JP2015136650A - Belt dehydrator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve problems that: a washing nozzle clogs when using a filtrate as washing water in a filter device equipped with the washing nozzle to wash a filter cloth; and the washing water is recovered without using a device to clear the filtrate.SOLUTION: In a belt dehydrator having a filter part to separate a liquid including a solid to a filtrate and a residue, a filtrate receiving part being disposed under the filter part and collecting the filtrate and a partition part to separate the filtrate at a front side in a belt travelling direction from the filtrate at a depth side in the belt travelling direction, the depth side filtrate is recovered as clarified water, the front side filtrate is recovered as waste water and the clarified water is used as washing water.

Description

  The present invention relates to a belt dehydrator that processes a liquid containing solids with an endless filter cloth and separates it into a filtrate and a residue, and uses the filtrate as a cleaning liquid for the filter cloth.

  In a sludge dewatering device equipped with a belt press-type pressure dehydrator that supplies dehydrated material by supplying sludge or other material to be processed between upper and lower endless belt-like filter cloths, the filter cloth is clogged. For this purpose, the filter cloth is cleaned by providing a cleaning nozzle for spraying cleaning water on the filter cloth. As this washing water, it is known to collect and use a dehydrated filtrate obtained by gravity dehydration.

  There is also known a sludge dewatering apparatus that clarifies dehydrated filtrate and filter cloth washing wastewater and uses it as washing water. For example, Patent Document 1 describes a sludge dewatering device that collects dehydrated filtrate and filter cloth washing wastewater, and positively clarifies the recovered water using a recovered water clarification device.

JP-A-10-263889

The dehydrated filtrate obtained by gravity dehydration contains a large amount of solids that pass through the filter cloth, and if the dehydrated filtrate is used as washing water as it is, there is a problem of clogging the washing nozzle. Therefore, in reality, the dehydrated filtrate cannot be used as a cleaning liquid for a long period of time.
Further, in the sludge dewatering device described in Patent Document 1, although the clarified washing water can prevent clogging of the washing nozzle, the recovered water clarification device is necessary, so that the device is complicated and long. Turn into. Furthermore, the power for operating the recovered water clarification device is also required, and there is a problem that the operation cost is high.

As a result of intensive studies, the present inventor found that when a liquid containing solids was processed with a belt dehydrator, the filtrate on the front side in the traveling direction of the belt contained a large amount of solids, and the filtrate on the back side contained less solids. The present invention was completed by using the filtrate on the back side as washing water.
Specifically, the present invention provides the following belt dehydrator.

(First invention of the present application)
In order to solve the above problems, the first invention of the present application is a belt dehydrator for separating a solid from a liquid containing a solid, a filtration unit for separating the liquid containing the solid into a filtrate and a residue, and the filtration A filtrate receiving portion for collecting the filtrate, and a partition portion for separating the filtrate on the front side in the belt traveling direction and the filtrate on the back side in the belt traveling direction on the filtrate receiving portion, The belt dehydrator is characterized in that the filtrate is recovered as clarified water, the filtrate on the near side is recovered as dirty water, and the clarified water is used as washing water.
(The second invention of the present application)
The configuration of the second invention of the present application for solving the above problem is the belt dehydrator according to the first invention of the present application, wherein the partition portion is a partition plate.
(The third invention of the present application)
In the configuration of the third invention of the present application for solving the above-described problem, the filtrate receiving portion includes a bottom portion inclined so that the sewage flows down, and the partition plate is inclined with respect to a direction in which the sewage flows down. The belt dehydrator according to the second invention of the present application.
(The fourth invention of the present application)
The configuration of the fourth invention of the present application for solving the above-mentioned problems is the belt dehydrator according to the second or third application, wherein the partition plate is movable.
(The fifth invention of the present application)
The structure of the fifth invention of the present application for solving the above-mentioned problem is the belt dehydrator according to any one of the first to third inventions of the present invention, characterized in that two or more of the partition portions are provided.
(The sixth invention of the present application)
The sixth invention of the present application for solving the above problems is a method of operating a belt dehydrator for separating a solid from a liquid containing a solid, a filtration step of separating the liquid containing the solid into a filtrate and a residue, A step of separating the filtrate into a filtrate on the front side in the belt traveling direction and a filtrate on the back side in the belt traveling direction; and collecting the filtrate on the back side as clarified water, collecting the filtrate on the near side as sewage, and washing the clarified water as washing water The operation method of the belt dehydrator is characterized by being used as:

According to the belt dehydrator of the first invention of this application, the problem is solved that the cleaning nozzle is clogged by collecting the filtrate into clarified water and sewage at the partition and using the obtained clarified water as cleaning water. can do.
Moreover, since it is not necessary to provide the apparatus for clarifying filtrates, such as a recovered water clarification apparatus, in the belt dehydrator of 1st invention of this application, the structure of an apparatus becomes simple and an apparatus can be made small. it can.
Furthermore, the power of the recovered water clarifier is not required, and the power consumption can be saved. Moreover, since a filtrate can be used as washing water, the usage-amount of miscellaneous water can be reduced.

  According to the belt dehydrator of the second invention of the present application, it is possible to easily separate and collect sewage and clarified water by providing a partition plate in one filtrate receiving part without providing a plurality of filtrate receiving parts.

According to the belt dehydrator of the third invention of the present application, since the bottom portion of the filtrate receiving portion is inclined, the filtrate can be discharged from the filtrate receiving portion without requiring power from a pump or the like.
Further, by installing the partition plate to be inclined with respect to the direction in which the sewage flows, it is possible to prevent the solid content in the sewage from staying in the partition plate, and to smoothly discharge the sewage from the filtrate receiving part. .

According to the belt dehydrator of the fourth invention of the present application, the amount of sewage and clarified water obtained by distributing the filtrate can be adjusted by moving the partition plate back and forth in the belt traveling direction.
In the belt dehydrator of the present invention, the distribution amount of sewage and clarified water can be changed according to the state of the liquid containing solids. Therefore, it is possible to appropriately adjust the collection amount of the clear water while preventing the cleaning nozzle from clogging the concentration of the solid content contained in the clear water.

  According to the belt dehydrator of the fifth invention of the present application, the filtrate can be divided into a plurality of liquids having different solid content concentrations by providing a plurality of partition portions. It is possible to prepare the clear water so that the concentration of the obtained plurality of liquids is appropriately mixed so that the washing nozzle is not clogged.

According to the sixth aspect of the present invention, the dehydration process can be stably performed without clogging the cleaning nozzle.
Furthermore, according to this invention, the process of clarifying the filtrate is not necessary, and the power consumption can be reduced. Moreover, since a filtrate can be used as washing water, the usage-amount of miscellaneous water can be reduced.

It is a schematic explanatory drawing which shows the structure of the sludge processing system provided with the belt dehydrator of the Example of this invention. It is a schematic side view which shows the structure of the belt dehydrator of the Example of this invention. (A) It is a schematic plan view which shows the structure of the belt dehydrator of the 1st Example of this invention. (B) It is a schematic plan view which shows the structure of the filtrate receiving part of the belt dehydrator of the 1st Example of this invention, and a schematic explanatory drawing explaining the flow of sewage and clarified water. (A) It is XX cross-section perspective view of FIG.3 (b). (B) It is a schematic explanatory drawing explaining the flow of the sewage of the belt dehydrator of the 1st Example of this invention, and clarified water. It is a disassembled assembly figure which shows the structure of the belt dehydrator of the 1st Example of this invention. (A) It is a schematic plan view which shows the structure of the belt dehydrator of the 2nd Example of this invention. (B) It is a schematic plan view which shows the structure of the filtrate receiving part of the belt dehydrator of the 2nd Example of this invention, and a schematic explanatory drawing explaining the flow of sewage and clarified water. (A) It is the YY cross-section perspective view of FIG.6 (b). (B) It is a schematic explanatory drawing explaining the flow of the sewage of the belt dehydrator of the 2nd Example of this invention, and clarified water. It is a disassembled assembly figure which shows the structure of the belt dehydrator of the 2nd Example of this invention. (A) It is a schematic plan view which shows the structure of the belt dehydrator of the 3rd Example of this invention. (B) It is a schematic plan view which shows the structure of the filtrate receiving part of the belt dehydrator of the 3rd Example of this invention, and a schematic explanatory drawing explaining the flow of sewage and clarified water. (A) It is a ZZ cross-sectional perspective view of FIG.9 (b). (B) It is a cross-sectional perspective view which shows the structure inside the ZZ cross-sectional perspective view of Fig.10 (a). It is a schematic explanatory drawing explaining the flow of the water of the belt dehydrator of 3rd Example of this invention, and clarified water. It is a disassembled assembly figure which shows the structure of the belt dehydrator of the 3rd Example of this invention.

The “solid-containing liquid” of the present invention (hereinafter referred to as “object to be treated”) is a liquid in which a solid is dispersed, and is a mud having a high solid concentration from a liquid having a low solid concentration and a low viscosity. It includes up to the state. Specific examples include sewage sludge from sewage treatment plants, excess sludge from wastewater treatment plants, paper sludge from paper mills, dredged sludge, sludge, and the like.
In the following examples, a sludge treatment system and a belt dehydrator of the present invention provided in the sludge treatment system will be described.
In addition, in the structure of the apparatus in the drawing, a portion drawn using a broken line means a transparent view.

FIG. 1 is a schematic explanatory diagram showing a configuration of a sludge treatment system 1 including a belt dehydrator according to an embodiment of the present invention.
The sludge treatment system 1 includes a sludge storage tank 2, a sludge supply pump 3, a polymer dissolution tank 4, a chemical injection pump 5, a mixing tank 6, a sludge dewatering device 7, a washing water tank 8, a water supply pump 9, and a miscellaneous water tank 10. The
Sludge generated by sewage treatment or the like is accumulated in the sludge storage tank 2 and supplied to the mixing tank 6 by the sludge supply pump 3. Moreover, chemical | medical agents, such as a flocculant, are prepared in the polymer dissolution tank 4, are supplied to the mixing tank 6 by the chemical injection pump 5, and are mixed with sludge. The sludge mixed with the flocculant forms a floc floc by the action of the flocculant. The agglomerated sludge is fed to the sludge dewatering device 7 and dehydrated.

The sludge dewatering device 7 includes a belt dehydrator 11 that concentrates sludge by gravity filtration, and a pressure dehydrator 12 that forcibly dewaters by pressurization.
The belt dehydrator 11 has an endless belt 11a formed of a filter cloth, and sludge is supplied from the sludge supply unit 13 onto the endless belt 11a of the belt dehydrator 7 and transferred by the endless belt 11a. The filtrate and the residue are separated by gravity filtration. The detailed configuration of the belt dehydrator 11 will be described later.

  The pressure dehydrator 12 includes two filter cloth endless belts 11a and 12a and a plurality of pressure rolls 12b. The two endless belts are installed so that two filter cloths overlap each other, and a belt press. It constitutes a pressure dehydrator of the mold. The residue concentrated by the belt dehydrator 11 passes through the plurality of pressure rolls 12b while being narrowed by two filter cloths, and is pressurized and dewatered. Here, in the belt press type pressure dehydrator 12 of the embodiment of the present invention, the endless belt 11a of the belt dehydrator 11 is used as one endless belt 11a of two endless belts of filter cloth. However, in addition to the endless belt 11 a of the belt dehydrator 11, two endless belts may be provided to constitute the belt press type pressure dehydrator 12.

  The forcibly dehydrated residue is discharged from the dehydrated cake discharge unit 14 as a dehydrated cake. The dehydrated cake is used as a cement material, a fertilizer, a fuel, and the like after undergoing treatments such as drying and carbonization.

In addition, the sludge dewatering device 7 is provided with a cleaning nozzle 15 for cleaning the solid matter clogged in the filter cloth. The washing water is supplied from the washing water tank 8 to the washing nozzle 15 by the water supply pump 9 and sprayed toward the filter cloth.
In the sludge dewatering device 7 of the embodiment of the present invention, clarified water obtained from the filtrate of the belt dewatering machine 7 is used as the washing water. When the amount of clarified water recovered as washing water is insufficient, miscellaneous water is supplied from the miscellaneous water tank 10 to replenish the washing water.

FIG. 2 is a schematic side view showing the configuration of the belt dehydrator 11 according to the embodiment of the present invention.
The belt dehydrator 11 of the present invention includes a filtration unit 16 that separates an object to be treated such as sludge into filtrate and residue, and a filtrate receiving unit 17 provided below the filtration unit 16.

The filtration part 16 has the filter cloth 16a and the two tension | tensile_strength rolls 16b, and the tension | tensile_strength roll 16b can rotate and can transfer the filter cloth 16a. An object to be treated such as sludge is supplied to the front side in the traveling direction of the filter cloth 16a, while the liquid falls as a filtrate while proceeding to the far side in the traveling direction, and the solid remains as a residue and is transferred onto the filter cloth 16a. The residue is subjected to subsequent processing such as pressure dehydration.
Here, the filtration unit 16 of the present invention may be a belt-like filtration device that travels in a substantially horizontal direction, and instead of the configuration of the filter cloth 16a and the tension roll 16b, an endless conveyor of a plurality of punching plates, a plurality of It is good also as an endless conveyor etc. in which the wire or metal plate of this was formed with the clearance gap.
The material of the filter cloth 16a is not particularly limited, and examples thereof include synthetic fibers such as nylon and polyester, and metal meshes such as cotton and stainless steel.
The filter cloth is preferable because it is lightweight and easy to handle, and can be used for pressure dehydration in cooperation with another endless belt.
The filter cloth 16a may be installed so as to proceed in the horizontal direction, or may be installed so as to be inclined upward.

  The filtrate receiving part 17 consists of the filtrate receiving tank 17a installed under the filtering part 16, and the filtrate receiving tank 17a collect | recovers the filtrate which permeate | transmitted the filter cloth 16a.

FIG. 3A is a schematic plan view showing the configuration of the belt dehydrator according to the first embodiment of the present invention. FIG. 3B is a schematic plan view showing the configuration of the filtrate receiving part of the belt dehydrator according to the first embodiment of the present invention, and a schematic explanatory diagram for explaining the flow of sewage and clarified water.
The filtrate receiving tank 17a has a partition plate 19 and is divided into a sewage receiving area and a clarified water receiving area. The filtrate that has passed through the filtration unit of the belt dehydrator has a high solid content concentration on the front side in the traveling direction of the filter cloth 16a and a low solid content concentration on the far side in the traveling direction. The partition plate 19 separates and collects the filtrate on the near side in the traveling direction and the filtrate on the far side, and uses the filtrate on the far side as clarified water for washing water.

  The partition plate 19 may have any configuration as long as the partition portion separates the filtrate on the front side in the traveling direction of the filter cloth 16a and the filtrate on the back side. For example, the filtrate receiving tank may be composed of one tank, and the partition plate may separate the filtrate on the front side of the filter cloth 16a and the filtrate on the far side, or the filtrate receiving tank may be composed of a plurality of tanks. Use of a partition plate is preferable because the configuration of the filtrate receiving tank becomes simple. In addition, when the filtrate receiving tank is composed of a plurality of tanks, the tanks can be separately operated during cleaning and maintenance.

  The sewage collected in the sewage receiving area is discharged from the sewage discharge port 17d and is collected through the sewage flow path 18 provided outside the filtrate receiving tank 17a. Although it does not limit about the process of the collect | recovered sewage, For example, it returns to the sludge storage tank 2, and is again mixed with the coagulant | flocculant by the mixing tank 6. FIG.

  On the other hand, the clarified water collected in the clarified water receiving area passes through the clarified water discharge passage 17c and is discharged from the clarified water discharge port 17b. The clarified water is collected in the washing water tank 8 and used as washing water.

Fig.4 (a) is XX cross-section perspective view of FIG.3 (b). FIG. 4B is a schematic explanatory diagram for explaining the flow of sewage and clarified water in the belt dehydrator according to the first embodiment of the present invention.
The partition plate 19 has a partition plate holding portion 20, and the partition plate holding portion 20 is provided with a holding portion hole 20 a. Further, the side wall 17e of the filtrate receiving tank 17a is provided with a plurality of side wall holes 17h. When installing the partition plate 19, a fixing member such as a screw is inserted so that the side wall hole 17h and the holding portion hole 20a communicate with each other, thereby fixing the partition plate holding portion 20 to the side wall 17e.
The means for fixing the partition plate 19 to the filtrate receiving tank 17a is not particularly limited. For example, instead of the fixing means for inserting the side wall hole 17h and the holding portion hole 20a, the partition plate holding portion 20 and the side wall 17e from above. It may be fixed by a fixing member that holds them, or may be fitted with a partition plate holding part 20 and a side wall 17e by providing a fitting piece and a fitting groove, respectively.

A plurality of side wall holes 17h are provided along the traveling direction of the filter cloth 16a. The partition plate 19 can be moved back and forth in the traveling direction of the filter cloth 16a by selecting one of the holes as the side wall hole 17h to be fixed to the holding portion hole 20a. With this configuration, when changing the type of the object to be processed or when the solid concentration of the object to be processed is changed, an appropriate clear water that can be used as washing water is prepared by moving the partition plate back and forth in the traveling direction. can do.
The means for moving the partition plate is not limited to the embodiment, and for example, a rail and an electric motor may be provided and moved by automatic control.

The bottom 17g of the filtrate receiving tank 17a is inclined so that sewage and clarified water flow down. Thereby, dirty water and clarified water can be discharged | emitted by natural fall.
A clear water discharge passage 17c is provided at the bottom of the filtrate receiving tank 17a, and the clear water in the clear water receiving region is collected in the clear water discharge passage 17c and discharged from the clear water discharge port 17b.

  On the other hand, the sewage in the sewage receiving area is blocked by the partition plate 19 while flowing down the bottom toward the bottom. The partition plate 19 is installed so as to be inclined with respect to the direction in which the sewage flows, and guides the sewage to the sewage discharge port 17d. With this configuration, it is possible to prevent the solid content in the sewage from collecting on the partition plate 19. The sewage guided to the sewage discharge port 17d is collected through the sewage flow path 18.

FIG. 5 is an exploded view showing the configuration of the belt dehydrator according to the first embodiment of the present invention.
The filtrate receiving tank 17a, the partition plate 19 and the partition plate holding portion 20 are detachable, and the position of the partition plate 19 can be moved by changing the position of the side wall hole 17h.

FIG. 6A is a schematic plan view showing the configuration of the belt dehydrator according to the second embodiment of the present invention. FIG. 6B is a schematic plan view showing the configuration of the filtrate receiver of the belt dehydrator according to the second embodiment of the present invention, and a schematic explanatory diagram for explaining the flow of sewage and clarified water.
In the second embodiment, instead of the sewage channel 18 of the first embodiment, a sewage channel region is provided in the filtrate receiving tank 17a. Thereby, since the sludge receiving tank 17a becomes a simpler structure and it is not necessary to provide the sewage flow path 18 in the outer side of the sludge receiving tank 17a, it becomes a more compact structure.

Specifically, the flow path separating plate 21 is provided in the filtrate receiving tank 17a in parallel with the direction in which the filtrate flows down, and the sewage discharge port 17d of the side wall 17e is formed at the lowermost part of the filtrate receiving tank 17a. A flow path region is formed between the flow path dividing plate 21 and the side wall 17e. The sewage in the sewage receiving area is guided to the flow path area by the partition plate 19, flows down the flow path area, and is discharged from the sewage discharge port 17d formed at the lowermost part.
The clear water is discharged from the clear water discharge port 17b as in the first embodiment.

Fig.7 (a) is the YY cross-section perspective view of FIG.6 (b). Moreover, FIG.7 (b) is a schematic explanatory drawing explaining the flow of the sewage of the belt dehydrator of the 2nd Example of this invention, and clarified water.
The flow path partition plate 21 is formed with a plurality of flow path partition plate holes 21a arranged in parallel in the traveling direction of the filter cloth 16a. As in the first embodiment, the position of the partition plate 19 is set by fixing the flow path partition plate holes 21a and the holding portion holes 20a of the partition plate holding portion 20 with a fixing member.

FIG. 8 is an exploded view showing the configuration of the belt dehydrator according to the second embodiment of the present invention.
Similar to the first embodiment, the partition plate 19 and the partition plate holding portion 20 are detachable. Moreover, the flow-path division | segmentation board 21 also becomes a structure which can be attached to the filtrate receiving tank 17a. Thereby, the flow path division plate 21, the partition plate 19, and the partition plate holding | maintenance part 20 can be attached to the filtrate receiving tank 17a used conventionally. And it is possible to apply this invention to the filtrate receiving tank 17a used conventionally, without producing the new filtrate receiving tank 17a by processing to form the sewage discharge port 17d in the filtrate receiving tank 17a.

FIG. 9A is a schematic plan view showing the configuration of the belt dehydrator according to the third embodiment of the present invention. FIG. 9B is a schematic plan view showing the configuration of the filtrate receiver of the belt dehydrator according to the third embodiment of the present invention, and a schematic explanatory diagram for explaining the flow of sewage and clarified water.
In the third embodiment, the filtrate receiving tank 17 a has a plurality of partition plates 19. Further, in all regions formed by the plurality of partition plates 19, a sewage discharge port 17d and a clarified water discharge port 17b are formed on the side wall e and the side wall f on both sides, respectively, and the sewage flow channel 18 and the clarified water flow are formed outside thereof. A path 22 is provided. Further, each region has a closing plate 23 for closing the sewage discharge port 17d or the clear water discharge port 17b.
A specific configuration will be described with reference to FIGS. 10A, 10B, and 11. FIG.

Fig.10 (a) is a ZZ cross-sectional perspective view of FIG.9 (b). FIG. 10B is a cross-sectional perspective view illustrating the internal configuration, with a part of the Z-Z cross-sectional perspective view of FIG. Further, FIG. 11 is a schematic explanatory view for explaining the flow of the water and the clarified water of the belt dehydrator according to the third embodiment of the present invention.
Three partition plates 19a, 19b, and 19c are fixed to the filtrate receiving tank 17a. These partition plates are arranged so as to be perpendicular to the direction in which sewage and clarified water flow down. And in the side wall e and the side wall f of the area | region formed of the partition plates 19a, 19b, 19c, the sewage discharge port 17e and the clarified water discharge port 17b are formed, respectively. Further, in order to close the sewage discharge port 17e or the clarified water discharge port 17b, blocking plates 23a, 23b, and 23c are detachably installed in the respective regions.
In each region, the blocking plates 23a, 23b, 23c block either the sewage discharge port 17e or the clarified water discharge port 17b, thereby selecting each region as either the sewage receiving unit or the clarified water receiving unit. Is possible.

For example, in the example of FIG. 11, in the region formed by the partition plates 19a and 19b, the sewage discharge port 17d is closed using the closing plate 23a, the region formed by the partition plates 19b and 19c, and the partition plate 19c. And in the area | region formed with the filtrate receiving tank 17a, the clear water discharge port 17b is obstruct | occluded using the obstruction | occlusion board 23b, 23c.
Thereby, the region formed by the partition plates 19a and 19b becomes a clear water receiving region, while the region formed by the partition plates 19b and 19c, and the region formed by the partition plate 19c and the filtrate receiving tank 17a, It becomes a sewage receiving area.
Then, the clarified water in the clarified water receiving area is discharged from the clarified water discharge port 17 b and is collected in the washing water tank 8 through the clarified water flow path 22. Further, the sewage in the sewage receiving area is discharged from the sewage discharge port 17 d and is collected through the sewage flow path 18.

FIG. 12 is an exploded view showing the configuration of the belt dehydrator according to the third embodiment of the present invention.
In the third embodiment, the partition plates 19a, 19b, and 19c are fixed, and the sewage discharge port 17d or the clarified water discharge port 17b is closed using the removable closing plates 23a, 23b, and 23c. Thus, the positions of the sewage receiving area and the clear water receiving area are adjusted.

The belt dehydrator of the present invention can be used in a filtration device that uses washing water. For example, the belt dehydrator of the present invention can be used not only as a sludge dewatering apparatus equipped with a belt press type pressure dehydrator of an embodiment of the present invention but also as a pretreatment for a screw press type filtration apparatus or the like. .
Moreover, although the belt dehydrator of the Example of this invention is based on gravity filtration, it can be utilized also for the belt dehydrator by vacuum filtration.

  Fields in which filtration devices are used include sewage treatment plants, wastewater treatment plants, food factories, paper mills, pharmaceutical factories, dredging work sites, etc. In these fields, washing water is jetted from washing nozzles and filters are used. When washing, the belt dehydrator of the present invention can be used.

  1 sludge treatment system, 2 sludge storage tank, 3 sludge supply pump, 4 polymer dissolution tank, 5 chemical injection pump, 6 mixing tank, 7 sludge dewatering device, 8 washing water tank, 9 water supply pump, 10 miscellaneous water tank, 11 belt dewatering Machine, 11a endless belt, 12 pressure dehydrator, 12a endless belt, 12b pressure roll, 13 sludge supply section, 14 dehydrated cake discharge section, 15 washing nozzle, 16 filtration section, 16a filter cloth, 16b tension roll, 17 filtrate Receiving part, 17a Filtrate receiving tank, 17b Clarified water outlet, 17c Clarified water outlet, 17d Sewage outlet, 17e, 17f Side wall, 17g Bottom, 17h Side wall hole, 18 Sewage channel, 19, 19a, 19b, 19c Partition plate , 20 Partition plate holding portion, 20a holding portion hole, 21 flow path partition plate, 21a flow path partition plate hole, 22 clear water flow path, 23, 23 , 23b, 23c closing plate

Claims (6)

In a belt dehydrator for separating solids from liquids containing solids,
A filtration unit for separating the liquid containing the solid into a filtrate and a residue;
A filtrate receiver provided under the filter and collecting the filtrate;
In the filtrate receiver, a partition for separating the filtrate on the near side in the belt traveling direction and the filtrate on the far side in the belt traveling direction is provided,
The back side filtrate is recovered as clear water, and the front side filtrate is recovered as sewage,
A belt dehydrator using the clarified water as washing water. The belt dehydrator according to claim 1, wherein the partition portion is a partition plate. The filtrate receiving part includes a bottom part inclined so that the sewage flows down,
The belt dehydrator according to claim 2, wherein the partition plate is inclined with respect to a direction in which the sewage flows down. The belt dehydrator according to claim 2 or 3, wherein the partition plate is movable. The belt dehydrator according to any one of claims 1 to 3, wherein two or more of the partition portions are provided. In the operation method of the belt dehydrator for separating the solid from the liquid containing the solid,
A filtration step of separating the liquid containing the solid into a filtrate and a residue;
Separating the filtrate into a filtrate on the front side in the belt traveling direction and a filtrate on the back side in the belt traveling direction;
The back side filtrate is recovered as clear water, and the front side filtrate is recovered as sewage,
A method of operating a belt dehydrator, wherein the clarified water is used as washing water.

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