KR101867534B1 - Hydroextractor improved dehydration efficiency by the principle of increasing stay-time - Google Patents

Abstract

The present invention relates to a hydroextractor which relatively rotates a screw casing of a decanter shape and a dehydration screw at different speeds while the dehydration screw is inserted into the screw casing to centrifugally dehydrate sludge supplied into the screw casing via a screw shaft of the dehydration screw and, more specifically, to a hydroextractor with dehydration efficiency improved by the principle of increasing stay-time which forms protruding dehydration wedges having a triangular cross section at regular intervals in a transport direction of sludge by a screw wing on a surface of the screw wing corresponding to the transport area of low pressure side sludge adjacent to a screw shaft to quickly discharge a solid component of the sludge effectively dehydrated by a centrifugal force on an edge side in a screw casing out of the screw casing and apply a dehydration method of relatively increasing discharge time and a transport pressure of the sludge by extension of stay-time of the sludge by the dehydration wedges and sequential wedge-type pressing actions to a solid component of the sludge which was not effectively dehydrated by a centrifugal force by being positioned on a center side in the screw casing to induce uniform dehydration of the sludge from the edge side in the screw casing to the center side to improve overall dehydration performance.

Description

[0001] The present invention relates to a centrifugal dehydrator having improved dewatering performance by increasing the residence time,

The present invention relates to a dewatering device for dewatering a dewatering device such that a dewatering screw is inserted into a decanter-shaped screw casing and relatively rotating the screw casing and the dewatering screw at different speeds, Pressure side sludge adjacent to the screw shaft. The centrifugal dehydrator has a triangular shape at regular intervals along the conveying direction of the sludge by the screw blade on the surface of the screw blade corresponding to the conveying region of the low- So that the dewatering method that relatively increases the discharge time and the transfer pressure of the low-pressure side sludge is applied through the extension of the sludge residence time by the respective dewatering wedges and the successive wedge-type pressing action The dewatering performance is improved by the principle of increasing the residence time It relates to a dehydrator.

1 to 3, a centrifugal dehydrator widely used for dewatering sludge generally includes a dewatering screw casing 10 having a front inlet side formed with a cone portion 11 and a dewatering screw 20 The screw casing 10 and the dewatering screw 20 are provided so as to be able to relatively rotate at different speeds in a state where the screw casing 10 is inserted into the screw casing 10. To this end, The dewatering screw 20 is connected to the casing motor 10 through a central portion of the rear end side (the left end in FIG. 1) of the screw casing 10, and is connected to the casing motor 2 by a transmission unit And the rear end of the rotary shaft 6 is connected to the screw motor 3 by another electric power unit 16.

A bearing unit 5 for supporting the rotation of the screw casing 10 and the dewatering screw 20 is provided on the front face of the screw casing 10 and the rotational shaft 6 of the dewatering screw 20, A decelerator 7 is additionally provided in the chamber 6 immediately after the bearing unit 5 and the dehydrating screw 20 has a pipe shaft 21 and an outer circumferential surface of the shaft 21, And a sludge inlet pipe (4) is inserted and installed through the tip end of the screw shaft (21) in a penetrating manner, and the body of the screw shaft (21) And a sludge discharge port 12 and a dewatering discharge port 13 are formed on the front end side and the rear end side of the screw casing 10, respectively.

The sludge outlet 12 and the dehydrating solution outlet 13 are formed on the outer side of the screw casing 10 so that the sludge S and the dehydrated water component W discharged from the screw casing 10 are not mixed with each other, And a sludge discharge pipe 14 connected to the sludge discharge port 12 of the screw casing 10 is provided at the lower end side of the outer housing 9, And a dehydrating liquid discharge pipe 15 connected to the dehydrating liquid discharge port 13 of the screw casing 10 is connected to the lower side of the rear end side of the outer housing 9. The inside of the screw shaft 21 A partition plate 8 is provided at the center for limiting the inflow path of the sludge S to the front side portion of the dewatering screw 20. [

The conventional centrifugal dehydrator 1 constructed as described above is theoretically a product of the mass m of the sludge S and the circumferential acceleration rω ² and acts on the inside of the cylindrical wall of the screw casing 10 The dewatering solution W separated by the centrifugal force (F = mr? ² ) and the solid component in the sludge S by the centrifugal force is applied to the sludge S by the screw The solid component in the sludge S is discharged to the outside through the dewatering liquid discharge port 13 while being pushed backward along the inner wall surface of the casing 10 and the solids component in the sludge S flows along the dewatering screw 20 And then finally discharged to the outside through the sludge discharge port 12. [

In the process of discharging the solid component in the sludge S subjected to the first dehydration treatment by the centrifugal force to the sludge discharge port 12 via the cone portion 11 of the screw casing 10, The conveying efficiency (the feeding speed per unit time and the feeding amount) of the sludge S is relatively lowered due to the reduction of the sectional area of the cone portion 11, so that the residence time of the sludge S inside the cone portion 11 is naturally increased, The sludge S is gradually accumulated on the inside of the cone portion 11 and the sludge S which has been subjected to the first dehydration treatment by the centrifugal force is further squeezed and dewatered in the cone portion 11. [

However, in the conventional centrifugal dehydrator 1 as described above, due to the characteristics of the sludge S to be pressurized by the centrifugal force, the solids content in the sludge S is increased by the centrifugal force (F = mr? ² ) A dehydration treatment is performed in a manner totally dependent on the thickness r of the solidified sludge S accumulated in the casing 10 so that the portion close to the inner wall surface (inner peripheral surface) of the screw casing 10, that is, The dehydrating efficiency of the sludge S at a position far from the screw shaft 21 of the dehydrating screw 20 is high and is close to the screw shaft 21 of the dehydrating screw 20 The dehydration efficiency of the sludge S becomes significantly lower.

The dewatering efficiency of the sludge S by the conventional centrifugal dehydrator 1 is largely lowered due to the above factors. In order to compensate this, the pitch of the screw wings 22 of the dewatering screw 20 is increased, The distance between the threads is narrowed, or the distance between the threads is narrowed in accordance with Korean Patent No. 10-1056798 (Publication Date: Aug. 16, 2011) and Korean Patent No. 10-1383595 (Publication Date: Apr. 09, 2014) Pressure side sludge S is formed by forming an impeller-type protrusion along the surface of the screw blade 22 of the dewatering screw 20 to increase the dewatering ability of the low-pressure side sludge S And the like.

However, all of the above-mentioned conventional techniques are also dehydration systems that use the principle of squeezing the sludge S based on the centrifugal force, and the conditions of several factors affecting the dewatering ability by the centrifugal force such as the thickness of the sludge S have been improved The sludge S on the low pressure side is excessively pushed into the high pressure side and is squeezed so that the smooth discharge of the sludge S can not be performed naturally. This is because the inside of the cone portion 11 of the screw casing 10 is filled with sludge S ) Of the centrifugal dehydrator 1 is caused to cause a mechanical load which is considerable in the operation of the centrifugal dehydrator 1, leading to failure or malfunction of the centrifugal dehydrator 1.

Korean Patent No. 10-1056798 Korean Patent No. 10-1383595

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a sludge- A dewatering wedge having a triangular cross section is protruded so that the sludge solid matter component smoothly dewatered by the centrifugal force from the inner side of the screw casing can be quickly discharged to the outside of the screw casing, The sludge solid component which is not smoothly dewatered by centrifugal force is composed of a dewatering system which relatively increases sludge discharge time and transfer pressure through extension of sludge residence time and successive wedge pressing operation by each dehydration wedge , And through this, It is an object of the present invention to provide a centrifugal dehydrator which improves dewatering performance by inducing even dewatering of sludge from the inner periphery side to the center side of the sintering furnace, to be.

According to the present invention as a means for solving the above problems, a screw casing and a dewatering screw are relatively rotatable at different speeds in a state that a dewatering screw is inserted into a decanter-like screw casing formed with a cone portion on the front inlet side Wherein the dewatering screw includes a pipe-shaped screw shaft and a screw blade connected to the screw shaft in a spiral shape along the outer circumferential surface of the screw shaft. The sludge injecting pipe is inserted through the tip of the screw shaft, And a sludge discharge port and a dewatering liquid discharge port are formed in a tip end side and a rear end side of the screw casing, the centrifugal dewatering device comprising: On the surface of the corresponding screw blade, At regular intervals in the conveying direction of the sludge by dehydration it characterized in that the wedge is formed having a protruding end surface of the triangular shape.

The dewatering wedge may be disposed at equal intervals along corresponding screw vane portions within two to five pitches from the tip end side of the screw shaft where the cone portion of the screw casing starts, Has a length corresponding to 30 to 60% of the length of the straight line extending from the outer circumferential surface of the screw shaft to the end of the screw blade and a length corresponding to 20 to 40% of the length of the screw extending 360 degrees in the circumferential direction of the screw blade, Wherein each of the dewatering wedges has an introduction angle and an outflow angle on a sludge transport path by a screw blade, the introduction angle is 15 to 30 degrees, And the outflow angle is 30 to 60 degrees.

According to the present invention, the sludge solid component, which is located in the low-pressure side transfer region adjacent to the screw shaft of the dewatering screw and can not be dewatered smoothly due to the centrifugal force, is extended by the dewatering wedge of each sludge, The dewatering method which relatively increases the discharge time and the transferring pressure of the sludge is applied through the wedge pressing operation to induce the even dewatering of the sludge from the inner side of the screw casing to the center side, Thereby providing an effect that can be improved.

In particular, the sludge on the low-pressure side is not pushed into the sludge on the low-pressure side, but the sludge on the low-pressure side is naturally conveyed and compressed by the respective dewatering wedges for a relatively long time at the inner center side of the screw casing adjacent to the screw shaft, The sludge on the low pressure side is excessively conveyed and squeezed to the high pressure side area, and cone part on the front side of the screw casing is clogged, thereby preventing overload of the centrifugal dehydrator and malfunction or malfunction of the centrifugal dehydrator. And can provide a very useful effect.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side cross-sectional view showing a dehydration principle of a conventional centrifugal dehydrator;
FIG. 2 is an explanatory enlarged view of the main part of FIG. 1; FIG.
3 is an external perspective view of a dehydrating screw used in a conventional centrifugal dehydrator.
4 is a magnified explanatory view showing the principle of dewatering of a centrifugal dehydrator according to the present invention.
5 is an external perspective view of a dehydrating screw used in the centrifugal dehydrator of the present invention.
6 is an enlarged view of a portion "A"
Fig. 7 is a side view of the main part of the screw blade showing the arrangement state of the dehydrating wedge; Fig.
8 is a comparison of sludge residence time according to whether or not a dehydrated wedge is applied.
9 is a front sectional view of a dewatering screw illustrating the difference in sludge circumferential velocity with application of the dewatering wedge;

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

4 to 7, in the case of the centrifugal dehydrator 1 according to the present invention, the deaerating screw 20 is disposed inside the decanter-shaped screw casing 10 formed with the cone portion 11 on the front inlet side The screw casing 10 and the dewatering screw 20 are installed such that the screw casing 10 and the dewatering screw 20 are rotatable relative to each other at a different speed while the dewatering screw 20 is mounted on the screw shaft 21 And a screw blade 22 connected in a spiral shape along the outer circumferential surface of the screw shaft 21. The screw shaft 21 has a structure in which the inlet hole 23 of the sludge S is formed on the body portion of the screw shaft 21, do.

In addition to the basic structure mentioned above, the remaining components constituting the centrifugal dehydrator 1 are considered to be in line with the one described with reference to Fig. 1. As a substantial component of the present invention, (Indicated by arrows in FIG. 5) on the surface of the screw blade 22 corresponding to the conveyance area of the low-pressure side sludge S2 adjacent to the screw shaft 21 of the screw 20 in the conveying direction of the sludge S by the screw blade 22 A dehydration wedge 24 having a triangular cross-section at a predetermined interval is protruded.

The dewatering wedge 24 may be disposed over all of the screw vanes 22 constituting the dewatering screw 20. The dewatering wedge 24 may extend from the tip end side of the screw shaft 21 at which the cone portion 11 of the screw casing 10 starts It is most preferable to arrange the screw blades 22 at equal intervals within a range of 2 pitches to 5 pitches at the same intervals along the portion of the corresponding screw vanes 22. This is because the partition plate 8 is installed at the inner center portion of the screw shaft 21 Only the portion of the screw blade 22 on the inside of the cone portion 11 where the main dewatering treatment of the sludge S is required is dewatered so that the sludge S is concentrated on the front side portion of the dewatering screw 20. Therefore, This is because it is most reasonable and economical to concentrate the wedge 24.

A wedge-shaped dewatering wedge 24 having a triangular cross section is protruded from the front face of the screw blade 22 of the dewatering screw 20 inserted into the cone portion 11 on the front side of the screw casing 10 as described above, When the wedge 24 is disposed on the transfer area of the low-pressure side sludge S2 adjacent to the screw shaft 21 of the dewatering screw 20, the high-pressure side sludge S1, in which dewatering by centrifugal force is smooth, Pressure side sludge S2, which can not be dewatered by the centrifugal force at a position close to the screw shaft 21, can be quickly transferred and discharged through the dewatering wedge 24, It can be slowly transferred and discharged at a speed.

In other words, in the case of the centrifugal dehydrator 1 according to the present invention, as shown in FIGS. 8A and 8B, the residence time of the sludge S in the region of the cone region 11 is T1 and T2 T1 is the sludge retention time at the high pressure side region where the dehydration wedge 24 is not formed and T2 is the sludge retention time at the low pressure side region where the dehydration wedge 24 is formed. The retention time T2 of the low-pressure side sludge S2 is higher than the retention time T2 of the high-pressure side sludge S1, because the time required for the low-pressure side sludge S2 to pass through the feed path further provided on the surface of the screw blade 22 by the dewatering wedge 24, Is longer than the time T1.

9, the circumferential speed of the high-pressure side sludge S1 not passing through the dewatering wedge 24 is V1, and the dehydration wedge 24 (see FIG. 9) And the circumferential speed of the low pressure side sludge S2 not passing through the dehydrating wedge 24 is V2 and the circumferential speed of the low pressure side sludge S2 passing through the dehydrating wedge 24 is V3, The circumferential velocity {V = (? DN) -R} having the resistance R of the dewatering wedge 24 as a variable becomes V1> V2> V3, because the radius D of the sludge S is the same , The peripheral velocity V3 of the low-pressure side sludge S2 passing through the dehydrating wedge 24 becomes the slowest.

In accordance with the above-described principle, the residence time of the sludge S in the low-pressure side region can be relatively increased. In addition, in the boundary line indicated by the sludge front end face S3 in Figs. 6 and 9, The shear force generated by the dehydrating wedge 24 between the sludge S accumulated on the inside of the high pressure side sludge S 1 and the low pressure side sludge S 2 region can be minimized Pressure side sludge S1 can be smoothly conveyed and discharged while the conveyance path of the low-pressure side sludge S2 and the dewatering time can be ensured as long as possible.

In addition, when the sludge S is filled between the respective screw vanes 22 disposed in the cone portion 11, each of the dewatering wedges 24 has a function of increasing the residence time of the low-pressure side sludge S2 A squeezing type dewatering function in which the sludge S is wedged and pressed to the rear surface of the screw vane 22 facing each dewatering wedge 24 can be additionally provided. Since the function is generated chained in accordance with the rotation of the dewatering screw 20, the dewatering performance of the low-pressure side sludge S2 can be greatly improved as compared with the conventional centrifugal dehydrator 1. [

7, each dewatering wedge 24 has different inlet angles? And outflow angles? On the sludge transport path by the screw vanes 22, It is preferable that the introduction angle alpha is in the range of 15 to 30 degrees for smooth entry and compression of the sludge S and the expansion (relaxation) of the compressed sludge S is promptly induced, The outflow angle β is preferably within the range of 30 to 60 degrees, and the dehydration wedge 24 of the triangular cross section is the most preferable application example.

The preferable range of the dimension of each dehydrating wedge 24 is a width corresponding to 30 to 60% of the straight length (the thread height of the screw vanes) from the outer circumferential surface of the screw shaft 21 to the end portion of the screw vane 22 (That is, one pitch corresponding to one pitch) of the screw vanes 22 in the circumferential direction of 360 degrees of the screw vanes 22, as shown in Fig. 9, 20 to 40% of the circumferential length of the screw blades), and at least 2 to 5 per pitch of the screw blades 22.

The reason for limiting the arrangement condition of the dehydrating wedge 24 in the above-mentioned dimensional range is that if the number of the dehydrating wedges 24 is less than one pitch on the basis of one pitch of the screw vanes 22, It is difficult to adequately secure the dewatering performance through the extension of the time and the successive wedge-type pressing action, and the installation of six or more dewatering wedges 24 on the basis of one pitch of the screw vanes 22, This is because the manufacturing itself is complicated and the weight dispersion and balance of the screw blades 22 across the screw shaft 21 may be adversely affected.

The dewatering wedge 24 may be further disposed on the screw blade 22 corresponding to the rear side of the cone portion 11 over a range of about one to two pitches as the need arises. It is preferable to apply only to the case where the inflow hole 23 is also formed at the rear side position beyond the center of the screw shaft 21 and the dehydration wedge 24 Are preferably provided in an even number as much as possible for each screw blade 22 forming each pitch from the start position of the cone portion 11.

As a further matter, each dehydrating wedge 24 may be made as a separate part from the screw vane 22 and attached to the screw vane 22 to make it more economical, and the dehydrating wedge 24 itself The dewatering wedge 24 contacting the sludge S can be regarded as the most preferable in terms of securing the structural strength, and the dewatering wedge 24, which is in contact with the sludge S, It is preferable to form an abrasion-resistant coating layer by a stellite on the surface of the base material so as to secure sufficient durability.

According to the centrifugal dehydrator 1 of the present invention as described above, the sludge (S) solid component which is located in the low-pressure side transfer region adjacent to the screw shaft 21 of the dewatering screw 20 and can not be dewatered smoothly by the centrifugal force, The dewatering system in which the discharge time and the transfer pressure of the sludge S are relatively increased through the extension of the residence time of the sludge S by the respective dewatering wedges 24 and the successive wedge pressing operation is applied, It is possible to induce even dewatering of the sludge S from the inner periphery side to the center side of the casing 10, thereby further improving the overall dewatering performance.

Pressure side sludge S2 is not pushed into the high pressure side sludge S1 but the low pressure side sludge S2 is discharged by the respective dewatering wedge 24 to the screw casing 10 Pressure side sludge S1 is excessively conveyed and pressed to the area of the high pressure side sludge S1 so that the screw casing 10 is moved forward The cone portion 11 of the centrifugal dehydrator 1 is blocked and the overload of the centrifugal dehydrator 1 and the failure or malfunction of the centrifugal dehydrator 1 can be prevented in advance.

1: Centrifugal dehydrator 2: Casing motor 3: Screw motor
4: sludge inlet pipe 5: bearing unit 6: rotating shaft
7: Reduction gear 8: Partition plate 9: Outer housing
10: Screw casing 11: Cone part 12: Sludge outlet
13: Dewatering liquid discharge port 14: Sludge discharge pipe 15: Dewatering liquid discharge pipe
16: electric power unit 20: dehydrating screw 21: screw shaft
22: screw blade 23: inflow hole 24: dehydrated wedge
S: Sludge S1: High-pressure side sludge S2: Low-pressure side sludge
S3: sludge shear section α: introduction angle β: outflow angle
T1, T2: Sludge residence time V1, V2, V3: Sludge circumferential velocity
W: dehydrated solution

Claims (4)

The screw casing 10 and the dewatering screw 20 are relatively rotated at different speeds in a state where the dewatering screw 20 is inserted into the decantered screw casing 10 having the front inlet side formed with the cone portion 11 Wherein the dewatering screw 20 comprises a pipe-shaped screw shaft 21 and a screw blade 22 connected in a spiral shape along the outer circumferential surface of the screw shaft 21, A sludge inlet pipe 4 is inserted through the tip end of the screw shaft 21 and an inlet hole 23 of the sludge S is formed in the body of the screw shaft 21, (1) having a sludge discharge port (12) and a dewatered liquid discharge port (13) formed on the front end side and the rear end side of the centrifugal dehydrator (10)
The surface of the screw blade 22 corresponding to the transfer area of the low pressure side sludge S2 adjacent to the screw shaft 21 is formed with a triangular shape at regular intervals along the conveying direction of the sludge S by the screw blade 22. [ A dewatering wedge 24 having a cross section of the dewatering wedge 24 is protruded,
The dehydrating wedge 24 has a width corresponding to 30 to 60% of the straight line length from the outer circumferential surface of the screw shaft 21 to the end of the screw vane 22, Wherein a length corresponding to 20 to 40% of a spiral length is provided in a minimum of two to five per pitch of the screw blade (22), wherein the dewatering performance is improved by the dwelling time increasing principle. The dewatering wedge (24) according to claim 1, wherein the dehydrating wedge (24) is a screw wing (22) portion corresponding to a pitch ranging from 2 to 5 pitches from the tip end side of the screw shaft (21) The centrifugal dehydrator according to claim 1, wherein the dewatering performance is improved by increasing the dwell time. delete 3. A method as claimed in claim 1 or 2, wherein each dehydrating wedge (24) has an inlet angle (?) And an outlet angle (?) On the sludge (S) (?) is 15 to 30 degrees, and the outflow angle (?) is 30 to 60 degrees. The centrifugal dehydrator according to claim 1, wherein the dehydration performance is improved by the residence time increasing principle.

Images