KR20180135790A - Screw press - Google Patents

Abstract

The present invention provides a screw press capable of suppressing or preventing the deposition of solid matter on a filtration surface and continuously operating over a long period of time.
The screw press of the present invention is provided with a rotary drum 11 having a cylindrical filtration surface 11A and a screw 12 having a screw blade 12B provided along the axis of the rotary drum 11, A shoe mechanism 30 for removing solid matter adhering to the surface 11A is provided along the outer peripheral edge of the screw blade 12B and the shoe mechanism 30 has a resin shoe 30 which elastically slidably contacts the filtration surface 11A, An elastic member 33 for giving elasticity to the resin shoe 31 in the accommodating body 32 and an elastic member 33 for elastically applying the resin shoe 31 to the resin shoe 31, And a protrusion preventing member 34 for preventing the protrusion from protruding from the housing body 32.

Description

SCREW PRESS

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a screw press for compressing a material to be treated such as sludge to perform solid-liquid separation, and more particularly, drum to prevent the film from being deposited on the drum.

A conventional screw press of this kind is known, for example, as shown in Fig. Fig. 5 schematically shows a screw press described in Patent Document 1. Fig. The conventional screw press M has a rotary drum 1 having a cylindrical filtration surface 1A as shown in Fig. 5, and a rotary drum 1 having an axial center And a screw 2 having a screw shaft 2A penetrating therethrough and a screw blade 2B formed in a spiral shape on the outer peripheral surface of the screw shaft 2A. ) Is pressed to separate the solid from the separated liquid by solid-liquid separation.

The rotary drum 1 has a left end face 1B which closes one end (left end in the figure) of the filtration face 1A and a left end face 1B which closes the filtration face 1A A diameter portion 1C formed continuously with a diameter larger than the surface 1A and a right end surface 1D closing the right end of the diameter portion 1C. The screw shaft 2A has a left end portion passing through the center of the left end face 1B of the rotary drum 1 and a right end portion passing through the center of the right end face 1D. 5, the screw shaft 2A has a hollow portion 2C formed at the left end portion and an opening portion (opening portion) 2C opened from the hollow portion 2C in the rotary drum 1 The sludge is supplied from the left end of the screw shaft 2A into the hollow portion 2C as indicated by an arrow A and is rotated from the opening portion 2D of the screw shaft 2A in the rotary drum 1 And is introduced into the drum 1.

The screw shaft 2A has a tapered portion gradually tapered from the vicinity of the left end surface 1B of the rotary drum 1 to the right end of the filtration surface 1A, And has a straight portion formed to have the same diameter as the maximum diameter of the shape portion. The screw blade 2B is formed in the tapered portion, and a narrow gap is formed between the outer periphery of the screw blade 2B and the filtration surface. Then, the screw blade 2B gradually narrows the spiral interval from the left side to the right side of the filtration surface 1A, so that the compression force becomes strong at the large diameter portion 1C side.

First and second bearings 3A and 3B are provided on both left and right ends of the screw shaft 2A so that the screw shaft 2A can be rotated by the first and second bearings 3A and 3B have. In the rotary drum 1, a third bearing 4A is provided between the center hole of the left end surface 1B and the screw shaft 2A. A cylindrical body 1E covering the screw shaft 2A is connected to the center of the right end surface 1D of the rotary drum 1. A cylindrical body 1E is interposed between the cylindrical body 1E and the screw shaft 2A 4 bearings 4B are provided. The second bearing 3B axially supports the screw shaft 2A through a thin portion formed by extending from the cylinder 1E of the rotary drum 1. [

A first sprocket 5A is attached to the left end of the screw shaft 2A and a second sprocket 5A is attached to the right end of the thin portion of the cylindrical body 1E of the rotary drum 1. [ And the screw 2 and the rotary drum 1 rotate through the sprockets 5A and 5B, respectively. The rotary drum 1 performs differential rotation with the screw 2 at a different rotational speed.

A straight portion 1F having the same diameter as the filtration surface 1A is provided between the right end of the filtration surface 1A and the left end of the enlarged diameter portion 1C of the rotary drum 1, And the ring-shaped gap of the straight portion of the screw shaft 2A serves as a discharge port for the solid portion after the squeezing process. Further, since the solid portion from the discharge port is discharged to the outside via the enlarged diameter portion 1C, the enlarged diameter portion 1C will be described as the discharge portion 1C in the following description.

A presser 6A having a ring shape is provided in the discharge portion 1C of the rotary drum 1. This presser 6A closes the discharge port to give a back pressure to the solid portion. The presser 6A is formed into a ring shape having a tapered surface for closing the discharge port, and the straight portion of the screw shaft 2A passes through the center hole. On the outside of the discharge portion 1C, a presser pressing plate 6B having a ring shape is provided parallel to the presser 6A at a predetermined interval. The cylinder 1E of the rotary drum 1 passes through the center hole of the presser presser plate 6B and the presser presser plate 6B slides in the lateral direction along the cylinder 1E. The presser presser plate 6B is connected to the presser 6A through a plurality of rods 6C. The presser pressing plate 6B reciprocates the cylinder 1E in the left-right direction through the drive mechanism 6D. A drive mechanism (6D) is, for example, pressurized air (加壓空氣) an air cylinder (air cylinder) working in (6D _1), and a sliding member fitting parts of the outer peripheral edge of the press, the pressure plate (6B) (6D ₂₎ and And a supporting body 6D ₃ supporting the sliding member 6D ₂ so that the air cylinder 6D ₁ expands and contracts the cylinder rod 6D ₄ by the pressurized air to operate the presser pressing plate 6B .

When the discharge port is closed by the presser 6A, the presser pressing plate 6B is moved through the drive mechanism 6D to the position indicated by the two-dot chain line from the solid line position to the left direction, And the discharge port is closed to give a back pressure to the solid component conveyed by the screw 2 in the rotary drum 1. [ This back pressure can be appropriately set by the air pressure of the air cylinder 6D ₁ of the drive mechanism 6D. Also the rotating drum (1) is rotated and as well as to the sliding presser (6A) is between the back-and-forth motion along the cylinder (1E), the circumferential edge portion of the sliding member (6D ₂₎ a press, the pressing plate (6B) is being rotated. When the pressure from the solid component conveyed by the screw 2 overcomes the back pressure from the presser 6A, the presser 6A moves rightward from the position indicated by the chain double-dashed line, The solid portion is discharged from the portion 1C to the outside as indicated by the arrow B in FIG.

Further, in FIG. 5, 6E is a housing (housing), 8 is a rotary drum (1) for accommodating a sliding member (6D ₂₎ the guide unit (guide機構) to smoothly straight a, 7 a rotating drum (1) including 9 is a drainage section formed at a central portion of the water collecting section 8. As shown in Fig. A cleaning device (not shown) is provided over the entire length of the filtration surface 1A in the gap between the filtration surface 1A and the housing 7 in the rotary drum 1, The filtration surface 1A is cleaned while the rotary drum 1 is rotating.

Then, the rotating drum 1 and the screw 2 of the screw press M are rotated to separate the solid from the sludge, and the solid content is conveyed to the discharge port while pressing the solid portion gradually and strongly. As a result of the solid content reaching the presser 6A, The presser 6A opens the discharge port to discharge the solid portion to the discharge portion 1C and discharges the solid portion from the discharge portion 1C to the outside as indicated by the arrow B do. The separated water by the crimping is collected in the catching portion 8 from the filtration surface 1A and discharged to the outside from the drainage portion 9.

: Japanese Patent No. 4373832

However, if the conventional screw press M is operated and the squeezing process of the sludge is continued for a long period of time, the solid portion is filled on the filtration surface 1A, and a sediment layer is formed on the inner surface of the filtration surface 1A, The filtration becomes difficult and there is a fear that the subsequent squeezing of the sludge becomes impossible. Therefore, the screw press M was stopped in a relatively short time, and the inside of the rotary drum 1 was cleaned to remove the deposit layer.

An object of the present invention is to provide a screw press capable of suppressing or preventing accumulation of solid matter on a filtration surface and continuously operating for a long time.

The screw press described in claim 1 of the present invention comprises a rotary drum having a cylindrical filtration surface and a screw having a screw blade installed along the axial center in the rotary drum, A shoe mechanism for removing solid matter adhering to the filtration surface is provided on an outer peripheral edge portion of the screw blade so as to be separated from the outer peripheral edge portion of the screw blade Wherein the shoe mechanism comprises: a shoe which elastically slidably contacts the filtration surface; an accommodating body for accommodating the shoe; an elastic member for elastically slidingly contacting the shoe with the filtration surface in the accommodating body; , And that the sugar protrudes from the housing And an ejection preventing member for preventing the ejection of the ink.

According to a second aspect of the present invention, there is provided a screw press according to the first aspect of the present invention, wherein the shoe mechanism is provided over an entire circumferential edge portion of the screw blade.

Further, in the screw press according to claim 3 of the present invention, in the invention described in claim 1 or claim 2, the shoe mechanism has a plurality of shooses, and each shoe is formed by an arc- And the like.

According to a fourth aspect of the present invention, there is provided a screw press according to any one of the first to third aspects of the present invention, wherein the shoe mechanism has a plurality of elastic members, And an elastic member formed by the elastic member.

According to a fifth aspect of the present invention, there is provided a screw press according to any one of the first to fourth aspects of the present invention, wherein the projecting prevention member is a screw member.

According to a sixth aspect of the present invention, in the screw press according to the fifth aspect of the present invention, the shoe has a hole through which the screw member is loosely fitted.

According to the present invention, it is possible to provide a screw press capable of suppressing or preventing the deposition of solid matter on the filtration surface, thereby enabling continuous operation for a long time.

1 is a cross-sectional view showing one embodiment of a screw press of the present invention over its entire length.
Fig. 2 is a cross-sectional view showing a presser drive mechanism of the screw press shown in Fig. 1. Fig.
Figs. 3 (a) and 3 (b) are enlarged views of the shoe mechanism shown in Fig. 1, wherein (a) is a front view showing a main part. (b) is an enlarged sectional view of the screw in the axial direction.
4 (a) to 4 (c) are enlarged views of a shoe mechanism according to another embodiment of the present invention, wherein (a) is a front view showing a main portion. (b) is a cross-sectional view taken along the line BB of (a), and FIG.
5 is a schematic diagram showing a conventional screw press.

Hereinafter, the present invention will be described based on the embodiments shown in Figs.

The screw press 10 according to the present embodiment has a first end face (first end face) formed on the left end (left end) of a cylindrical filtration face (filtration face) 11A as shown in Fig. 1, (Hereinafter referred to as " left end face ") 11B extending from the right end of the filtration surface 11A, A rotary drum 11 having a second end face 11D (hereinafter referred to as a "right end face") 11D and a rotary drum 11 having an axial center shared within the rotary drum 11 A screw shaft 12A projecting outwardly from both end faces 11B and 11D of the rotary drum 11 and a screw blade 12A formed in a spiral shape on the peripheral surface of the screw shaft 12A The rotary drum 11 and the screw 12 cooperate with each other to press the object to be processed (for example, sludge) (Solid-liquid separation) with a separating liquid, and the separated liquid is discharged from the filtration surface 11A and the solid content is conveyed to a discharge port (to be described later) while being squeezed by a screw blade 12B Consists of.

As shown in Fig. 1, first and second bearings 13A and 13B are provided at both ends of the screw shaft 12A, respectively. The screw shaft 12A is rotated by these first and second bearings 13A and 13B, That is, the screw 12 is rotated. The first and second bearings 13A and 13B are all fixed to the supporting bodies S1 and S2. The second bearing 13B is connected to an adjacent rotary joint as described later. Third and fourth bearings 14A and 14B sandwiching the screw shaft 12A are provided in the center holes of both end faces 11B and 11D of the rotary drum 11, And is rotatably supported on the screw shaft 12A by the bearings 14A and 14B so that the rotary drum 11 can rotate.

1, a cylindrical body 11E surrounding the fourth bearing 14B is connected to the outer surface of the right end surface 11D of the rotary drum 11, and a sprocket 11D is provided on the right end of the cylindrical body 11E. a sprocket 15A is provided. The first drive device 16A is connected to the sprocket 15A through an endless chain 17A so that the first drive device 16A can drive the chain 17A and the sprocket 15A Thereby rotating the rotary drum 11. A sprocket 15B is provided at the right end of the screw shaft 12A and a second drive device 16B is connected to the sprocket 15B via an endless chain 17B so that the second drive device 16B Rotates the screw 12 at a faster rotational speed than the rotary drum 11 through the chain 17B and the sprocket 15B.

1, the screw shaft 12A has a tapered shape in which the diameter gradually decreases from the vicinity of the left end surface 11B to the vicinity of the enlarged diameter portion 11C in the filtration surface 11A of the rotary drum 11, It has a portion _{(taper形狀部) (12A 1} ) , and a direct portion (12A ₂₎ extends into the enlarged diameter (11C) with the same diameter as that formed from the right end of the tapered section (12A _1). Accordingly, all of the first, second, third and fourth bearings 13A, 13B, 14A and 14B are provided at both ends of the screw shaft 12 so that the rotary drum 11 is rotated by the screw shaft 12 To be able to do. The screw blade 12B is formed in a spiral shape in the tapered portion 12A ₁ , and the interval of the screw is narrowed toward the discharge portion 11C. A narrow gap is formed between the outer peripheral surface of the screw blade 12B and the inner peripheral surface of the filtration surface 11A and the dimension of the gap between the outer periphery of the screw blade 12B and the filtration surface 11A is relatively simple , It is easy to manage the dimension at the time of production.

The left end of the screw shaft 12A passing through the left end face 11B of the rotary drum 11 is formed as a hollow shaft. In the hollow shaft, an opening portion (opening portion) 12C located in the vicinity of the inner side of the left end surface 11B of the rotary drum 11 is formed. The sludge is supplied from the left end opening of the hollow shaft and flows into the rotary drum 11 from the opening 12C.

A ring-shaped gap exists between the right end of the filtration surface 11A of the rotary drum 11 and the straight portion 12A ₂ of the screw shaft 12A, and solid matter is discharged from this gap. The ring-shaped gap will be described below as a discharge port. Further, the solid component discharged from the outlet is discharged to the outside as will be described later via the enlarged diameter portion 11C. In the following description, the enlarged diameter portion 11C will be described as the discharge portion 11C.

A pressor 18 for opening and closing a solid outlet is provided in the discharge portion 11C and is configured to give a back pressure to the solid portion at the discharge port by the presser 18. [ When the solid extruding pressure at the discharge port overcomes the predetermined back pressure from the presser 18, the presser 18 is moved from the position of the two dot chain line in the discharge portion 11C to the solid line position of the right end face 11D side And the outlet is gradually opened to discharge the solid content to the discharge portion 11C.

As shown in Figs. 1 and 2, the presser 18 has a tapered surface for closing the discharge port by penetrating the distal end side into the ring-shaped discharge port, and the center hole is connected to the straight portion 12A ₂ of the screw shaft 12A, And is configured to move leftward and rightward along the straight portion 12A ₂ . The presser 18 is configured such that a predetermined back pressure is applied to the solid portion at the discharge port by the drive mechanism 19 provided outside the rotary drum 11 and the discharge port is opened and closed.

1 and 2, the drive mechanism 19 includes, for example, two cylinder mechanisms (cylinder mechanisms) provided at positions apart from each other by 180 degrees from the right end face 11D of the rotary drum 11 A rotary joint 19C connected to the air cylinder 19A through pipes 19B and 19B and a rotary joint 19C and a pipe 19B via an air cylinder 19A, And a connected air source 19D. A presser 18 is connected to the tip end of the cylinder rod 19A _{1 in the} two air cylinders 19A. 1 and 2, the presser 18 is disposed in the discharge section 11C of the rotary drum 11 in the circumferential direction between the right end surface 11D and the opposite surface thereof at equal intervals The guide rods 19E are connected to a plurality of guide rods 19E arranged so as to guide the guide rods 19E smoothly in the left and right directions. Only one air cylinder 19A is shown in Figs. 1 and 2. In addition, in the present embodiment, a double acting type air cylinder (return type aircylinder) is used as the air cylinder 19A. In the present invention, a single acting air cylinder (a single cylinder type) can also be used.

Therefore, when the pressurized air is supplied from the air source 19D to the air cylinder 19A through the rotary joint 19C, the cylinder 19A ₁ is stretched to move the presser 18 to the solid Move it toward the discharge port to close the discharge port. At this time, the back pressure applied to the solid content can be adjusted by properly setting the magnitude of the pressure of the pressurized air in accordance with the characteristics of the sludge and the like. If the pressure of the pressurized air is set high, the back pressure from the presser 18 to the solid component becomes large, and the water content of the solid component decreases. Conversely, if the pressure of the pressurized air is set low, So that the water content of the solid content becomes high.

The rotary joint 19C is sandwiched between the second bearing 13B and the fourth bearing 14B as shown in Fig. The rotary joint 19C includes a tubular fixed portion 19C ₁ connected to the second bearing 13B as shown in the figure and a cylindrical fixed portion 19C ₁ slidingly connected to the fixed portion 19C ₁ in addition, provided with a bearing (19C ₃₎ sandwiched between the both ends of the tubular rotary part (19C ₂₎ connected to the cylinder (11E) of the rotary drum 11, a fixing section (19C ₁₎ and rotating part (19C _2), rotating portion (19C ₂₎ is configured to rotate while being rotated and with the drum 11 and to the central government (19C ₁₎ to the sliding contact state (19C _1). A narrow clearance is provided between the cylindrical fixing portion 19C ₁ and the screw shaft 12A so that the screw shaft 12A smoothly rotates through a narrow gap between the fixing portion 19C ₁ and the fixing portion 19C ₁ .

Additionally, it and at the same time, and the two outer peripheral surface through two passages with each state (19C ₁₎ There is a pressurized air passage in the axial direction is formed of two cylindrical fixing portion (19C ₁₎ in as shown in Figure 2 An annular groove is formed. That is, the passage and the annular groove communicate with each other through the communication passage. The rotary part 19C ₂ is formed with two first ports communicating with the two annular grooves in the radial direction and a fixing part 19C ₁ protruded from the rotary part 19C ₂ is provided with a fixing part 19C ₁ , And two second ports communicating with the two passages of the first passage 19C ₁ are formed in the radial direction. Each of the two second ports at the right end of the fixed portion 19C ₁ is provided with a one touch coupling 19C ₄ (see Fig. 2B) connected to the piping 19B of the air source 19D shown in Fig. 1 a reference) is attached, the two ports of the rotating portion (19C _2), there are two one-touch coupling (19C ₅₎ are respectively connected to the two pipes (19B) with an air cylinder (19A) is attached. In both ends of an air cylinder (19A), rotation (19C _{2) 2} of the pipe (19B), a (FIG. 1) for connecting the one-touch coupling (19A ₂₎ is attached, the air source (19D) (Fig. 1 of ) Is supplied to the port for opening and closing the air cylinder 19A through the second port, the passage and the first port of the rotary joint 19C. The air cylinder 19A moves the presser 18 to close the discharge port and gives a back pressure to the solid portion at the discharge port.

1, the rotary drum 11 is housed in the housing 20 and is provided above the rotary drum 11 in the housing 20 over the entire length of the filtering surface 11A, A device 21 is provided for intermittently spraying the washing water from the washing device 21 to clean the filtering surface 11A. A water collecting section 22 having an inclined surface is formed below the rotary drum 11 and a drain pipe 23 is provided at a lower end of the water collecting section 22. [ Therefore, the separated water and the washing water from the rotary drum 11 are collected in the collecting part 22 and discharged to the outside from the drain pipe 23.

In the screw blade 12B of the screw 12 used in the present embodiment, as shown in Figs. 1 and 3 (a) and 3 (b), the filtration surface 11A of the rotary drum 11, (Shoe mechanism) 30 for removing solid matter adhering to the surface of the wafer W. 3 (a) and 3 (b), the shoe mechanism 30 includes a resin shoe 31 that elastically contacts the filtration surface 11A, A housing body 32 fixed to the left side face (the side opposite to the left end face 11B, that is, the side of the screw 12 on the sludge supply side) of the outer peripheral edge portion of the screw blade 12B, An elastic member 33 (for example, a leaf spring 33A and / or an elastic rubber 33B) that applies elastic force in the direction of the filtration surface 11A in the resin shoe 32 to the resin shoe 31, (For example, a screw member) 34 for preventing the resin shoe 31 from protruding from the accommodating body 32 while the resin shoe 31 is pressed by the elastic member 33 And is in elastic contact with the filtration surface 11A. Since the shoe mechanism 30 is provided on the surface opposite to the sludge conveyance of the screw blade 12B, contact with the sludge is small and damage due to the sludge is suppressed. The elastic member 33 is composed of the leaf spring 33A and / or the elastic rubber 33B. In FIG. 3B, the elastic member 33 is shown as a spring for convenience.

It is preferable that the shoe mechanism 30 is installed over the entire length of the left side surface of the outer peripheral edge portion of the screw blade 12B, as can be assumed from Fig. 3 (a). Therefore, it is preferable that a plurality of the resin shoes 31 are arranged over the entire length of the screw blades 12B through the clearances. The individual resin shoe 31 is provided with a resilient force by the elastic members 33 sandwiched between the respective lower surfaces and the accommodating body 32.

3 (a) and 3 (b), the resin shoe 31 is formed in an arc shape aligned with the outer circumferential edge portion of the screw blade 12B. For example, the resin shoe 31 is made of ultra- And the like. The resin shoe 31 is preferably made of a material hard to be worn. In the resin shoe 31, there are formed radial slots 31A at two positions on the left and right, and these slots 31A are formed such that the screw members 34 are loosely fitted. A notch portion 31B is formed in a lower portion of both ends of the resin shoe 31 and a part of a leaf spring 33A described later is intruded into the notch portion 31B. When the shoe mechanism 30 is attached to the screw blade 12B, the resin shoe 31 and the leaf spring 33A are integrally formed as a single body, so that the leaf spring 33A is integrated with the resin shoe 31 .

As shown in Fig. 3 (b), the housing 32 has a U-shaped cross section and is formed to match the length of the outer peripheral edge portion of the screw blade 12B. A hole for allowing the screw shoe 31 to pass through the screw member 34 for preventing the resin shoe 31 from jumping out from the inside of the accommodating member 32 is formed on the projecting surface of the housing member 32 from the screw blade 12B, And a screw hole corresponding to the hole is formed in the side surface. The housing body 32 may be formed continuously from the start end to the end of the screw vane 12B or may be divided into a plurality of pieces. In the present embodiment, the accommodating body 32 is formed of a metal such as stainless steel, and is fixed to the outer peripheral edge portion of the screw blade 12B by welding or the like. The plurality of resin shoes 31 are arranged in the accommodating body 32 with a gap therebetween as shown in Fig. 3 (a), and the resin shoeholes 31, which are constrained in the accommodating body 32 via the screw member 34, The elastic member 31 is elastically contacted to the filtration surface 11A through the elastic member 33 and smoothly slides up and down and left and right along the filtration surface 11A.

The elastic member 33 is formed by the leaf spring 33A and / or the elastic rubber 33B as described above. The elastic member 33 may be the leaf spring 33A alone, but may be an elastic rubber 33B, as shown in Fig. 3 (a), provided at a predetermined interval between the leaf springs 33A. The leaf spring 33A may be a coil spring as long as it is an elastic member.

The leaf spring 33A is formed by curving the side surface in a mountain shape and is formed into a substantially U shape by bending the both ends of the plate spring 33A upward from the valley of the mountain shape, One resin shoe 31 is used. 3A and 3B, the plate spring 33A contacts the lower surface of the resin shoe 31 at two places, and the valley of the center contacts the bottom of the housing body 32, As shown in Fig. And the U-shaped portions at both ends of the leaf spring 33A are inserted into the notch portions 31B at both ends of the resin shoe 31. [ The side surface shape of the leaf spring 33A varies depending on the shape of the notched portion 31B of the resin shoe 31. [

The elastic rubber 33B is curved in an arc shape along the bottom surface of the resin shoe 31 in a state of being mounted in the accommodating body 32 as shown in Fig.3A, And one elastic rubber is used for two resin shoes 31, for example. The elastic rubber 33B is embedded in the concave portion formed by the notch 31B of the right and left resin shoe 31 and its upper surface is in contact with the bottom surface of the right and left resin shoes 31. [ That is, the resin shoe 31 supported by the elastic rubber 33B and the resin shoe 31 supported by the leaf spring 33A can use the same resin shoe.

The resin shoe 31 is housed in the accommodating body 32 so as to elastically slide on the filtration surface 11A through the elastic member 33 (the leaf spring 33A and / or the elastic rubber 33B) , The upper surface slidingly in contact with the filtration surface 11A is worn over time. The sliding surface of the resin shoe 31 with the filtration surface 11A becomes more conformable to the filtration surface 11A as the surface wears, and the subsequent wear can be suppressed. When the resin shoe 31 is worn, it is gradually lifted upward by the elastic member 33. Since the elastic member 33 (the leaf spring 33A and / or the elastic rubber 33B) does not function after the lower surface of the elongated hole of the resin shoe 31 comes into contact with the screw member 34, The resin shoe 31 is replaced with a new resin shoe 31 at an appropriate time.

Next, the operation of the screw press 10 of the present embodiment will be described. When the screw press 10 is started, the first and second driving devices 16A and 16B differentially rotate the rotary drum 11 and the screw 12, and the presser 18 The discharge port is closed at a predetermined pressure in the vicinity of the discharge port through the air cylinder 19A of the drive mechanism 19. [ The sludge is supplied from the hollow shaft of the screw shaft 12A and flows into the rotary drum 11 from the opening 12C of the hollow shaft as shown by the arrow A in Fig. The sludge is gradually and strongly pressed by the operation of the screw blade 12B which is gradually narrowed while being conveyed toward the discharge port through the screw blade 12B of the screw 12 into the rotary drum 11 and solid- do. The solid component after the solid-liquid separation is conveyed to the discharge port by the screw blade 12B and the separated water is discharged from the filtration surface 11A to the collecting part 22. [

The resin shoe 31 of the shoe mechanism 30 tends to stick to the inner surface of the filtration surface 11A of the rotary drum 11 while the screw press 10 is driven, The solid portion is wiped off by the resin shoe 31 to prevent the solid matter from adhering to and accumulating on the inner peripheral surface of the filtration surface 11A. Since the filtration surface 11A is cleaned by removing the solid content from the filtration surface 11A, the filtration area 11A is prevented from clogging so that the filtration area does not decrease over a long period of time, And is discharged to the collecting part 22. As a result, the load on the cleaning device 21 for cleaning the filtration surface 11A is reduced.

When the screw press 10 is solid-liquid separated from the filtration surface 11A by the shoe mechanism 30, the solid content is gradually accumulated and conveyed in the rotary drum 11 to reach the presser 18, (18). When the pressing force of the solid component gradually increases to overcome the back pressure from the presser 18, the presser 18 is retracted by the pressing force of the solid component to open the outlet. As a result, the solid content is discharged from the discharge port into the discharge portion 11C and discharged from the discharge portion to the outside as indicated by the arrow B in Fig. When the discharge of the solid content is completed, the drive mechanism 19 is driven to close the discharge port by advancing the presser 18 to the discharge port. And the squeezing of the sludge continues.

When the solid-liquid separation is continued for a long time, the resin shoe 31 of the shoe mechanism 30 gradually wears. However, since the resin shoe 31 is resiliently lifted toward the filtration surface 11A by the elastic member 33, the resin shoe 31 is still in sliding contact with the filtration surface 11A in a resilient manner, The abutment surface of the abutment surface 31 is very close to the filtration surface 11A so that the solid part can be more surely removed from the filtration surface 11A and the service life of the resin shoe 31 itself is prolonged. When the wear of the resin shoe 31 is advanced, the resin shoe 31 is replaced at an appropriate time.

As described above, according to the present embodiment, the shoe mechanism 30 is provided on the outer peripheral edge portion of the screw blade 12B, and the shoe mechanism 30 is fixed to the resin shoe 31, the accommodating body 32, Even if the solid component generated by the solid-liquid separation of the sludge tends to adhere to and accumulate on the filtration surface 11A of the rotary drum 11, The solid component is removed from the filtration surface 11A and deposition of the solid content on the filtration surface 11A is suppressed and prevented so that the stable permeability of the filtration surface 11A can be maintained for a long time and the screw press 10 can be maintained for a long time So that stable operation can be continued.

Even if the resin shoe 31 is elastically slidingly contacted with the filtration surface 11A and the upper end surface of the resin shoe 31 is worn out, The resin shoe 31 elastically comes into sliding contact with the filtration surface 11A and stably removes the solid content by the elastic shrinkage of the resin shoe 31 , Deposition of solid matter on the filtration surface 11A is reliably suppressed and prevented. When the wear of the resin shoe 31 progresses, the resin shoe 31 is simply exchanged by removing the screw member 34 at an appropriate time. Further, since the shoe mechanism 30 is divided into a plurality of shoe assemblies 30, even if warping occurs in the rotary drum 11 or the screw 12, the shoe mechanism 30 is suitable for its shape, and the sludge processing can be continued.

The screw member 34 loosely fits into the elongated hole 31A of the resin shoe 31 and the resin shoe 31 swings freely forward and backward about the screw member 34 around the entire length of the resin shoe 31, So that the solid content is removed all over a long period of time by sliding contact with the filtration surface 11A.

4 (a) to 4 (c) are views showing a shoe mechanism according to another embodiment of the present invention, respectively. 4A to 4C, the shoe mechanism 40 according to the present embodiment includes a resin shoe 41 that elastically contacts the filtration surface 11A, And an elastic member (for example, a plate (not shown)) formed in a mountain shape so as to give elasticity to the resin shoe 41 in the accommodating body 42. The accommodating body 42 is fixed to the left side surface of the outer peripheral edge portion of the screw blade 12B, And a screw member 44 for preventing the resin shoe 41 from protruding from the accommodating body 42. The resin shoe 41 is pressed by the leaf spring 43 to form a filtration surface 11A.

The resin shoe 41 is formed in an arc shape along the outer circumferential edge of the screw blade 12B, and two long holes 41A are formed at left and right spaced positions. These elongated holes 41A are elongated in the diameter direction of the screw blade 12B as shown in Fig. 4A, a semicircular notch 41B is formed at the lower center of the resin shoe 41, and a mountain portion of a mountain-shaped leaf spring 43 is inserted into the notch 41B, , And its top portion elastically contacts the innermost portion of the notch 41B. A valley portion is formed on the right and left sides of the top portion, and these valleys elastically contact the bottom surface of the housing body 42. [ The resin shoe 41 is always urged upward through the leaf spring 43 in the accommodating body 42 so that the resin shoe 41 is resiliently pressed against the filtration surface 11A as shown in Figs. Contact.

As shown in Figs. 4 (a) to 4 (c), the resin shoe 41 is provided with a screw member 44 (see Fig. 4) through the long hole 41A in the accommodating body 42 like the resin shoe 31 shown in Fig. And is restrained to be rotated in the housing body 42. As shown in Fig. Since the resin shoe 41 is always pressed upward by the leaf spring 43 in the accommodating body 42 like the resin shoe 31 shown in Figs. 3 (a) and 3 (b) And is elastically brought into contact with the filtration surface 11A to exert the same performance as the resin shoe 31. [ Since the notch portion 41B is formed on the bottom surface of the resin shoe 41 and the protruding portion of the leaf spring 43 enters the notch portion 41B, the width of the resin shoe 41 is narrowed, The shoe mechanism 40 can be adapted to the screw blade 12B of Fig.

The shoe mechanism 40 shown in Figs. 4 (a) to 4 (c) has been described as having one kind of resin shoe 41 and leaf spring 43, but the shoe mechanism 30 shown in Fig. Or the resin shoe 31 using the elastic rubber 33B may be mixed. Also in this embodiment, the same operational effects as those of the above-described embodiment can be expected.

The present invention can be used as a solid-liquid separator for solid-liquid separation by squeezing a material to be treated such as sludge or slurry.

10: Screw press
11: rotary drum
11A: Filtration side
12: Screw
12B: Screw wing
30, 40: shoe mechanism
31, 41: resin shoe
31A, 41A: Long hole (hole)
32, 42:
33: elastic member
33A, 43: leaf spring (elastic member)
33B: Elastic rubber (elastic member)
34, 44: Screw member (protrusion preventing member)

Claims (6)

1. A rotary drum comprising a rotary drum having a cylindrical filtration surface and a screw having a screw blade installed along the axial center of the rotary drum, (Solid-liquid separation) from a solids (solid content) and a separating liquid (separation liquid) by squeezing the object to be processed, which is supplied into the rotary drum through the two, as a screw press,
A shoe mechanism for removing solid matter adhering to the filtration surface is provided along the outer peripheral edge of the screw blade,
Wherein the shoe mechanism includes a shoe that resiliently slidably contacts the filtration surface, a storage body that houses the shoe, and a shoe that is flexible in the housing surface, And a protrusion preventing member for preventing the shoe from protruding from the accommodating body. The screw press according to claim 1, wherein the resilient member is a resilient member.
The method according to claim 1,
Wherein the shoe mechanism is provided over an entire periphery of the outer periphery of the screw blade.
3. The method according to claim 1 or 2,
Wherein the shoe mechanism has a plurality of shoples, and the plurality of shooses are all formed of an arc-shaped resin.
4. The method according to any one of claims 1 to 3,
Wherein the shoe mechanism has a plurality of elastic members, and the plurality of elastic members include at least one of a spring member and an elastic member formed by the elastic member.
5. The method according to any one of claims 1 to 4,
Wherein the protrusion preventing member is a screw member.
6. The method of claim 5,
Wherein the shoe has a hole through which the screw member is loosely fitted.

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