JP2008012524A - Solid-liquid separator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solid-liquid separator which is capable of optionally changing the conveyance pitch in accordance with the fluid properties of a material to be treated (sludge) and of conducting various sludge treatments by one device to increase the usability of users. <P>SOLUTION: In the solid-liquid separator, an outer barrel 17 is constituted as a fixed member by inserting a fixed plate 21 having an opening to a long bolt 19, and a movable member 18 is constituted by inserting a conveyance plate 29 having an opening to a cross-section polygonal shaft 25 to be rotatively driven by a motor 13 and a spacer 28. A spiral step conveyance vane is constituted by a part of the conveyance plate 29 and the spacer 28 by inserting each conveyance plate 29 and spacer 28 in the position shifted to the peripheral direction. Flocculation sludge charged from an inflow box 12 is conveyed while being compressed by the spiral step conveyance vane and is discharged from the exit. The cloggings are prevented by the rotation movement accompanied by the vertical variation of the conveyance plate 29 because the conveyance plate 29 and spacer 28 are eccentrified to the shaft 25. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to solids and moisture contained in sludge (including concepts such as livestock manure, oil-containing sludge generated from wastewater treatment of food factories, surplus sludge generated from sewage treatment, inorganic sludge generated from construction sites, etc.) The present invention relates to a solid-liquid separation device that separates.

This type of sludge contains a large amount of moisture, and it is difficult to process compost etc. as it is (raw water). Therefore, it is dehydrated by a solid-liquid separation device after flocking, and the water content is about 80%. It is done to make a dehydrated cake.
Conventionally, various methods have been proposed as a method for dewatering sludge (treatment target). For example, a screw press type method is known. The filter body is configured by providing a screw conveyor in which a spiral blade is fixed to a shaft in a fixing member (stator) obtained by processing a plate having good water drainage such as a punching plate into a cylindrical shape. An object to be treated is introduced from one end side of the steel plate, the screw conveyor is rotated at a low speed, and moisture is allowed to flow down from the hole of the fixed member while conveying the solid material in the axial direction.
Sufficient internal pressure can be obtained by reducing the screw pitch toward the other end side (outlet side) of the filter body and providing a plate that regulates the amount of solid matter discharged from the outlet. A high dehydration rate with a water content of about 80% can be obtained.
However, since the punching plate is likely to be clogged, it is necessary to frequently clean the punching plate as the outer cylinder, and there is a problem that a large amount of cleaning water is required and the cleaning operation is troublesome.

In Patent Document 1, a large number of fixing rings are arranged in an axial direction at intervals to form a cylindrical fixing member, and a movable ring is arranged between the fixing rings. A solid-liquid separation device is described in which a screw conveyor is provided in an internal space to constitute a filter body.
The inner diameter of the movable ring is set slightly smaller than the outer diameter of the screw conveyor. When the screw conveyor rotates, sludge is transported in the axial direction, and moisture is discharged to the outside through a minute gap between the movable ring and the fixed ring. .
Due to the rotation of the screw conveyor, the movable ring is pushed up and swung in a direction orthogonal to the axial direction, thereby preventing clogging of the solid content in the gap between the fixed ring and the movable ring.
That is, the clogging prevention operation is also performed at the same time by utilizing the rotation operation of the screw conveyor.

JP-A-5-228695 JP 2005-169323 A

In the configuration described in Patent Document 1, since the clogging is prevented by utilizing the rotational operation of the screw conveyor, an exclusive power source for preventing clogging is not required, and the above-described cleaning problem can be solved. Have.
However, the outer edge (edge) of the spiral blade of the screw conveyor always repeats metal contact with the inner peripheral surface of the movable ring, so when the inner diameter of the movable ring increases over time and becomes equal to the inner diameter of the fixed ring. In this case, the movable ring is not swung, and the function of preventing clogging is lost.
In order to solve this problem, the wear state of the movable ring and the screw conveyor must be periodically checked, and if the wear is large, the wear ring must be replaced, which increases the maintenance cost.

Further, in this type of solid-liquid separation apparatus, there is an optimum apparatus specification depending on the type of the processing object (flow characteristics, etc.), and if the processing object is different, for example, the pitch of the screw conveyor must be changed. Don't be.
However, in the conventional apparatus, when changing the pitch, a new screw conveyor has to be purchased, and when the standard is not met, it is necessary to replace the entire apparatus.

In addition, as a common drawback of the conventional screw conveyor system, when sludge containing a large amount of fibrous impurities such as livestock wastewater or dust control wastewater is dehydrated, fiber tangles have occurred on the screw shaft.
The more the internal pressure is generated inside the filter body, that is, the higher the dehydrating function is, the more the solid matter is compressed in the fiber layer entangled with the shaft, and the solid matter adheres to substantially increase the shaft diameter.
When the shaft diameter is increased, the volume of the conveyance path in the filter body is inevitably reduced, so that it is impossible to supply sludge having a specified capacity, resulting in a reduction in processing efficiency.
In this case, in order to recover the processing efficiency, it is necessary to remove the shaft and remove the fiber layer and the solid matter adhering to the shaft from the shaft, but the shaft is provided with a spiral blade integrally. The removal work was troublesome.
In addition, this type of solid-liquid separator generally requires ease of disassembly and assembly from the viewpoint of overhaul, maintenance, cleaning, and the like.

  An object of the present invention is to provide a solid-liquid separation apparatus that can solve at least one or all of the above-described problems.

  In order to achieve the above object, according to the first aspect of the present invention, there is provided a filter body provided with a movable member exhibiting a screw conveyor function inside a cylindrical fixed member, and driving means for rotationally driving the movable member. In the solid-liquid separator that dewaters the sludge fed from one end of the filter body while dehydrating it and discharging it to the other end, the movable member includes a rotating shaft and an axially stacked state on the rotating shaft. A plurality of detachable transport plates arranged and supported, wherein the transport plates are positioned by shifting each transport plate at a substantially constant interval in the circumferential direction within a plane substantially perpendicular to the axial direction of the rotating shaft. By fixing, it has a shape capable of forming a conveyance path and a spiral stepped conveyance blade continuously connected in the axial direction.

According to a second aspect of the present invention, in the solid-liquid separation device according to the first aspect, the transport plate extends from the outside toward the rotation center portion with respect to the rotation shaft. It has a protruding edge having an insertion hole, and the protruding edge is continuously connected to form the spiral stepped conveying blade.
According to a third aspect of the present invention, in the solid-liquid separator according to the second aspect, the rotating shaft and the insertion hole of the protruding edge have a relative engagement structure, and when the shaft is inserted through the rotating shaft, The position of the conveyance plate in the circumferential direction with respect to the rotation axis is fixed.

According to a fourth aspect of the present invention, in the solid-liquid separation device according to the third aspect, a plurality of circumferentially fixed positions are provided at predetermined angular intervals, and the pitch of the spiral stepped conveying blades can be changed. It is characterized by that.
According to a fifth aspect of the present invention, in the solid-liquid separator according to any one of the second to fourth aspects, a spacer that forms the spiral staircase-shaped conveying blades together with the protruding edges is disposed between the conveying plates. It is characterized by.
According to a sixth aspect of the present invention, in the solid-liquid separator according to the fifth aspect, the spacer is formed integrally with the protruding portion of the transport plate.

According to a seventh aspect of the present invention, in the solid-liquid separation device according to the fifth aspect, the spacer has a shape equivalent to the protruding edge, and is arranged to alternately pass through the rotation plate and the transport plate. It is characterized by that.
According to an eighth aspect of the present invention, in the solid-liquid separation device according to any one of the fifth to seventh aspects, the fixing member has a plurality of openings having an opening portion and spaced apart in the axial direction of the rotating shaft. The fixing plates are arranged so as to cover the outer periphery of the rotation locus of the spacer.
According to a ninth aspect of the present invention, in the solid-liquid separator according to the eighth aspect, in the axial direction of the rotating shaft, the thickness of the spacer is St, the thickness of the fixed plate is Kt, and the thickness of the transport plate is Ft. In this case, the relationship of St>Kt> Ft is satisfied.

According to the present invention, the spiral staircase blades corresponding to the screw conveyor can be formed by the laminated configuration in which the circumferential positions of the plurality of transport plates are shifted. Therefore, the blade pitch can be arbitrarily set according to the flow characteristics of the processing object. Therefore, it is possible to obtain a treatment function suitable for sludge characteristics or user characteristics without purchasing a new screw conveyor.
Since there is no member contact such as metal contact in the rotating operation of the movable member, the maintenance cost can be greatly reduced.

Since the movable member and the spiral staircase blade can be finely disassembled, maintenance, overhaul and cleaning can be performed with high accuracy. Since there is no heavy load such as a screw conveyor, it is easy to disassemble and assemble with little effort.
Even if the fibers are entangled, the screw conveyor-like configuration can be finely disassembled, so that the removal operation becomes easy.
The conveyance force can be improved by the presence of the spacer.
Since almost the entire assembly is performed simply by inserting the transport plate and the spacer through the rotating shaft, the assembling / disassembling performance is greatly improved as compared with the case where each part is fixed.
Since the pitch of the spiral staircase blades can be changed simply by changing the circumferential positions of the transport plate and the spacer, the pitch can be easily changed.
When the spacer is integrally formed, the number of parts can be reduced, and assembly / disassembly is further facilitated.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, a solid-liquid separator 10 according to the present embodiment is provided with a filter body 11 for dewatering sludge, and one end side (inlet side) of the filter body 11, and flocated sludge is input. An inflow box 12 to be performed, a motor 13 as a driving means that is provided on the other end side (exit side or discharge side) of the filter body 11 and rotationally drives a movable member (described later) provided in the filter body 11, Similarly, it is provided on the other end side of the filter body 11, and includes a pressure adjusting means 14 for adjusting the pressure inside the filter body 11 by limiting the discharge capacity on the outlet side, and an L-shaped plate for supporting the filter body 11. It has three support bodies 15 and a motor fixing plate 16 to which the motor 13 is fixed.
The solid-liquid separation device 10 here is a horizontal installation type that is substantially parallel to the floor surface.

The filter body 11 has an outer cylinder 17 as a fixed member having a rectangular tube shape, and a movable member 18 provided inside the outer cylinder 17.
As shown in FIG. 2, the outer cylinder 17 is configured by arranging a plurality of fixing plates 21 in a stacked state in the axial direction on three long bolts 19 supported by the support body 15, and the support body 15 on both sides and the center. It has a reinforced structure.
Therefore, the outer cylinder 17 is a rectangular tube body that can drain moisture in a direction orthogonal to the axial direction as a whole by a gap (described later) secured between the fixed plates 21.
One end of the long bolt 19 is fixed by a nut member 22 outside the support 15 on the right side in the drawing. The other end of the long bolt 19 is fixed by a nut member 22 outside the left support 15 fixed to the motor fixing plate 16.

As shown in FIG. 3, the support 15 includes a vertical portion 23 and a horizontal portion 24, and the vertical portion 23 includes a circular hole 23 a constituting a part of the sludge conveyance path, and a long bolt 19. The insertion hole 23b is formed. The horizontal portion 24 is formed with a fixing hole 24a for fixing to an apparatus main body frame (not shown).
The fixed plate 21 is formed with a circular hole 21a constituting a part of the sludge conveyance path in the center portion, and through holes 21b for the long bolts 19 are formed at three locations. The hole 21a of the fixing plate 21 and the hole 23a of the support 15 have substantially the same diameter.
As shown in FIG. 4, the fixed plate 21 is formed in a ring shape in which a peripheral edge portion 21c having a radial width w1 is connected, and each protruding piece 21d connected to the peripheral edge portion 21c at an interval of approximately 120 °. An insertion hole 21b is formed in the. The thickness Kt of the fixed plate 21 is set to about 2 mm.

As shown in FIG. 5, the movable member 18, which functions as a screw conveyor that conveys sludge, has an i-type spacer 28 and a conveying plate 29 on a shaft 25 having a polygonal cross section (here, a dodecagon) as a rotating shaft. Are alternately inserted, and a plurality of spacers 28 and transport plates 29 are arranged in a stacked state in the axial direction.
The movable member 18 has a cylindrical shape that allows moisture to escape in a direction orthogonal to the axial direction by a gap (described later) secured by the spacer 28.

As shown in FIG. 6, the transport plate 29 is formed in a disc shape as a whole, specifically, formed in a ring shape in which peripheral edge portions 29 a having a radial width w <b> 2 are connected, and a transport path is formed inside the transport plate 29. And a projecting edge 29d extending from the outer side (peripheral portion 29a) toward the center of rotation and having an insertion hole 29c for the shaft 25 at the center. The protruding edge 29d is composed of an insertion part 29d-1 and a sector part 29d-2.
The insertion hole 29c is formed in a dodecagon according to the outer shape (decagon) of the shaft 25.
The center h1 of the insertion hole 29c is more eccentric than the center h0 of the transport plate 29 as a disk by a dimension δ (here 2 mm). The thickness Ft of the transport plate 29 is set to about 1 mm.

As shown in FIG. 7, the spacer 28 has the same shape as the protruding edge 29 d of the transport plate 29. That is, it is composed of an insertion portion 28b having an insertion hole 28a for the shaft 25 and a sector portion 28c.
Similarly, the insertion hole 28 a is also formed in a dodecagon according to the outer shape of the shaft 25. The center h2 of the insertion hole 28a is also eccentric from the center h0 of the transport plate 29 as a disk by a dimension δ (here 2 mm). The thickness St of the spacer 28 is set to about 3 mm.

The insertion hole 28 a of the spacer 28 is shifted by a predetermined angle (here, 5 °) from the insertion hole 29 c of the transport plate 29 in the clockwise direction.
Therefore, as shown in FIG. 8, when the conveying plate 29 and the spacer 28 are sequentially inserted and overlapped with the shaft 25 in a state where the corresponding apex angles coincide with each other, the sector 28c of the spacer 28 and the protruding edge 29d of the conveying plate 29 are provided. The fan-shaped portion 29d-2 is shifted.
In the assembly, as shown in FIG. 3, the spacer 28 is first inserted and positioned in the hole 23 a of the left support 15, and then the conveying plate 29, the spacer 28, and the fixing plate 21 (the spacer 28 and the fixing plate 21 in order). In any case, the order may be any), and the transfer plate 29, spacers 28,...
Here, as shown in FIG. 9, one set of the conveyance plate 29 and the spacer 28 shown in FIG. 8 is arranged while being shifted at a substantially constant interval in the direction orthogonal to the axial direction. Here, since the shaft 25 is a dodecagon, for example, when the vertex angle position of the polygon is shifted one by one, it is shifted by 30 °.
Assembling is facilitated by attaching marks that can distinguish angular positions such as numbers, symbols, and the like around the insertion holes 29c, 28a of the transport plate 29 and the spacer 28. In this case, a mark may be attached to the shaft 25 and one mark may be attached to the reference position of the insertion holes 29c and 28a.

Since the polygons are engaged with each other, the spacers 28 and the transport plate 29 are fixed in the circumferential direction when they are inserted through the shaft 25. In the present embodiment, the outer surface of the shaft 25 has a polygonal shape, and the shapes of the insertion holes 29c and 28a of the transport plate 29 and the spacer 28 have a corresponding polygonal shape. However, the present invention is not limited to this. A convex portion may be formed on the hole side, and an engagement groove may be formed on the outer surface of the shaft. For example, it is possible to adopt a relative engagement structure between the insertion hole and the shaft, such as serration or spline engagement.
The shift positions (a) to (h) shown in FIG. 9 correspond to (a) to (h) in FIG. Thus, by arranging the transport plate 29 and the spacer 28 while shifting the positions in the circumferential direction, the protruding edge 29d of the transport plate 29 and the spacer 28 are continuously connected in the axial direction inside the movable member 18. A spiral staircase conveying blade is formed.
When the movable member 18 is rotated by the motor 13, the spiral staircase-shaped transport blades are rotated, and the transport function is the same as that of the screw conveyor.

In order to enhance the transport function, the angle of the spacer 28 with respect to the transport plate 29 is shifted as described above. By doing so, the multi-stage is promoted and the conveying force is increased as compared with the case where the protruding edge 29d of the conveying plate 29 and the spacer 28 substantially coincide.
In FIGS. 1 and 5, the vertical positions of the transport plate 29 are all displayed in the same manner. However, since they are eccentric as described above, they actually deviate within the range of the eccentric amount. .

The shape of the insertion hole 29c of the transport plate 29 may be a shape in which the apex angle is directly above as shown in FIG. In this case, as shown in FIG. 11, the insertion hole 28a of the spacer 28 has the corresponding vertex angle position shifted by 5 ° in the clockwise direction, and when inserted so that the corresponding vertex angles match each other, Similarly, the spacer 28 is removed.
In the present embodiment, the spacer 28 is a separate member from the transport plate 29, but may be formed integrally with the protruding edge 29d of the transport plate 29 by molding or injection molding.

As shown in FIGS. 12 and 13, the shaft 25 is formed of a drawn bar having a polygonal cross section (here, a dodecagon). As the number of corners increases, the pitch of the spiral conveying blades can be freely changed.
On the sludge inlet side of the shaft 25, a sludge pushing means 37 that promotes the feeding of the flocked sludge thrown into the inflow box 12 to the movable member 18 is provided.
The sludge pushing means 37 has a shaft portion 38 inserted and fixed to the shaft 25, and a spiral blade (feed blade) 39 fixed to the shaft portion 38 by means such as welding.
On the sludge outlet side of the shaft 25, although not shown, machine key groove processing for motor connection is performed. The position of the spacer 28 inserted through the shaft 25 and the transport plate 29 in the axial direction is fixed by a C-type retaining ring 28.
As shown in FIG. 13, bolt insertion holes 25 a and 38 a are formed at corresponding portions of the shaft 25 on the sludge inlet side and the shaft portion 38, and both are not shown by inserting the shaft 25 into the shaft portion 38. It is designed to be fixed integrally with a through bolt.
Thus, if it is set as the system integrated by inserting in the axial part 38 to which the spiral blade 39 was fixed previously, the spiral blade 39 can be formed in either side of the both ends of the shaft 25. Great freedom. The spiral blade 39 may be directly fixed to the shaft 25.

As shown in FIG. 14, the pressure adjusting means 14 is formed on the boss portion 30 that can be firmly fixed to the shaft 25, a circular plate (back pressure plate) 31 formed integrally with the boss portion 30, and the boss portion 30. A fixing screw 36 to be screwed into the screw hole is provided. By loosening the fixing screw 36 and adjusting the position of the back pressure plate 31 in the axial direction, the discharge capacity of the dewatered cake on the outlet side can be limited, and thereby the internal pressure of the filter body 11 can be adjusted.
The outer diameter of the back pressure plate 31 is set to be slightly larger than the diameter of the hole 23 a of the support 15.

As shown in FIG. 15, the peripheral edge portion 29a of the transport plate 29 and the peripheral edge portion 21c of the fixed plate 21 are always facing each other. The inner peripheral surface of the fixed plate 21 is positioned on the outer periphery of the spacer 28 that forms an axial gap between the transport plates 29.
That is, the fixed plate 21 is disposed so as to cover the outer periphery of the rotation miracle of the spacer 28. The inner peripheral surface of the fixed plate 21 plays a role of a so-called screw conveyor case, and the transport function is obtained by the spacer 28 rotating on the inner peripheral surface. Therefore, the conveying ability can be increased as the thicknesses of both the spacer 28 and the fixed plate 21 are increased.
On the outlet side of the filter body 11, as described above, the spacer 28 is disposed on the inner peripheral surface of the support body 15, so that the conveyance force does not decrease even at the final stage.
In order to obtain a larger conveying function, it is advantageous to make the thickness Kt of the fixed plate 21 larger than the thickness Ft of the conveying plate 29.
That is, when the thickness Ft of the transport plate 29 is larger than the thickness Kt of the fixed plate 21, the frictional force between the spacer 28 and the inner peripheral surface of the fixed plate 21 is reduced, and sludge remains in the thickness Ft of the transport plate 29. The action to try increases, and as a result, the conveying force decreases.

In the present embodiment, as described above, St = 3 mm, Kt = 2 mm, and Ft = 1 mm are set, and a gap g of 0.5 mm exists between the fixed plate 21 and the transport plate 29. Due to this slight gap g, moisture falls by gravity.
The fixed plate 21 is disposed in a gap between the conveying plates 29 formed by the spacers 28, and there is no spacer as a spacing member between the fixed plates 21, so that it slides in the axial direction within the gap. (Movement) is possible.
Due to the free configuration of the fixed plate 21 in the axial direction, even when a hundred or more transport plates 29 and spacers 28 are stacked, errors caused by stacking can be absorbed and rotation can be performed more smoothly.
Of course, a spacer may be arranged between the fixed plates 21 that is separate from the fixed plate 21 or formed integrally with the fixed plate 21. However, in this case, since high precision is required, high costs cannot be avoided.

When the motor 13 rotates, the transport plate 29 and the spacer 28 rotate synchronously, but the minute solid matter that has entered the gap g is sandwiched between the peripheral portion 29 a of the transport plate 29 and the peripheral portion 21 c of the fixed plate 21. While rotating, it rotates with the transport plate 29.
In the present embodiment, the outer diameter of the transport plate 29 is set slightly larger than the outer diameter of the fixed plate 21 (the outer diameter of the transport plate 29 = 100 mm, the outer diameter of the fixed plate 21 = 98 mm), and FIG. The width w2 of the peripheral portion 29a of the transport plate 29 shown is set to be larger than the width w1 of the peripheral portion 21c of the fixed plate 21 shown in FIG. 4 (w2 = 10 mm, w1 = 6 mm).
As described above, the eccentric amount of the transport plate 29 is 2 mm. Therefore, the overlap amount of the transport plate 29 and the fixed plate 21 is larger than the eccentric amount. That is, it is set so that there is an overlapping portion between the peripheral edge 29 a of the transport plate 29 and the peripheral edge 21 c of the fixed plate 21 at any rotational position.

By this rubbing movement in which the amount of overlap changes at the rotation position, the clogging prevention function and the drainage function are improved as compared with the case where the amount of overlap is not eccentric. This operation is shown in FIG.
In the state shown in FIG. 16A, the drainage action tends to decrease because the amount of overlap is large in the lower part, and clogging is likely to be eliminated because the amount of overlap is small in the upper part.
In the state shown in FIG. 16B, the overlap amount is small in the lower part, so that the drainage action is large and clogging is easy to be solved. FIG. 16C shows a state in which the transport plate 29 is eccentric to the left side, and FIG. 16D shows a state in which the transport plate 29 is eccentric to the right side.
The effect of promoting the outflow of the liquid can be expected as the eccentric amount of the transport plate 29 and the spacer 28 is larger and as the overlap amount of the transport plate 29 and the fixed plate 21 is smaller.

For the purpose of removing moisture, the material of the transport plate 29 is preferably stainless steel, and the plate thickness (Ft) is preferably about 1 to 3 mm. In addition, when targeting sludge containing a large amount of oil such as food wastewater, in order to further increase the drainage of water, a material with high liquid repellency (including concepts such as water repellency and oil repellency), For example, coating with Teflon (registered trademark) is effective. A similar coating may be applied to the fixing plate 21 in order to improve drainage.
The outer diameter of the transport plate 29 is preferably about 60 mm to 300 mm, and the area ratio of the protruding edge 29d that greatly affects the setting of the pitch of the spiral staircase transport blades is preferably about 1/16 to 1/4.

If the shift angle of the transport plate 29 and the spacer 28 is decreased (for example, 30 to 60 °), the pitch of the spiral staircase transport blades is decreased, and the action of increasing the internal pressure against the sludge in the filter body 11 occurs. This greatly affects the removal of moisture from solids.
For the purpose of dewatering surplus sludge of organic activated sludge such as livestock wastewater, it contains a lot of liquid (for example, water content 99%), so more filtration surface is used on the inlet side of the filter body 11. In order to increase the concentration effect that separates water by its own weight, it is necessary to quickly convey the sludge toward the outlet.
For this reason, it is preferable to consider the shift angle with an emphasis on transporting at a pitch similar to the inner diameter of the transport plate 29.
In the present embodiment, the conveying plate 29 and the spacer 28 are arranged so that the pitch is increased on the inlet side of the filter body 11 so that the concentration effect of separating water by its own weight can be enhanced and the pitch gradually decreases toward the outlet side. The shift angle is adjusted. Therefore, the internal pressure increases as it approaches the outlet side.

When dewatering inorganic sludge such as plating wastewater, the liquid content is about 98% to 96%, for example, and the pitch of the transport plate 29 and the spacer 28 is rearranged when the water content is already sufficiently concentrated. As a result, the internal pressure and the conveying force can be freely changed.
Instead of selecting from several screw pitch products as in the past, a pitch suitable for the sludge characteristics can be freely configured, so it does not require many parts and is inexpensive. It can be configured.

Next, the dehydrating operation of the solid-liquid separator 10 in this embodiment will be described. It is an example used for dehydration by adding a polymer flocculant to surplus sludge generated from an organic activated sludge method such as swine sewage to form a floc and separate it into a solid and liquid.
Flocked sludge is introduced into the inflow box 12 from a flocking device (not shown). The introduced sludge is sent to one end side (inlet side) of the filter body 11 by the sludge pushing means 37 in the inflow box 12.
The sludge is transported in the axial direction by the above-described spiral stepped transport blades of the movable member 18. As described above, since the pitch of the spiral staircase conveying blades is set large on the inlet side (front stage) of the filter body 11, the sludge is quickly transported, and at this time, a large amount of moisture moves downward from the filter body 11. Flow down.
This is because the sludge immediately after charging has a ratio of solid content: water = 1: 99, and therefore it is necessary to quickly transport it in the axial direction in order to use as many filtration surfaces as possible in a cylindrical shape.
It can be said that in the portion filtered using the gravity action, the solid pressure contained in the falling water is extremely small because the internal pressure of the filter body 11 is small.
The entire amount of moisture obtained from this portion (the front stage of the filter body 11) is discharged as treated water to the outside of the apparatus.

Since the pitch of the spiral staircase conveying blades gradually decreases toward the outlet of the filter body 11, the internal pressure increases and the dehydration rate improves. The dehydrated water flows downward from the filter body 11.
When the diameter of the opening 29b of the transport plate 29 is d and the pitch of the spiral staircase transport blades is L, the filter body 11 is reduced toward d: L = 1: 0.5 in the exit direction. The inside is filled with sludge and internal pressure is generated.
During this time, the sludge that has entered the gap g between the fixed plate 21 and the transport plate 29 is scraped off by the eccentric motion (rubbing rocking) of the transport plate 29.
Since the fixed plate 21 and the transport plate 29 are set so as to satisfy the relationship of overlap amount> eccentric amount, clogging is always prevented.
The dehydrated solid matter (dehydrated cake) is discharged from the outlet side of the filter body 11, but the discharge amount is limited by the back pressure plate 35 of the pressure adjusting means 14 provided on the outlet side. The internal pressure is increased.
The sufficiently dehydrated cake is discharged from between the outlet side support 15 and the back pressure plate 35.

FIG. 13 shows a second embodiment. In addition, the same part as the said embodiment is shown with the same code | symbol, and unless it was especially required, the description on the structure and function which were already demonstrated is abbreviate | omitted, and only the principal part is demonstrated.
The solid-liquid separation device 10A according to the present embodiment is characterized in that the dewatering performance of the filter body 11 is also enhanced by its inclined arrangement. In the above embodiment, the horizontal arrangement method is exemplified, but in this embodiment, the filter body 11 is installed so as to have an inclination angle θ so that the outlet side of the filter body 11 becomes higher.
When the filter body 11 is activated, that is, at the initial stage when the movable member 18 is rotationally driven to start dewatering, the filter body 11 is not sufficiently filled with sludge. In this state, a sufficient internal pressure cannot be obtained and the dehydrating function is low.
When the filter body 11 is inclined, the sludge is transported while returning to the inlet side by its own weight, so that the internal pressure is quickly increased, and the sludge in a state that does not become a sufficient dehydrated cake is discharged from the outlet side. Can be prevented.

The filter body 11 in this embodiment is divided into a gravity concentrating part A on the inlet side and a pressure dehydrating part B on the outlet side in terms of its function. Below the filter body 11, a collection tray 44 is disposed as means for individually collecting the processing liquid (separated liquid) discharged from the gravity concentrating part A and the pressure dehydrating part B.
The collection tray 44 has a two-part configuration including a tray unit 45 corresponding to the gravity concentrating unit A and a tray unit 46 corresponding to the pressure dewatering unit B.
Since the amount of solids contained in the water discharged from the gravity concentrating unit A is small, the entire amount collected in the tray unit 45 can be discharged as treated water. For this reason, the water | moisture content of the tray part 45 is directly stored in the tank 47 so that it may be sent to a water treatment facility.

From the pressure dehydration part B, solids and water are mixed and fall under the influence of pressure. A tray section 46 is partitioned so that only this portion can be collected, and a sedimentation tank 48 capable of sedimenting for a predetermined time is provided below the tray section 46. The mixed treated water that has entered the settling tank 48 is separated by precipitation, and the precipitate is periodically sucked by a pump 49 installed in the settling tank 48 and sent to a flocking device for reprocessing.
When the pump 49 does not operate in the settling tank 48, the supernatant water is put into the tank 47 to be discharged out of the apparatus as treated water.
If the thickness (St) of the spacer 28 is changed so that the gap g between the fixed plate 21 and the transport plate 29 is smaller in the pressure dewatering part B than in the gravity concentrating part A, the pressure dehydrating part B The fall of a solid substance can be decreased and the internal pressure of the filter body 11 can also be raised simultaneously.

In each of the above-described embodiments, a configuration having one filter body is provided. However, two or more filter bodies are provided in parallel, and sludge is supplied to each filter body from an individual or common flocking device to increase the processing capacity. It is good also as a system to make it.
Moreover, it is good also as a structure provided with the washing | cleaning apparatus which wash | cleans the periphery of a filter body regularly and automatically with a timer.

It is an outline front view of the solid-liquid separation device concerning a 1st embodiment of the present invention. It is a general | schematic front view of a fixing member. It is a principal part disassembled perspective view. It is a figure which shows a fixed plate, (a) is a side view, (b) is a front view. It is a general | schematic front view of a movable member. It is a figure which shows a conveyance plate, (a) is a side view, (b) is a front view. It is a figure which shows a spacer, (a) is a side view, (b) is a front view. It is a side view of the state which inserted and accumulated the conveyance plate and the spacer. It is a pattern figure which shows the position shift state of a conveyance plate and a spacer. It is a side view which shows the modification of a conveyance plate. It is a side view which shows the modification of a spacer. It is a figure which shows a rotating shaft, (a) is a front view, (b) is an enlarged side view. It is a figure which shows the assembly structure of a rotating shaft. It is a figure which shows a pressure adjustment means, (a) is sectional drawing, (b) is a side view. It is a figure which shows the positional relationship and thickness relationship among a conveyance plate, a spacer, and a fixed plate. It is a figure which shows eccentric rotation of the conveyance plate with respect to a fixed plate. It is a general | schematic front view of the solid-liquid separator which concerns on 2nd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Filter body 13 Motor as drive means 17 Fixed member 18 Movable member 21 Fixed plate 25 Rotating shaft 28 Spacer 29 Conveying plate 29b Opening 29d Projection edge

Claims (9)

A filter body provided with a movable member exhibiting a screw conveyor function inside a cylindrical fixed member, and a driving means for rotationally driving the movable member, while dewatering sludge fed from one end side of the filter body In the solid-liquid separator that conveys and discharges to the other end side,
The movable member includes a rotary shaft and a plurality of removable transport plates that are arranged and supported in a stacked state in the axial direction on the rotary shaft, and the transport plate is configured so that each transport plate is an axis of the rotary shaft. It has a shape capable of forming a conveying path and a spiral stepwise conveying blade continuously connected in the axial direction by shifting and fixing the position at a substantially constant interval in the circumferential direction within a plane substantially orthogonal to the direction. A solid-liquid separator characterized by that. The solid-liquid separator according to claim 1,
The transport plate has an opening that constitutes a transport path, and a protruding edge that extends from the outside toward the rotation center portion and has an insertion hole for the rotation shaft at the center portion, and the protrusion edges are continuously connected. A solid-liquid separator characterized by forming the spiral stepped conveying blade. The solid-liquid separator according to claim 2,
The rotation shaft and the insertion hole of the protruding edge have a relative engagement structure, and when the rotation plate is inserted through the rotation shaft, the circumferential position of the transport plate with respect to the rotation shaft is fixed. Solid-liquid separation device. The solid-liquid separation device according to claim 3,
A solid-liquid separation device, wherein a plurality of circumferentially fixed positions are provided at predetermined angular intervals, and the pitch of the spiral stepped conveying blades can be changed. In the solid-liquid separation device according to any one of claims 2 to 4,
A spacer that forms the spiral staircase-shaped conveying blades together with the protruding edges is disposed between the conveying plates. The solid-liquid separator according to claim 5,
The solid-liquid separation device, wherein the spacer is formed integrally with the protruding portion of the transport plate. The solid-liquid separator according to claim 5,
The solid-liquid separation device, wherein the spacer has a shape equivalent to that of the protruding edge, and is arranged so as to alternately pass through the rotation shaft and the conveying plate. In the solid-liquid separator in any one of Claims 5-7,
The fixing member includes a plurality of fixing plates having openings and spaced apart in the axial direction of the rotating shaft, and the fixing plates are arranged so as to cover the outer periphery of the rotation locus of the spacer. A solid-liquid separator characterized by comprising: The solid-liquid separator according to claim 8,
When the thickness of the spacer in the axial direction of the rotating shaft is St, the thickness of the fixed plate is Kt, and the thickness of the transport plate is Ft,
St>Kt> Ft
A solid-liquid separator characterized by satisfying the above relationship.

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