrease accordingly. The dispersion / aggregation state can be evaluated by measuring the water pressure. In this system, a batch sedimentation experiment of an alumina slurry with a particle size of 0.5μm and a concentration of 20vol% was performed while measuring the hydrostatic pressure at the bottom of the container with Aikabust. It was conceived from the experimental results that the hydrostatic pressure hardly decreased even when concentrated. A simple experiment using a side wall as a filter medium has been conducted and it has been confirmed that a slurry with a high concentration can be continuously taken out.

Next, a description will be given of a filtration device according to the best mode for embodying the present invention.
The filter device of the present embodiment uses a filter container 1 as shown in FIG. 10, and the filter container 1 has a filtrate of a suspension injected from the filter container inlet 2 in the filter container side wall 3. The suspension discharged from the portion 3a and concentrated in a substantially dispersed state can be discharged from the filter container discharge port 4.
In this case, the filter container side wall 3 has a configuration in which a base plate-type filter portion 3a in front view and a back plate 3b of the same shape are connected by a side plate 3c, and the upper portion is opened to serve as a slurry inlet. It is the filter container inlet 2. It is desirable to use a porous ceramic pipe for the filter part 3a.
A hype 5 as a discharge port is connected to the lower edge of the filter container discharge port 4, and an open / close valve 6 is attached to the pipe 5. Note that the lower edge portion of the filter container outlet 4 does not need to have a tapered shape, and the hype 5 and the on-off valve 6 do not necessarily have to be attached.
Whether or not the particles in the suspension are substantially dispersed is determined by putting the suspension into the filter container 1 and monitoring the change in the liquid pressure of the suspension at the inner bottom of the filter container 1. can do. That is, when the liquid pressure of the suspension at the inner bottom of the filter container 1 hardly changes (see the example of pH = 4.2), the particles are in a dispersed state. In other words, when the liquid pressure at the inner bottom portion of the filter container 1 corresponds to the mass of the suspension per unit volume and the state continues, it can be said that the suspension is substantially in a dispersed state. These demonstrations are described in detail in JP-A-2005-66384.
In this embodiment, the particles of the suspension can be dispersed by adjusting the pH of the suspension and adding a dispersing agent such as a surfactant, and as much as possible to generate cake during the filtration process. Trying to prevent.

Next, the filtration apparatus of 1st Embodiment is demonstrated with reference to FIG.
As shown in FIG. 1, the filtration device 7 of the first embodiment includes a filtration device inlet 8, a filtration device outlet 9, and a filtrate discharge port 10. As shown in FIGS. 1 to 3, the filtering device 7 has a plurality of filter containers 11, 12, and 13 arranged in a plurality of stages.
In this case, the filter container 11 of the upper group, the filter container 12 of the middle group, and the filter container 13 of the lower group are arranged in the vertical direction. A plurality of filter containers 11 in the upper group, filter containers 12 in the middle group, and filter containers 13 in the lower group are arranged in the horizontal direction.

As shown in FIG. 3, the upper-stage group of filter containers 11 is installed to be shifted from the middle-stage group of filter containers 12 by a half pitch in the lateral direction. Similarly, the filter container 12 in the middle group is installed to be shifted by a half pitch in the lateral direction from the filter container 13 in the lower group.
Each filter container 11, 12, 13 has the same structure as the filter container 1 shown in FIG. 10, and the filtrate of the suspension injected from the inlets 11a, 12a, 13a is filtered into the filter container side walls 11b, 12b. , 13b, and the suspension in which the particles are substantially dispersed and concentrated is discharged from the filter container outlets 11c, 12c, 13c. In addition, the filtrate discharged | emitted from filter container side wall part 11b, 12b, 13b is discharged | emitted from the filtrate discharge port 10. FIG.
Between the discharge port 11c of the filter container 11 of the upper group and the filter container inlet 12a of the middle group, a first suspension storage unit 14 that stores the suspension is provided. Between the filter container outlet 12c of the middle group and the filter container inlet 13a of the lower group, a second suspension storage unit 15 for storing the suspension is provided. A third suspension reservoir 16 for storing the suspension is provided on the discharge port 13c side of the filter container 13 in the lower group.
The first suspension reservoir 14 promotes the function of mixing and stirring the suspension discharged from the upper filter container discharge port 11c, and puts the suspension from the filter container inlet 12a of the middle group. Similarly, the 2nd suspension storage part 15 accelerates | stimulates the function which mixes and stirs the suspension which came out of the middle stage filter container discharge port 12c, and puts suspension from the filter container inlet 13a of a lower stage group. The third suspension reservoir promotes the function of mixing and stirring the suspension output from the lower filter container outlet 13c, and discharges the concentrated suspension from the filtration device outlet 9.
Such a suspension reservoir between the upstream filter container outlet and the downstream filter container inlet promotes the function of mixing and stirring the suspension. In addition, since the position of the upstream filter container is shifted from the position of the downstream filter container in the lateral direction, the suspension flow path is displaced, and the mixing and stirring of the suspension is promoted.

Next, the filtration apparatus of 2nd Embodiment is demonstrated with reference to FIG. 4 thru | or FIG.
As shown in FIG. 4, the filtration device 17 of the second embodiment includes a filtration device inlet 18, a filtration device outlet 19, and a filtrate discharge port 20. The filter device 17 has a plurality of filter containers 21, 22, 23, and 24 arranged in a plurality of stages as shown in FIGS.
In this case, the upper group filter container 21, the middle upper group filter container 22, the middle lower group filter container 23, and the lower group filter container 24 are arranged in the vertical direction. A plurality of upper group filter containers 21, middle upper group filter containers 22, middle lower group filter containers 23, and lower group filter containers 24 are arranged in the horizontal direction.
Each of the filter containers 21, 22, 23, 24 shown in FIGS. 4 to 6 has the same structure as the filter container 1 shown in FIG. 10, and is injected from the filter container inlets 21a, 22a, 23a, 24a. The suspension filtrate is discharged from the filter container side wall portions 21b, 22b, 23b, 24b, and the suspension in which the particles are substantially dispersed and concentrated is filtered into the filter container discharge ports 21c, 22c, 23c, It has the structure discharged | emitted from 24c. In addition, the filtrate discharged | emitted from filter container side wall part 21b, 22b, 23b, 24b is discharged | emitted from the filtrate discharge port 20. FIG.

In this case, the filter containers 21 and 22 are disposed so that the filtrate discharge direction discharged from the filter container side wall part 21b of the upper group intersects with the filtrate discharge direction discharged from the filter container side wall part 22c of the middle and upper group 90 degrees. is set up. The filter containers 22 and 23 are installed so that the direction of discharge of the filtrate discharged from the filter container side wall part 22c of the middle upper stage group intersects with the direction of the filtrate discharged from the filter container side wall part 23c of the lower middle group 90 degrees. ing. The filter containers 23 and 24 are installed so that the direction of the filtrate discharged from the filter container side wall portion 23c of the middle lower group intersects with the direction of the filtrate discharged from the filter container side wall portion 24c of the lower group 90 degrees. Yes. The intersecting angle is not necessarily 90 degrees and can be changed as appropriate.
In the case of such a configuration, the suspension discharged from the upper filter container discharge port 21c enters from the filter container inlet 22a of the middle group. Similarly, the suspension discharged from the filter container discharge port 22c of the middle and upper stage group enters from the filter container inlet 23a of the middle and lower stage group. Similarly, the suspension discharged from the filter container outlet 23c of the middle and lower group enters from the filter container inlet 24a of the lower group. The concentrated suspension exiting from the lower group filter container outlet 24 c exits from the filter outlet 19.
The upstream filter container and the downstream filter container are arranged such that the filtrate discharge direction discharged from the upstream filter container side wall portion intersects the filtrate discharge direction discharged from the downstream filter container side wall portion. As a result, the suspension flow path is displaced, which facilitates suspension mixing and stirring.
If necessary, the suspension storage section provided in the first embodiment may be provided between the filter container 21 in the upper group and the filter container 22 in the middle and upper group. Similarly, the suspension storage section provided in the first embodiment may be provided between the filter container 22 of the middle upper group and the filter container 23 of the middle lower group. Furthermore, the suspension storage section provided in the first embodiment may be provided between the filter container 23 of the middle lower group and the filter container 24 of the lower group.

Next, a filtration device according to a third embodiment will be described with reference to FIGS.
As shown in FIG. 7, the filtration device 27 of the third embodiment includes a filtration device inlet 28, a filtration device outlet 29, and a filtrate discharge port 30. The filter device 27 has a plurality of filter containers 31, 32, 33, and 34 arranged in a plurality of stages as shown in FIGS.
In this case, the upper group filter container 31, the middle upper group filter container 32, the middle lower group filter container 33, and the lower group filter container 34 are arranged in the vertical direction. A plurality of upper group filter containers 31, a middle upper group filter container 32, a middle lower group filter container 33, and a lower group filter container 34 are arranged in the horizontal direction.
Each of the filter containers 31, 32, 33, 34 shown in FIGS. 7 to 9 has the same structure as the filter container 1 shown in FIG. 10, and is injected from the filter container inlets 31a, 32a, 33a, 34a. The filtrate of the suspension is discharged from the filter container side wall portions 31b, 32b, 33b, 34b, and the suspension in which the particles are substantially dispersed and concentrated becomes the filter container discharge ports 31c, 32c, 33c, 34c can be discharged from 34c. In addition, the filtrate discharged | emitted from filter container side wall part 31b, 32b, 33b, 34b is discharged | emitted from the filtrate discharge port 30. FIG.

In this case, the discharge direction of the particle discharge path in the upper-stage group of filter containers 31 is inclined to the left as shown in FIG. The discharge direction of the particle discharge path in the filter container 32 of the middle / upper group is an oblique slope to the right. The discharge direction of the particle discharge path in the filter container 33 of the middle / lower stage group is an oblique left slope. The discharge direction of the particle discharge path in the filter container 34 in the lower group is inclined rightward.
Since the upper group filter container outlet 31c is coupled to the middle upper group filter container inlet 32a, the suspension from the filter container outlet 31c enters from the middle group filter container 32a. Since the middle and upper group filter container outlet 32c is connected to the middle and lower group filter container inlet 33a, the suspension from the outlet 22c of the middle and upper stage filter container 32 becomes the middle and lower stage filter container inlet 33a. Enter from 33a. Since the filter container outlet 33c of the middle lower group is coupled to the filter container inlet 34a of the lower group, the suspension that has exited from the filter container outlet 33c of the lower group enters from the filter container inlet 34a of the lower group. . The concentrated suspension exiting from the lower group filter container outlet 34 c exits the filter outlet 29.
The particle discharge paths of the upstream and downstream filter containers are formed so that the discharge direction of the particles in the upstream filter container intersects the discharge direction of the particles in the downstream filter container. As a result, the flow path of the suspension is shifted, and the suspension is mixed and stirred.
If necessary, a suspension storage section as in the first embodiment may be provided between the upper group filter container 31 and the middle upper group filter container 32. Similarly, the suspension storage section provided in the first embodiment may be provided between the filter container 32 of the middle upper group and the filter container 33 of the middle lower group. Furthermore, the suspension storage section provided in the first embodiment may be provided between the filter container 33 of the middle and lower group and the filter container 34 of the lower group.

In order to demonstrate the effectiveness of this system, a ceramic filter shown in FIGS. 11B and 11C was attached to the filtration device portion of FIG. The inner diameters of the ceramic filters (B) and (C) are both 9 mm, the effective filtration length is 200 mm, and the filtration areas are equal.
The filter (B) does not have a suspension reservoir, but in the filter (C), a filter having an effective filtration length of 100 mm is connected with a suspension reservoir as a suspension reservoir interposed therebetween.
A sericite suspension having a particle size of 4 μm was used as a sample. The concentration of the suspension is 1 vol. % With 3% water glass added as a dispersant. The filtration pressure is 0.2 MPa, the valve V ₂ is initially closed, and the filtrate is allowed to flow out from the valve V ₁ until the average concentration in the filtration device reaches 10 vol%. The average concentration in the filter was calculated from the amount of discharged filtrate. After reaching the predetermined concentration, the valve V ₂ is slightly opened, and the relationship between the filtrate amount and the filtration rate is measured for the filtration device of the first stage of the filter (B) and the second stage of the filter (C). . As is clear from the figure, the filtration speed is larger than the reproducibility when the two effective filtration lengths are the same, and the filtration performance is improved by providing two (multistage) filters and a filtrate reservoir between them. Was shown to be improved.

  The present invention is not limited to the first to third embodiments described above, and various modifications can be made within the scope that can be easily conceived by those skilled in the art without departing from the scope of the claims. include. For example, the number of filter containers used in the filtration device is not limited to the above embodiment, and can be arbitrarily changed. Alternatively, the mixing and stirring can be promoted by making the flow path zigzag or spiral. If the flow path is divided into several sections in the flow direction and the flow paths in the respective sections are shifted, modifications other than the embodiment can be made. In particular, if a liquid reservoir is provided between the sections, mixing and stirring are promoted.

The filtration device of the present invention can be used as a cakeless high-concentration continuous filtration system for mass processing. The system concentrates and separates the fine particles dispersed in the liquid, not only in the beneficiation process and water treatment process, but also in environmental fields such as various algae treatments, river sludge and marine dredging sludge treatment. It can be put to practical use in a wide range of fields such as advanced mechanical fields such as chemical mechanical polishing (CMP) waste liquid treatment of silicon wafers, fine particle manufacturing process by crystallization, and wet pulverization / recovery of high value added substances by recycling.
This system has the following advantages over conventional filtration systems if an appropriate dispersant can be selected for the target solid-liquid dispersion and an appropriate input amount can be determined. That is, since a cake scraping mechanism is not required, the filtration area per unit volume can be increased. Since there are no moving parts, energy saving and maintenance-free are possible. The absence of moving parts simplifies the structure of the device and facilitates scale-up, but if a mechanism for mixing and stirring the suspension is not added, channeling and blockage are likely to occur. In the middle of changing the suspension flow path, a suspension reservoir is provided to promote mixing and stirring of the concentrated suspension.

This system has the following effects. Since the apparatus can be easily downsized and the installation area of the apparatus can be reduced, the apparatus can be easily installed in a narrow place. By taking basic data once, the system can be designed according to the throughput and target concentration. Since the system can be componentized, it is possible to flexibly cope with the processing amount and the target concentration. Continuous operation is easy. Particles can be recovered while maintaining a high concentration flow state. Since the dispersed particles can be concentrated in a dispersed state, the production process and schedule can be shortened, such as a relatively simple drying process (operation). Since no flocculant containing metal ions is required, the adverse effects on the product due to the flocculant are eliminated. In particular, in order to treat a large amount of water, it is currently treated semi-batch with a thickener using a large site and a large amount of flocculant, or dried in the sun. If a concentration system is used, a high-concentration particle suspension can be obtained continuously in a short time compared to the conventional method, and the installation area can be reduced, so that the land can be used effectively.
In addition, there are currently no effective treatment technologies for sludge treatment of iron compounds in the beneficiation and ironmaking fields, but this system makes it easy to treat sludge such as iron compounds and reuse the iron compounds. If possible, it is expected that new systems will be created through the development and manufacture of new systems centered on this system and their operational technologies. In addition, environmental problems such as reduction of industrial waste disposal costs by reducing sludge in rivers and oceans, and recovery of algae such as sea cucumbers that lead to water pollution such as lakes and marshes that are urgently required not only in Japan but also worldwide.・ It is expected to become a large market due to the need to solve social problems.
The system is intended for particle suspensions containing inorganic and organic substances such as iron compounds, sludge and blue sea bream, but if you can find suitable dispersants and dispersion conditions for the particle suspension, The suspension can be handled. If a more versatile dispersant is developed, the scope of application of this system is expected to expand further.

It is a conceptual diagram at the time of seeing the filtration apparatus of 1st Embodiment which actualized this invention from the side. It is a conceptual diagram at the time of seeing a part of filtration apparatus of 1st Embodiment from diagonally upward. It is a conceptual diagram at the time of seeing the cross section of the filtration apparatus of 1st Embodiment from upper direction. It is a conceptual diagram at the time of seeing the filtration apparatus of 2nd Embodiment which actualized this invention from the side. It is a conceptual diagram at the time of seeing a part of filtration apparatus of 2nd Embodiment from diagonally upward. It is a conceptual diagram at the time of seeing the cross section of the filtration apparatus of 2nd Embodiment from upper direction. It is a conceptual diagram at the time of seeing the filtration apparatus of 3rd Embodiment which actualized this invention from the side. It is a conceptual diagram at the time of seeing a part of filtration apparatus of 3rd Embodiment from diagonally upward. It is a conceptual diagram at the time of seeing the cross section of the filtration apparatus of 3rd Embodiment from upper direction. It is a perspective view which expands and shows the filter container used for the filtration apparatus of the said embodiment. It is a conceptual diagram which shows a filtration experiment. It is a figure which shows the result of having measured the relationship between the filtrate amount and the filtration rate, Comprising: The comparative example of 1 step | paragraph of a filter and 2 steps | paragraphs is shown.

Explanation of symbols

7, 17, 27, filtration device 11, 12, 13, 21, 22, 23, 24, 31, 32, 33, 34 Filter container 11a, 12a, 13a, 21a, 22a, 23a, 24a, 31a, 32a, 33a 34a Filter container inlet 11b, 12b, 13b, 21b, 22b, 23b, 24b, 31b, 32b, 33b, 34b Filter container side wall 11c, 12c, 13c, 21c, 22c, 23c, 24c, 31c, 32c, 33c 34c Filter container outlet 14, 15, 16 Suspension reservoir

Claims (4)

The filtrate of the suspension injected from the filter container inlet is discharged from the side wall of the filter container, and the filter container in which the suspension in which particles are substantially dispersed is discharged from the filter container discharge port in the vertical direction. A plurality of filtration devices,
A filtration apparatus comprising a suspension storage section for storing a suspension between the upstream filter container outlet and the downstream filter container inlet.   A plurality of the upstream filter containers are arranged in the lateral direction, a plurality of the downstream filter containers are arranged in the lateral direction, and the position of the upstream filter container is shifted laterally from the position of the downstream filter container. The filtration device according to claim 1, wherein the filtration device is installed. The filtrate of the suspension injected from the filter container inlet is discharged from the side wall of the filter container, and the filter container in which the suspension in which particles are substantially dispersed is discharged from the filter container discharge port in the vertical direction. A plurality of filtration devices,
The upstream filter container and the downstream filter container are arranged so that the filtrate discharge direction discharged from the upstream filter container side wall and the filtrate discharge direction discharged from the downstream filter container side wall intersect. A filtering device characterized by that. The suspension filtrate injected from the filter container inlet is discharged from the side wall of the filter container, and a plurality of filter containers are discharged vertically from the filter container discharge port. A filtration device connected in a direction,
The particle discharge paths in the upstream and downstream filter containers so that the discharge direction of the particles in the upstream filter container and the discharge direction of the particles in the downstream filter container intersect. A filtration device characterized by comprising:

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