JP2011177633A - Apparatus for transferring and dehydrating wet powder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus for transferring and dehydrating a wet powder which can remarkably decrease the water content of a wet powder such as sand after wet classification, make a drying step unnecessary after dehydration, accordingly quicken shipping cycles of products, and at the same time carry out dehydration simultaneously with transfer of the wet powder by a single apparatus, and give high treatment efficiency without requiring a wide installation space. <P>SOLUTION: The apparatus for transferring and dehydrating a wet powder includes a transfer means for transferring a wet powder and a dehydration means for removing water of the wet powder being transferred by the transfer means, wherein the transfer means has a conveyer obtained by striding a net-like endless belt over a starting side rotary body, and an ending side rotary body, and the dehydration means has a water receiving container installed between the upper belt and the lower belt of the endless belt for storing water which passes through the meshes of the upper belt and drips and a suction means for decreasing the pressure of the inside of the water receiving container. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention can dehydrate while transferring wet powder such as sand after wet classification, and can greatly reduce the moisture content of the wet powder during transfer, eliminating the drying step after dehydration. The present invention relates to a wet powder transfer and dehydration apparatus.

In general, a large amount of water is contained in the sand after wet classification, and for example, sand having a particle size of 10 mm or less contains about 50% of water.
Since sand containing such a large amount of water cannot be shipped as a product as it is, it is usually shipped after the moisture content is reduced to about 15% or less by naturally drying the sand after wet classification at a predetermined place. is doing.
However, such a conventional method requires several days for drying, and therefore cannot be shipped in a short period of time, resulting in a problem that the shipping cycle becomes long.

On the other hand, the following Patent Document 1 discloses a technique for solving such a problem.
In the disclosed technology of Patent Document 1, a filter medium and a crushed stone material are arranged on the upper and lower stages of a water collecting body composed of a concave groove installed below a reversing part of a sand belt conveyor to be conveyed to a predetermined place, and surrounded by the crushed stone material. A water permeable suction pipe is connected to a jet pump through a connecting pipe, and this jet pump is connected to a muddy water treatment tank, and a backwash valve is provided in the middle part, and the muddy water treatment tank is connected to a water purification tank. This is a forced dewatering device for flushing sand that communicates by piping from the tank to the jet pump.

However, the apparatus disclosed in Patent Document 1 must be provided with a filter medium, a water collection body, a water permeable suction pipe, and the like separately from a belt conveyor for transferring sand. There is a problem of requiring installation space.
In addition, after sand is transferred by the belt conveyor, dehydration work is performed by a filter medium, a water collection body, a water permeable suction pipe, a jet pump, etc., and therefore, a two-stage processing process of a transfer process and a dehydration process is required. There is also a problem of inefficiency.

Patent Document 2 below discloses a dewatering apparatus after wet granulation provided with a dewatering apparatus including a sieve, a mesh conveyor, a vibrating sieve, and a centrifugal dehydrator.
However, the apparatus disclosed in Patent Document 2 also requires a sieve, a vibrating sieve, and a centrifugal dehydrator separately from the mesh conveyor for transferring the sand. There is a problem of needing.
In addition to the sand transfer process using a mesh conveyor, a dehydration process using a sieve, a vibrating sieve, and a centrifugal dehydrator is required, which causes a problem of poor processing efficiency.

JP 2002-192198 A JP 2001-54728 A

  The present invention has been made to solve the above-described problems of the prior art, and can greatly reduce the moisture content of wet powder such as sand after wet classification, and can be dried after dehydration. The process can be omitted and the product shipping cycle can be shortened, while the wet powder can be dehydrated simultaneously with a single device, and it does not require a large installation space and is highly processed. It is an object of the present invention to provide a wet powder transfer dehydration apparatus that can achieve efficiency.

  The invention according to claim 1 includes a transfer means for transferring the wet powder, and a dehydrating means for removing the moisture of the wet powder transferred by the transfer means, the transfer means being a net-like endless The dewatering means is disposed between the upper belt and the lower belt of the endless belt, and is arranged between the upper belt and the lower belt of the conveyor. The present invention relates to a wet powder transfer and dehydration apparatus comprising a water receiving container for storing water that has passed and dropped, and suction means for decompressing the inside of the water receiving container.

  According to a second aspect of the present invention, the conveyor includes a support member that supports a lower surface of an upper belt of the endless belt, and the support member extends in a width direction of the endless belt and has a length of the endless belt. The shaft body has a plurality of shaft bodies arranged at predetermined intervals in the direction, and the shaft body has alternately a large diameter portion and a small diameter portion in the length direction, and the surface of the large diameter portion is the upper side 2. The wet powder transfer dewatering device according to claim 1, wherein the wet powder transfer dewatering device is rotatably in contact with the lower surface of the belt.

  The invention according to claim 3 is characterized in that, in the length direction of the endless belt, a large diameter portion of one shaft body is arranged side by side with a small diameter portion of another adjacent shaft body. It relates to the described wet powder transfer dehydration apparatus.

  According to a fourth aspect of the present invention, there is provided the wet powder transfer dehydrating apparatus according to the second or third aspect, wherein the large diameter portion is made of a bearing roller, and the surface of the bearing roller is made of an elastic material.

  In the invention according to claim 5, the endless belt is made of a wire mesh, sprockets are attached to both ends of the starting end side rotating body and the terminal end side rotating body, and a chain is stretched over the sprocket. The wet powder transfer dehydration apparatus according to any one of claims 1 to 4, wherein

  The invention according to claim 6 is the wet powder transfer dehydration according to any one of claims 1 to 5, characterized in that an elastic material is lined on a surface of the starting end side rotating body and the terminal end side rotating body. Relates to the device.

  In the invention according to claim 7, a plurality of the water receiving containers are arranged in the length direction of the endless belt, and a suction port connected to the suction means is connected to each of the plurality of water receiving containers. The wet powder transfer dehydration apparatus according to claim 1, wherein the wet powder transfer dehydration apparatus is provided.

  The invention according to claim 8 relates to the wet powder transfer and dehydration apparatus according to any one of claims 1 to 7, further comprising a first nozzle that injects cleaning water onto the endless belt.

  In the invention according to claim 9, the lower belt of the endless belt has a downward extending portion that is lowered downward in a part in the length direction, and the first nozzle is in the downward extending portion. 9. The wet powder transfer dewatering device according to claim 8, wherein cleaning water is jetted from above the lower belt.

  According to a tenth aspect of the present invention, the water receiving container is inclined so that a bottom surface thereof is lowered from one side in the width direction of the endless belt toward the other side, and the suction port is provided on the other side. The wet powder transfer dewatering device according to any one of claims 7 to 9, wherein

  The invention according to claim 11 is the wet powder transfer according to claim 10, wherein the water receiving container is formed so that the width of the bottom surface becomes narrower from the one side toward the other side. The present invention relates to a dehydrator.

  According to a twelfth aspect of the present invention, the water is injected to the side surface on the one side of the water receiving container from the one side of the water receiving container toward the other side and inclined toward the bottom surface. The wet powder transfer dewatering device according to claim 10 or 11, further comprising a nozzle.

  A thirteenth aspect of the present invention relates to the wet powder transfer dewatering device according to the eighth or ninth aspect, further comprising an air nozzle that injects air to the endless belt.

  The invention according to claim 14 is provided with rubber flanges standing on both sides in the width direction of the endless belt and extending along the length direction and rotating together with the endless belt. The wet powder transfer dehydration apparatus according to any one of the above.

  The invention according to claim 15 relates to the wet powder transfer dewatering device according to claim 14, characterized in that the rubber flange is formed in a corrugated cross-sectional shape.

According to the first aspect of the present invention, the apparatus includes a transfer unit that transfers the wet powder and a dehydrating unit that removes moisture from the wet powder transferred by the transfer unit. Can be dehydrated at the same time while transferring the wet powder. Therefore, the installation space of the apparatus can be reduced, and the processing efficiency can be increased by reducing the number of steps.
Further, the transfer means comprises a conveyor formed by wrapping a net-like endless belt over the starting end side rotating body and the terminal end side rotating body, and the dewatering means is disposed between the upper belt and the lower belt of the endless belt. Since it has a water receiving container for storing water that has passed through the mesh of the upper belt and a suction means for decompressing the inside of the water receiving container, it is transferred by decompressing the inside of the water receiving container by the suction means. The moisture of the wet powder inside can be sucked out from the mesh of the upper belt into the water receiving container. Therefore, the moisture content of the wet powder can be greatly reduced, the drying step after dehydration can be omitted, and the product shipping cycle can be accelerated.

According to the invention of claim 2, since the conveyor includes a support member that supports the lower surface of the upper belt of the endless belt, the endless belt can be prevented from being bent by the weight of the wet powder, and the weight Even a large amount or a wet powder can be smoothly transferred by a conveyor.
The support member includes a plurality of shaft bodies that extend in the width direction of the endless belt and are arranged at predetermined intervals in the length direction of the endless belt. The shaft body has a large diameter portion and a small diameter portion in the length direction. Can be alternately dropped through the gap formed between the adjacent shafts. Therefore, dehydration is not hindered by the support member, and the support member does not hinder the water sucking action by the suction means.
Furthermore, since the surface of the large diameter portion is rotatably in contact with the lower surface of the upper belt, the large diameter portion rotates while contacting with the movement of the upper belt due to the rotation of the endless belt. Therefore, friction between the upper belt and the support member hardly occurs, and wear of the upper belt can be prevented.

  According to the invention according to claim 3, in the length direction of the endless belt, the large-diameter portion of one shaft body is arranged side by side with the small-diameter portion of another adjacent shaft body. Thus, the support force of the endless belt can be increased, and the effect of preventing the endless belt from bending can be increased while maintaining the dewatering function.

  According to the invention of claim 4, the large diameter portion is made of a bearing roller, and the surface of the bearing roller is made of an elastic material, so that the surface of the large diameter portion is prevented from slipping with respect to the lower surface of the upper belt. In addition, the large-diameter portion can be rotated very smoothly, and the endless belt can be prevented from being damaged.

According to the invention of claim 5, since the endless belt is made of a wire mesh, the strength such as the tensile strength is increased, and it becomes possible to load and transport a large amount or a heavy wet powder.
In addition, since sprockets are attached to both ends of the start-side rotator and the end-side rotator and a chain is stretched over the sprocket, the endless belt can be reliably and smoothly rotated without meandering. This can prevent the endless belt from being worn.

  According to the sixth aspect of the present invention, since the elastic material is lined on the surface of the starting end side rotating body and the terminal end side rotating body, the starting end rotating body and the terminal end side rotating body are in contact with the surface during rotation. The elongation of the endless belt in contact can be suppressed.

  According to the invention of claim 7, a plurality of water receiving containers are arranged side by side in the length direction of the endless belt, and a suction port connected to the suction means is provided in each of the plurality of water receiving containers. Therefore, it is possible to reduce the capacity of each water receiving container, and it is possible to sufficiently reduce the pressure of each water receiving container by the suction means, over the substantially entire length in the length direction of the endless belt. Dehydration can be performed reliably, and a high dehydration ability can be obtained.

  According to the eighth aspect of the invention, since the first nozzle for injecting the cleaning water onto the endless belt is provided, the foreign matter clogged in the mesh of the endless belt can be removed by the cleaning water, which is excellent. It becomes possible to maintain a dehydration function over a long period of time.

  According to the ninth aspect of the present invention, the lower belt of the endless belt has the lower extending portion that is lowered downward in a part of the length direction, and the first nozzle is the lower belt at the lower extending portion. Since the cleaning water is jetted from above, the distance from the first nozzle to the lower belt can be secured, and the cleaning can be performed over a wide range with a small number of first nozzles.

  According to the invention of claim 10, the water receiving container is inclined such that the bottom surface is lowered from one side in the width direction of the endless belt toward the other side, and the suction port is provided on the other side. Therefore, the water accumulated in the water receiving container can be guided along the slope to the suction port. Therefore, water can be efficiently recovered from the suction port, and the cleaning water can be easily recycled.

  According to the invention of claim 11, the water receiving container is formed so that the width of the bottom surface becomes narrower from one side to the other side, so that the suction port provided on the other side is not enlarged. The water collected in the water receiving container can be efficiently guided to the suction port.

  According to the twelfth aspect of the present invention, the second nozzle for injecting water on the side surface on one side of the water receiving container is inclined from the one side of the water receiving container toward the other side and toward the bottom surface. Therefore, foreign matter such as mud that has passed through the upper belt and accumulated at the bottom of the water receiving container can flow along the slope along with the water and be discharged from the suction port to the outside.

  According to the invention according to claim 13, since the air nozzle for injecting air to the endless belt is provided, it is possible to use both the injection of cleaning water from the first nozzle and the injection of air from the air nozzle, It is possible to more reliably remove foreign matters clogged in the mesh of the endless belt.

  According to the fourteenth aspect of the present invention, since the endless belt is provided with the rubber flanges standing on both sides in the width direction and extending along the length direction and rotating together with the endless belt, From the direction), and even a wet solid that can easily flow out can be transported.

  According to the fifteenth aspect of the present invention, since the rubber flange has a corrugated cross section, the rigidity of the rubber flange can be increased, and when a strong force is applied from the side, the deformation of the corrugation Can be absorbed.

It is a top view of the wet powder transfer dehydration device concerning the present invention. It is front sectional drawing of the wet powder transfer dehydration apparatus which concerns on this invention. It is sectional drawing of the left side of the wet powder transfer dehydration apparatus which concerns on this invention. (A) is A section sectional drawing of FIG. 2, (b) is B section sectional drawing of FIG. It is a principal part enlarged view of FIG.4 (b).

Hereinafter, a preferred embodiment of a wet powder transfer dehydrator according to the present invention will be described with reference to the drawings.
FIG. 1 is a plan view of a wet powder transfer dehydrator according to the present invention, FIG. 2 is a front sectional view of the wet powder transfer dehydrator according to the present invention, and FIG. 3 is a left side of the wet powder transfer dehydrator according to the present invention. 4A is a cross-sectional view of part A of FIG. 2, FIG. 4B is a cross-sectional view of part B of FIG. 2, and FIG. 5 is an enlarged view of a main part of FIG.

The wet powder transfer dehydration apparatus according to the present invention comprises a transfer means (1) for transferring wet powder and a dehydration means (2) for removing moisture from the wet powder transferred by the transfer means (1). I have.
The transfer means (1) is formed of a belt conveyor formed by spanning a net-like endless belt (3) over a starting end side rotating body (4) and a terminal end side rotating body (5).
The dewatering means (2) is disposed between the upper belt (31) and the lower belt (32) of the endless belt (3), and stores water that has dropped through the mesh of the upper belt (31). A receiving container (6) and suction means (not shown) for reducing the pressure in the water receiving container (6) are provided.

The endless belt (3) is a mesh belt that transports wet powder on the surface of the upper belt (31). The mesh size is such that water can pass through but the powder having a predetermined particle size or larger is passed through. The size is set so that it cannot pass. For example, when it is desired to transfer sand having a particle size of 0.15 mm or more as powder, the mesh size is set to a size that allows passage of 0.15 mm or more.
In FIG. 1, the mesh of the endless belt (3) is drawn only in the vicinity of the start end and near the end, and the other portions are members (a support member and a water receiving container) disposed below the upper belt (31). ) Is omitted for the sake of simplicity.
As the endless belt (3), an appropriate one may be selected according to the type (weight, etc.) of the wet powder, but a belt made of a wire mesh is preferably used. When a belt made of a metal mesh is used as the endless belt (3), the tensile strength and the like become high, so that even if the wet powder is heavy, it can be transported, and a large amount of wet powder is placed at once. Can be transferred.
As a suitable example of the endless belt (3), a belt made of a SUS metal mesh (wire diameter: 0.35 mm) having a mesh opening of 0.4 mm can be used.

The start-side rotator (4) and the end-side rotator (5) are cylindrical pulleys, and sprockets (41) and (51) are attached to both ends of the pulleys. The chain (7) is suspended between (51).
A second sprocket (42) is mounted coaxially with the sprocket (41) on the rotating shaft of the starting end side rotating body (4).
A chain (9) is stretched between the second sprocket (42) and a sprocket (81) attached to a rotating shaft of a motor (8) installed above the endless belt (3). Thus, when the motor (8) is driven to rotate the rotating shaft, the rotation is transmitted to the second sprocket (42) via the sprocket (81) and the chain (9), and the starting end side rotating body (4). Rotates, and the endless belt (3) rotates accordingly.
Thus, by rotating the endless belt (3) using a chain and a sprocket as a power transmission mechanism, the endless belt (3) can be reliably and smoothly rotated without meandering, and the endless belt (3 ) Can be prevented.

The starting end side rotator (4) and the end side rotator (5) are lined with an elastic material such as rubber.
Since the elastic material is lined on the surface of the starting end side rotating body (4) and the terminal end side rotating body (5), these rotations occur when the starting end side rotating body (4) and the terminal end side rotating body (5) rotate. The elongation of the endless belt (3) contacting the body surface can be suppressed. That is, during the rotation of the starting end side rotating body (4) and the terminal end side rotating body (5), the endless belt (3) tends to be stretched by applying a tensile force, but the elastic material abuts to suppress the stretching. Can do.

The conveyor which comprises a transfer means (1) is provided with the supporting member (10) which supports the lower surface of the upper belt (31) of an endless belt (3).
A support member (10) consists of a shaft body which has a large diameter part (10a) and a small diameter part (10b) alternately in a length direction.
The large diameter portion (10a) is formed of a bearing roller whose surface is made of an elastic material such as polyurethane. The bearing roller is externally fitted and fixed at a predetermined interval in the length direction of the cylindrical shaft body, and a portion where the bearing roller is externally fitted becomes a large diameter portion (10a), and the bearing roller is externally fitted. The part which does not have becomes a small diameter part (10b).
In the length direction of the support member (10), the length of the large diameter portion (10a) is shorter than the length of the small diameter portion (10b).

The support member (10) extends in the width direction of the endless belt (3), and a plurality of support members (46 in the illustrated example) are arranged at predetermined intervals in the length direction of the endless belt (3). Yes.
In the support member (10), the surface of the large diameter portion (10a) is in contact with the lower surface of the upper belt (31). Here, since the large diameter portion (10a) is composed of a bearing roller, the large diameter portion (10a) rotates with the movement of the upper belt (31).
As a result, the friction between the surface of the large diameter portion (10a) and the lower surface of the upper belt (31) can be made extremely small, and the upper belt (31) can be prevented from being worn or damaged. It is.
Further, since the surface of the large-diameter portion (bearing roller) (10a) is made of an elastic material such as polyurethane, the surface of the large-diameter portion (10a) is prevented from sliding against the lower surface of the upper belt (31). The large diameter portion (10a) can be rotated very smoothly, and the upper belt (31) can be prevented from being damaged.

Since the lower surface of the upper belt (31) of the endless belt (3) is supported by the plurality of support members (10) as described above, the upper belt (31) is bent by the weight of the wet powder transferred. It is possible to prevent a large amount of wet powder from being smoothly transferred by a conveyor.
The support member (10) is composed of a plurality of shaft bodies arranged at predetermined intervals in the length direction of the endless belt (3), and the shaft body has a large diameter portion (10a) and a small diameter portion in the length direction. Since (10b) are alternately provided, the water (water contained in the wet powder) that has passed through the mesh of the upper belt (31) can be dropped through the gap between the adjacent shafts. Therefore, dehydration is not hindered by the support member (10), and the sucking-out action of the suction means described later is not hindered by the support member.

As shown in FIG. 1, the support member (10) includes a small diameter portion (10 b) of another shaft body adjacent to the large diameter portion (10 a) of one shaft body in the length direction of the endless belt (3). They are arranged side by side.
Thereby, the clearance gap between adjacent shaft bodies can be made small and the supporting force of an endless belt (3) can be improved, and the bending prevention effect of an endless belt (3) can be improved, maintaining a spin-drying | dehydration function.

A plurality (three in the illustrated example) of the water receiving container (6) are arranged without gaps in the length direction of the endless belt (3). The plurality of water receiving containers (6) may be formed separately or integrally.
The water receiving container (6) includes a suction port (61) to which suction means is connected on each side surface (the other side surface described later).
In this way, a plurality of water receiving containers (6) are arranged side by side, and each of the plurality of water receiving containers (6) is provided with a suction port (61) connected to the suction means. The capacity of the water receiving containers (6) can be reduced, and each water receiving container (6) can be sufficiently decompressed by the suction means. Thereby, dehydration can be reliably performed over substantially the entire length in the length direction of the endless belt (3), and a high dewatering capability is obtained.
The number of water receiving containers (6) can be appropriately changed according to the length of the endless belt (3) and the capacity of the suction means.

A known suction device such as a vacuum pump can be used as the suction means, and the suction device and the suction port (61) are connected by a suction hose through a filter or the like.
By driving the suction device, the water receiving container (6) is evacuated and decompressed. Thereby, the moisture of the wet powder transferred on the upper belt (31) is sucked out from the mesh of the upper belt into the water receiving container (6). As a result, the moisture content of the wet powder is greatly reduced (reduced to 10% or less), and the drying step after dehydration can be omitted. Further, the water accumulated in the water receiving container (6) is sucked out from the suction port (61) together with the air, and is reused as cleaning water or the like which will be described later.

Furthermore, the wet powder transfer dewatering device according to the present invention includes a first nozzle (11) for injecting cleaning water (W1) to the endless belt (3).
As shown in FIG. 4B, a plurality of (three in the illustrated example) first nozzles (11) are provided along the width direction of the endless belt (3). Then spray the washing water from above. As a result, foreign matter clogged in the mesh of the endless belt (3) can be removed by the washing water, and an excellent dewatering function can be maintained for a long period of time.

As shown in FIG. 2, the lower belt (32) has a downward extending portion (32 a) that is lowered downward in a part in the length direction. This downward extension part (32a) is formed by spanning a chain (7) under the sprocket (41) and the sprocket (44) arranged below the sprocket (51). Further, the sprocket (43) arranged on the start end side from the sprocket (44) plays a role of holding down the start end side of the downward extending portion (32a) so as not to be loosened downward.
The first nozzle (11) injects wash water (W1) from above the lower belt (32) in the lower extension portion (32a). (See Fig. 2 and Fig. 4 (b))
Thereby, the distance from a 1st nozzle (11) to a lower belt (32) can be ensured, and it becomes possible to wash | clean over a wide range with a small number of 1st nozzles (11).

As shown in FIG. 4B, an air nozzle (12) for injecting air (A) to the endless belt (2) is provided behind and slightly below the first nozzle (11). In FIGS. 2 and 4 (b), the washing water supply pipe to the first nozzle (11) is denoted by reference numeral (11a), and the air supply pipe to the air nozzle (12) is denoted by reference numeral (12a). Yes.
As shown in FIG. 4B, a plurality (11 in the illustrated example) of air nozzles (12) are provided along the width direction of the endless belt (3), and below the downward extending portion (32a). Air (A) is jetted onto the belt (32) from above.
Thereby, the washing water (W1) injection from the first nozzle (11) and the air (A) injection from the air nozzle (12) can be used together, and the foreign matter clogged in the mesh of the endless belt (3) can be removed. It can be removed more reliably.

As shown in FIG. 4 (a), the water receiving container (6) has a bottom surface on one side in the width direction of the endless belt (3) (left side in FIG. 4 (a)) to the other side (right side in FIG. 4 (a)). The suction port (61) is provided on the other side surface.
Thereby, the water accumulated in the water receiving container (6) can be guided along the slope to the suction port (61). Therefore, water can be efficiently recovered from the suction port (61), and cleaning water can be easily recycled.

As shown in FIG. 4A, water (W2) is inclined on the side surface of one side of the water receiving container (6) from one side to the other side of the water receiving container (6) and toward the bottom surface. ) Is ejected from the second nozzle (13). In FIG. 4 (a), the reference numeral (13a) is attached to the washing water supply pipe to the second nozzle (13).
As a result, foreign matter such as mud that has passed through the upper belt (31) and accumulated at the bottom of the water receiving container (6) is caused to flow down along the slope together with the water and is discharged from the suction port (61) to the outside. be able to.

The water receiving container (6) is formed so that the width of the bottom surface becomes narrower from one side to the other side (see the broken line across the endless belt (3) in FIG. 1).
Thereby, the water accumulated in the water receiving container (6) can be efficiently guided to the suction port (61) without increasing the suction port (61) provided on the other side.

Side wall plates (14) extending along the length direction of the endless belt (3) are provided above both ends of the endless belt (3) in the width direction.
The side wall plate (14) is made of a metal plate and is provided along the upper belt (31). The side wall plate (14) is fixed to the apparatus main body and does not rotate together with the endless belt (3).
The side wall plate (14) is provided such that the lower portion is slightly perpendicular to the upper surface of the upper belt (31) and substantially perpendicular to the upper surface, and the upper portion expands outward as it goes upward. Is formed.
Providing such a side wall plate (14) prevents the wet powder from overflowing from above the upper belt (31). In addition, since there is a gap between the upper surface of the upper belt (31), the upper belt (31) can be prevented from being damaged.

Rubber flanges (15) extending along the length direction of the endless belt (3) are provided on both sides in the width direction of the endless belt (3) and outside the side wall plate (14).
The rubber flange (15) is made of synthetic rubber such as neoprene rubber or natural rubber, and is provided along the upper belt (31) and the lower belt (32). The rubber flange (15) is erected and fixed to the upper part of a belt-like cover (16) provided so as to make a round along both ends in the width direction of the endless belt (3), and rotates together with the endless belt (3). .
The rubber flange (15) covers the gap in the height direction formed between the side wall plate (14) and the upper surface of the upper belt (31) from the outside in the width direction.
Thereby, even if the moisture contained in the wet powder passes through the gap formed between the side wall plate (14) and the upper surface of the upper belt (31), it leaks to the side of the endless belt (3). Can be prevented.

As shown in FIG. 1, the rubber flange (15) has a waveform in a plan view (cross-sectional shape).
Thereby, while being able to improve the rigidity of a rubber flange (15), when a strong pressure is applied from the side, it can absorb by deformation of a waveform.

As shown in FIG. 5, attachments (17) can be attached to the chain (7) at any chain pitch (every other pitch in FIG. 5). In FIG. 5, a plan view of the chain (7) is shown above for easy understanding of the description.
The attachment (17) is a member having an L-shaped longitudinal section, the vertical portion is fixed to the side surface (inner surface) of the chain (7), and the horizontal portion is the lower surface of the belt-like cover (16) via the spacer (18). It is fixed to.
The spacer (18) is provided to match the height positions of the chain center (7a) and the endless belt (3) (only the upper belt (31) is shown in FIG. 5).

Sand having a particle diameter of 0 to 10 mm (water content 50%) was treated using the wet powder transfer dehydrator according to the present invention shown in FIGS.
As the endless belt (3), a SUS metal mesh (wire diameter: 0.35 mm) having a width of 1085.2 mm, a length of 3000 mm, and a mesh opening of 0.4 mm was used, and the conveyance speed was 20 m / min.
As a result of measuring the water content of the treated sand, the water content was 10%. This could be shipped without further drying steps.

  The wet powder transfer dehydration apparatus according to the present invention is preferably used for transferring and dewatering sand after wet classification and after washing, but the object to be treated is not limited to sand, and waste (sludge, It can be widely used for various types of wet powders such as food waste (food waste, etc.) and foods (rice, vegetables, processed foods, etc.).

DESCRIPTION OF SYMBOLS 1 Transfer means 2 Dehydration means 3 Endless belt 31 Upper belt 32 Lower belt 32a Lower extension part 4 Start end side rotary body 41 Sprocket 5 End side rotary body 51 Sprocket 6 Water receiving container 61 Suction port 7 Chain 10 Support member 10a Large diameter part 10b Small diameter portion 11 First nozzle 12 Air nozzle 13 Second nozzle 14 Side wall plate 15 Rubber flange A Air W1 Washing water (first nozzle)
W2 Wash water (second nozzle)

Claims (15)

A transfer means for transferring the wet powder, and a dehydrating means for removing the moisture of the wet powder transferred by the transfer means,
The transfer means is composed of a conveyor formed by spanning a net-like endless belt over a starting end side rotating body and a terminal end side rotating body,
The dewatering means is disposed between an upper belt and a lower belt of the endless belt, and stores a water receiving container that stores water dropped through the mesh of the upper belt, and depressurizes the water receiving container. A wet powder transfer dewatering device comprising a suction means. The conveyor includes a support member that supports the lower surface of the upper belt of the endless belt,
The support member is composed of a plurality of shafts that extend in the width direction of the endless belt and are arranged at predetermined intervals in the length direction of the endless belt,
The shaft body has alternately large-diameter portions and small-diameter portions in the length direction, and the surface of the large-diameter portion is in contact with the lower surface of the upper belt so as to be rotatable. The wet powder transfer dehydrator according to claim 1.   3. The wet powder transfer dewatering device according to claim 2, wherein a large diameter portion of one shaft body is arranged side by side with a small diameter portion of another adjacent shaft body in the length direction of the endless belt. . The large diameter portion is composed of a bearing roller,
4. The wet powder transfer dewatering device according to claim 2, wherein the bearing roller has a surface made of an elastic material. The endless belt is made of a wire mesh;
The wet according to any one of claims 1 to 4, wherein sprockets are attached to both ends of the starting end side rotating body and the terminal end side rotating body, and a chain is stretched over the sprocket. Powder transfer dehydrator.   The wet powder transfer dewatering device according to any one of claims 1 to 5, wherein an elastic material is lined on a surface of the starting end side rotating body and the terminal end side rotating body. A plurality of the water receiving containers are arranged in the length direction of the endless belt,
The wet powder transfer dewatering device according to any one of claims 1 to 6, wherein a suction port connected to the suction means is provided in each of the plurality of water receiving containers.   The wet powder transfer dewatering device according to any one of claims 1 to 7, further comprising a first nozzle for injecting cleaning water onto the endless belt. The lower belt of the endless belt has a downward extending portion that is lowered downward in a part in the length direction,
The wet powder transfer dewatering device according to claim 8, wherein the first nozzle ejects cleaning water from above the lower belt at the lower extension portion.   The water receiving container is inclined such that a bottom surface thereof is lowered from one side in the width direction of the endless belt toward the other side, and the suction port is provided on the other side. The wet powder transfer dehydrator according to any one of 7 to 9.   The wet powder transfer dewatering device according to claim 10, wherein the water receiving container is formed so that a width of a bottom surface becomes narrower from the one side toward the other side.   A second nozzle that injects water on the side surface of the one side of the water receiving container inclined from the one side of the water receiving container toward the other side and in the direction of the bottom surface is provided. The wet powder transfer dewatering device according to claim 10 or 11.   The wet powder transfer dewatering device according to claim 8 or 9, further comprising an air nozzle for injecting air to the endless belt.   14. The wet powder according to any one of claims 1 to 13, further comprising rubber flanges standing on both sides in the width direction of the endless belt and extending along the length direction and rotating together with the endless belt. Transfer dehydrator.   15. The wet powder transfer dewatering device according to claim 14, wherein the rubber plate is formed in a corrugated cross-sectional shape.

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