KR20100074685A - The separating screw decanter centrifuges having multi-step adjusting slot dam plate and method for adjusting collecting rate of separating water of separating screw decanter centrifuges using multi-step adjusting slot dam plate - Google Patents

Abstract

PURPOSE: A centrifugal separator having a slot dam plate and a method for controlling the same are provided to simply control a cake and discharge separated liquid without changing dam flange. CONSTITUTION: A method for controlling a centrifugal separator comprises: a step of classifying sludge into separated liquid and dehydrated cake(concentrate); a step of rotating bowl and tapered bowl to discharge the separated liquid; a step of discharging dehydrated cake through an outlet; and one or more slot plates(1) of multi-step control which is mounted.

Description

The separating screw decanter centrifuges having multi-step adjusting slot dam plate and method for adjusting collecting rate of separating the centrifuge with multi-stage adjustable slot dam plate and the multi-step adjusting slot dam plate. water of separating screw decanter centrifuges using multi-step adjusting slot dam plate}

The present invention relates to a method for controlling the removal rate of the desorption liquid of a centrifuge using a centrifugal separator equipped with a multistage control slot dam plate and a multistage control slot dam plate, and in detail, a separation liquid (or desorption liquid formed at one end of a large diameter shaft of the centrifuge) The present invention relates to a centrifuge and a multistage control method in which the discharge amount of the separating liquid (or desorption liquid) discharged from the discharge port is controlled in multiple stages using a multistage control slot dam plate.

Generally, centrifugal dehydrator or concentrator (hereinafter referred to as "centrifuge") that separates sludge supplied into water and solids through a sludge inlet pipe that supplies sludge from treatment processes such as sewage, manure, industrial wastewater, and livestock wastewater. The sludge supplied in the above) is subjected to mechanical centrifugal force, and the sludge concentration of the solid is concentrated or dewatered at a predetermined ratio by the centrifugal force, and the sludge is concentrated or dewatered, and the sludge discharged from the concentrated and dewatered centrifuge. The concentration and dehydration of the solids is achieved by varying the dams or skimmers per minute between the screw conveyor corresponding to the sludge discharge rate and the external fluid, or the depth of the liquid in the rotor.

According to the accompanying drawings, a structure of a centrifuge of a conventional conventional concentrator and dehydrator will be described below.

Figure 4 is a block diagram showing a cross-sectional view of the skew flow decanter centrifuge for dewatering, condensing the conventional general sludge, as shown in the configuration and action of the conventional concentrated and dehydrator centrifuge sludge input pipe 501 located on the right side Sludge supplied through the discharge through the discharge port 516 of the internal motion screw conveyor 512, it can be seen that the centrifugal force is configured to classify into supernatant (detachment or separation liquid), dehydration cake and concentrate.

The desorption liquid or separation liquid flows out through the desorption liquid or the separation liquid discharge port 511 by the rotation of the outer copper bowl 506 and the outer taper bowl 507, and the desorption liquid or the separation liquid discharge port 502 through one casing 502. Is discharged by

In addition, the dewatering cake and the concentrate is dehydrated or concentrated by the inner bowl 506 and the outer taper bowl 507 and the inner screw conveyor 512 rotates at a slow rotational speed with a rotary difference, the dewatering cake and the concentrate outlet 508 To the side. Then, the dewatered and concentrated sludge at the required water content and concentration is discharged by the discharge port 503 from the cake and the concentrated liquid discharged from the discharge port 508.

Rotational force of the outer bowl 506 and the outer taper bowl 507 is a rotation shaft and one side of the outer taper bowl 507 rotated by the drive pulley through the drive motor 513 and the drive pulley 510 installed on the right side The other end of the outer bowl 506 coupled with the outer tapered bowl 507 is rotated in conjunction with the bearing block (519, 520) is assembled to the large diameter shaft 515 and installed on the frame 505 and rotated Done. As a result, the introduced sludge is centrifuged to separate the desorption solution or the separation liquid, the dehydrated cake and the concentrate.

In addition, the rotational force of the screw conveyor 512 is transmitted through the differential motor 514 and the differential pulley through the shaft 509 rotating by the differential pulley. The shaft 509 is configured to rotate through the large diameter shaft 515 installed in the bearing block 519 to rotate inside the outer bowl 506 and the outer taper bowl 507. Accordingly, when the shaft 509 rotates, a screw conveyor 512 formed around the shaft 509 transfers the dehydrated cake and the concentrate in one direction.

Reference numeral 504 in the figure is a base frame that is installed on the ground to support the load of the entire centrifuge to dehydrate, concentrate.

On the other hand, a plurality of separation liquid discharge port 511 formed in the circular direction on the large diameter axis 515 of the centrifuge having the structure as described above is provided with a dam plate for adjusting the size of the hole, by such a dam plate Recovery and water content are controlled. That is, the dehydration cake is measured below the reference value of the moisture content, and the desorption liquid or the separation solution should also be measured above the reference value, which is called the recovery rate. If the dam is lowered (Ø larger) at the stage, the water content will be worse, but the recovery will be better, and if the dam is increased (Ø smaller), the water content will be better and the recovery will be worse.

Such a conventional flange dam is shown in Figures 5 to 7, Figure 5 is an illustration of a dam flange for adjusting the recovery rate of the separation liquid discharge port formed in the conventional large diameter shaft, Figure 6 is a separation liquid soil formed in the conventional large diameter shaft FIG. 7 is an exemplary view showing a state in which a dam flange for adjusting the recovery rate of the outlet is rotatably mounted, and FIG. 7 is a view illustrating a two-stage dam flange capable of adjusting only the recovery rate corresponding to two diameters by conventional rotation attachment.

As shown in the drawing, the conventional dam plate 521 has two upper and lower sides, and is fastened to a bolt hole formed on a large diameter shaft through holes formed in each dam plate, thereby reducing the open area of the separation liquid outlet 511 by two. However, in this way, the recovery rate and the moisture content are adjusted according to the ratio of the open area or the closed area of the separation liquid discharge port 511. FIG. 6 illustrates an example in which the recovery and water content are adjusted by adjusting the dam height adjustment to Ø 264, and FIG. 7 illustrates an example in which the dam height is adjusted to Ø 260 by rotating the same dam plate disclosed in FIG. 6.

Looking at the structure of such a dam plate 521 in detail in accordance with Figure 7 the inner diameter is processed in two stages with two diameters (for example Ø264, Ø260) to be adjusted in two stages. Therefore, in order to adjust the diameter (Ø) to have a desired recovery rate or water content, the desired diameter (Ø) is rotated to cover the separation liquid outlet 511 by rotating the marked portion, and then the bolt is fastened by attaching it to the large diameter shaft.

However, although the conventional rotatable dam plate 521 is manufactured in two stages, if there is no dam flange prepared to adjust the recovery rate and water content of the centrifugal separator installed in the field, the dam flange is prepared by relasing without work finishing. There is no need to adjust the dam again, and because there is no laser processing site near the site, it takes a lot of time and manpower, and there is a problem that the dam adjustment of the operating centrifuge is delayed. have.

Moreover, not only the dam flange that can adjust the two diameters according to the work is required, but there are problems that a plurality of individual dam flanges with various diameters are required for various diameter adjustments.

However, it is still a reality that there is no centrifugal separator equipped with an opening and closing area control means of the separation liquid discharge port 511 to solve the problems of the conventional dam flange structure as described above.

An object of the present invention for solving the above problems is not to replace the use of a number of dam flanges when adjusting the discharge amount of the separation liquid (or stripping liquid) discharged from the separation (or stripping liquid) discharge port formed at one end of the large diameter axis of the centrifuge The present invention provides a centrifugal separator that allows a simple control of a stripping solution or a cake having various recoveries or moisture contents by varying the height of the dam plate in a multi-stage without replacement using a single-stage adjusting slot dam plate.

In addition, another object of the present invention is to adjust the discharge amount of the separation liquid (or desorption liquid) discharged from the separation (or desorption liquid) discharge port formed at one end of the large diameter axis of the centrifugal separator without using multiple dam flanges in one multi-stage control slot The present invention provides a method for controlling the separation liquid recovery rate of a centrifuge in which the height of the dam plate is variably adjusted without using a dam dam plate to easily discharge the desorption liquid or cake having various recovery rates or moisture contents.

The present invention to achieve the object as described above and to perform the problem for removing the conventional defects, the sludge is supplied through the sludge input pipe and discharged to the discharge port of the screw conveyor separated by centrifugal force (or desorption liquid) and dehydration cake (Or concentrate), the supernatant separation liquid (or desorption liquid) is separated into one casing through a large diameter separation liquid (or desorption liquid) discharge port installed on one side of the outer copper bowl by the rotation of the outer and outer taper bowls. After collecting, the dehydrating cake (or concentrate) is discharged to the outlet, and the dehydrating cake (or concentrate) is transferred to the screw tape conveyor in the direction of external taper bowl, and then the dewatering cake (or concentrate) outlet is discharged to the dehydrating cake (or concentrate) outlet. In the dewatering, condensing screw decanter centrifuge comprising a configuration for discharging,

One or more multistage adjusting slot plates linearly moving in the direction of the center of the large diameter axis to have a desired recovery rate of the desired separation liquid on the outside of the separation liquid discharge port are installed in the large diameter axis to variably control the opening degree of the one or more separation liquid discharge ports. It is achieved by providing a centrifuge equipped with a multi-stage adjustable slot dam plate, characterized in that it is constructed so as to.

The multistage control slot plate has a size that can cover the area of the separation liquid discharge port and at the same time having an extra left and right areas; Slots each formed on both sides of the dam so as not to contact the separation liquid discharge port; Characterized in that consisting of; pitch circle diameter formed a plurality of stamps or printed on the surface of the dam to have a different diameter.

The slot is formed in the shape of a long hole, but smaller than the head diameter of the fixing bolt, the fixing bolt is configured to be fastened by installing two per one slot, three holes formed in the large diameter shaft is formed per one slot It is characterized in that it is configured to be able to change the fastening position of the fixing bolt according to the degree of back and forth of the dam.

The multi-stage control slot plate is characterized in that one or more circularly arranged to correspond to the one or more separation liquid discharge port is circularly arranged.

The separation liquid discharge port is formed in a rectangular shape, the left and right shapes form a straight line running toward the central axis of the large axis, and the upper and lower shapes are configured to have a form consisting of an arc based on the center of the large axis. .

The multi-stage adjusting slate has a rectangular shape, and the left and right shapes form a straight line running toward the center direction of the large diameter axis, and the upper and lower shapes are formed to have a shape consisting of an arc based on the center of the large diameter axis. It is done.

The fixing bolt is characterized in that the hexagon wrench bolt.

A hole is formed in the large diameter shaft, and the fixing bolt penetrates the slot and is configured to fasten a bolt to a hole formed in the large diameter shaft; and a circular or imprinted or printed dam height reference line is formed on the circular surface of the large diameter shaft. It features.

In the present invention, the sludge is supplied through the sludge inlet pipe and then discharged to the toe outlet of the screw conveyor, and separated by centrifugal force into a separation liquid (or desorption liquid) and a dehydrating cake (or concentrate), and the supernatant separation liquid (or desorption liquid) is By rotating the outer bowl and the outer taper bowl, it is collected into one casing through the large diameter separating liquid (or desorbing liquid) discharge port installed on one side of the outer copper bowl, and then discharged into the separating liquid (or desorbing liquid) outlet, and the dewatering cake (or Concentrate) is a screw decanter centrifuge for dewatering and condensing centrifuges comprising a sludge fed into the screw conveyor in the direction of the outer taper bowl and discharged to the dewatering cake (or concentrate) outlet through the dehydrating cake (or concentrate) outlet In the separation liquid recovery rate control method,

Arbitrary separation is achieved by installing a multi-stage adjusting slot dam plate corresponding to each separation liquid outlet outside the one or more separation liquid outlets and linearly moving in the direction of the center of the large diameter axis to variably control the opening area of the separation liquid outlet in multiple stages. It is achieved by providing a separation liquid recovery rate multi-stage control method of a centrifuge using a multi-stage control slot dam plate characterized by a method for discharging the separation liquid having a liquid recovery rate.

The multistage control slot plate has a size that can cover the area of the separation liquid discharge port and at the same time having an extra left and right areas; Slots each formed on both sides of the dam so as not to contact the separation liquid discharge port; and a plurality of pitch circle diameters having different diameters imprinted or printed on the surface of the dam;

A hole is formed in the large diameter shaft, and the fixing bolt is configured to be bolted to the hole formed in the large diameter shaft while supporting the slot.

The method of variably adjusting the opening area in multiple stages includes a pitch circle diameter formed with a plurality of different diameters imprinted or printed on the surface of the dam of the multi-stage adjusting slot plate on the dam height reference line imprinted or printed on the circular surface of the large diameter shaft. It is characterized by a method of controlling the recovery of the separation by linearly moving to adjust to the desired diameter.

The present invention uses one multi-stage adjusting slot dam plate without replacing several dam flanges when adjusting the discharge amount of the separating liquid (or desorbing liquid) discharged from the separating liquid (or desorbing liquid) discharge port formed at one end of the large diameter shaft of the centrifuge. The advantage of using without replacement,

It is a useful invention with the advantage that it is possible to simply discharge the desorption liquid or cake having various recovery rate or water content by varying the height of the dam plate in multiple stages using one multi-stage adjusting slot dam plate. It is the invention which is expected greatly.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is an exemplary view showing that the multi-stage control slot dam plate according to an embodiment of the present invention is installed on a large diameter axis, Figure 2 is an exemplary view showing a multi-stage control slot dam plate according to an embodiment of the present invention. Is

As shown, the multi-stage adjusting slot dam plate 1 provided in the centrifugal separator of the present invention is installed outside the separation liquid discharge port 511 formed at the large diameter shaft 515 at one end of the outer bowl 506. .

At this time, the shape of the separation liquid discharge port 511 according to an embodiment of the present invention may be formed such that a plurality of circular holes are arranged in a circular arrangement like a general separation liquid discharge port 511, but preferably made of a rectangular shape, but the left and right shapes are large. It is preferable to form a straight line running toward the center of the axis of the axis of rotation, and the upper and lower shapes have a form of an arc with respect to the center of the axis of the major axis of rotation.

It is also desirable to have the corners have a rounded shape. When formed in this way, it is possible to precisely adjust the recovery rate when the slot dam plate is adjusted to various dam heights.

If the shape of the multi-stage adjusting slot plate 1 is a shape capable of blocking the separation liquid discharge port 511, preferably, the left and right shapes form a straight line running toward the center direction of the large diameter axis, and the upper and lower shapes are large diameter axis. It is formed to have a shape consisting of an arc based on the center of the, and the corners have a rounded shape.

In addition, the left and right width can cover all the separation liquid discharge port 511 and the dam (11) having a width having an extra area; Slots 12 formed on both sides of the dam 11 to be in contact with the separation liquid discharge port 511, and a plurality of pitch circle diameters having a different diameter stamping or printed surface of the dam 11 (13);

The reason why the slots 12 are formed on both sides of the dam 11 is that the multi-stage adjusting slot plate 1 moves forward and backward with respect to the center direction of the large diameter axis 515 to adjust the recovery rate of the desired separation liquid or the moisture content of the cake. Two fixing bolts (2) which are screwed into three holes (5152) formed by drilling and tapping the side of the large diameter shaft (515) at the time of fixing to set the diameter to have a desired separation liquid recovery rate Preferably, the hexagon wrench bolts are pressed to fix the dam 11 to the side of the large diameter axis by pressing the dam 11 in the state inserted into the slot 12.

In addition, it is to prevent the forward and backward movement of the multi-stage adjustment slot plate (1) by the bolt (2) screwed into the hole (5152).

The shape of the slot 12 is preferably formed in a long hole shape, it is formed smaller than the head diameter of the fixing bolt (2).

In addition, the fixing bolt 2 is fastened by installing two per one slot, but the hole is formed three per one slot to change the fastening position of the fixing bolt according to the degree of forward and backward of the dam. This will guide the slot smoothly when linearly moving the fastening force of the multi-stage control plate and the multi-stage control plate.

On the other hand, the dam height reference line (3) stamped or printed on the circular surface of the large diameter axis in the drawing is a dam that covers the separation liquid discharge port 511 formed on the large diameter axis of the external ball when the slot dam plate (1) is adjusted up and down (11) It indicates the Ø of the circle whose height can be adjusted.

That is, it is a reference line used when adjusting the recovery rate by adjusting the pitch circle diameter 13 formed in plural numbers having different diameters imprinted or printed on the dam 11 to the dam height reference line 3.

Figure 3 is an exemplary view showing the operation of adjusting the recovery rate of the separation liquid discharge port using the multi-stage adjusting slot dam plate according to an embodiment of the present invention.

As shown in the drawing, the separation liquid (or desorption liquid) is discharged through a plurality of separation liquid discharge ports 511 formed around the center portion, and each other is imprinted or printed on the dam 11 by using the multi-stage adjusting slot dam plate 1. A plurality of pitch circle diameters 13 having different diameters were adjusted to the dam height reference line 3 to adjust the recovery rate.

That is, when the larger diameter (outer side) of the pitch circle diameter 13 of the multi-stage adjusting slot dam plate 1 is aligned with the dam height reference line 3, the multi-stage adjusting slot dam plate 1 is lowered toward the center. At this time, if the fixed bolt is fixed to the large shaft, the level of solids (sludge) in the outer bowl is increased. At this time, the water content of the dehydrated (condensed) cake is increased, but the recovery rate of the separation liquid (or desorption liquid) is deteriorated.

On the contrary, when the smaller diameter (inside) of the multi-stage adjusting slot dam plate (1) is aligned with the dam height reference line (3), the multi-stage adjusting slot dam plate (1) rises from the center to the outside. Fixing to a large diameter shaft using a lower the water level of the solids (sludge) in the outer ball, the water content of the dehydrated (concentrated) is worse, the recovery rate of the separation liquid (or desorbing liquid) is improved.

The reason for this is that the cake is located in the outer side of the outer bowl by centrifugal force and the cake is separated from the outside, so the water is located inside the cake. Because it is.

That is, when the large diameter number of the multi-stage adjusting slot dam plate pitch diameter 13 is aligned with the dam height reference line 3, the water content> recovery rate is satisfied.

If the smaller diameter number of the multi-stage adjusting slot dam plate pitch circle diameter 13 is matched to the dam height reference line 3, the water content <recovery rate is satisfied.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is an exemplary view showing that the multi-stage adjusting slot dam plate according to an embodiment of the present invention is installed on a large diameter axis,

Figure 2 is an exemplary view showing a multi-stage adjustable slot dam plate according to an embodiment of the present invention,

Figure 3 is an exemplary view showing the operation of adjusting the recovery rate of the separation liquid discharge port using a multi-stage control slot dam plate according to an embodiment of the present invention,

Figure 4 is a block diagram showing a cross-section of the conventional skew decanter centrifuge for dewatering and concentrating the sludge,

5 is an exemplary view in which a dam flange for adjusting a recovery rate of a separation liquid discharge port formed in a conventional large diameter shaft is provided.

Figure 6 is an exemplary view showing a state that the dam flange is rotated mounted to adjust the recovery rate of the separation liquid discharge port formed in the conventional large diameter shaft,

Figure 7 is an exemplary view showing a two-stage dam flange that can only adjust the recovery rate corresponding to the two diameters by the conventional rotation attachment.

<Description of the symbols for the main parts of the drawings>

(1): Multi-stage slot plate (2): Fixing bolt

(3): Dam height reference line (11): Dam

(12): Slot (13): Dam height pitch circle diameter

(511): separation liquid discharge port (515): large diameter axis

(5152): hall

Claims (11)

Sludge is supplied through the sludge inlet pipe and discharged to the discharge port of the screw conveyor. The sludge is separated into a separation liquid (or desorption liquid) and a dehydrating cake (or concentrate) by centrifugal force. By rotating the tapered bowl, the large diameter shaft is installed to one side casing through the large diameter separating liquid (or stripping liquid) discharge port installed on one side, and then discharged to the separating liquid (or stripping liquid) outlet, and the dewatering cake (or concentrate) is screw conveyor. In the dewatering, concentrated screw decanter centrifuge comprising a configuration in which the sludge injected into the outer taper bowl direction and then discharged to the dewatering cake (or concentrate) outlet through the dehydration cake (or concentrate) discharge port, One or more multistage adjusting slot plates linearly moving in the direction of the center of the large diameter axis to have a desired recovery rate of the desired separation liquid on the outside of the separation liquid discharge port are installed in the large diameter axis to variably control the opening degree of the one or more separation liquid discharge ports. Centrifugal separator equipped with a multi-stage adjustable slot dam plate, characterized in that the configuration. The method according to claim 1, The multistage control slot plate has a size that can cover the area of the separation liquid discharge port and at the same time having an extra left and right areas; Slots each formed on both sides of the dam so as not to contact the separation liquid discharge port; Centrifugal separator equipped with a multi-stage adjustable slot dam plate, characterized in that consisting of; multiple pitch circle diameter formed to have different diameters imprinted or printed on the surface of the dam. The method according to claim 2, The slot is formed in the shape of a long hole, smaller than the head diameter of the fixing bolt, The fixing bolt is configured to be fastened by installing two per one slot, And a plurality of holes formed in the large diameter shaft so that three holes are formed per one slot so that the fastening position of the fixing bolt can be changed according to the degree of forward and backward movement of the dam. The method according to claim 1, The multi-stage control slot plate is a centrifuge having a multi-stage control slot dam plate, characterized in that one or more of the circular arrangement corresponding to the one or more separation liquid discharge port of the circular arrangement. The method according to claim 2, The separation liquid discharge port is formed in a rectangular shape, the left and right shapes form a straight line running toward the central axis direction of the major axis, and the upper and lower shapes are configured to have a form consisting of an arc based on the center of the major axis. Centrifuge with multi-stage slotted dam plates. The method according to claim 2, The multi-stage adjusting slate has a rectangular shape, and the left and right shapes form a straight line running toward the center direction of the large diameter axis, and the upper and lower shapes are formed to have a shape consisting of an arc based on the center of the large diameter axis. Centrifuge with multistage adjustable slot dam plates. The method according to claim 2, The fixing bolt is a hexagon wrench bolt, characterized in that the centrifugal separator equipped with a multi-stage adjusting slot dam plate. The method according to claim 1, A hole is formed in the large diameter shaft so that the fixing bolt penetrates the slot and is configured to fasten the bolt to the hole formed in the large diameter shaft; Centrifugal separator equipped with a multi-stage adjustable slot dam plate, characterized in that the base surface of the large diameter axis is stamped or printed dam height baseline. Sludge is supplied through the sludge inlet pipe and discharged to the discharge port of the screw conveyor. The sludge is separated into a separation liquid (or desorption liquid) and a dehydrating cake (or concentrate) by centrifugal force. By rotating the tapered bowl, the large diameter shaft is installed to one side casing through the large diameter separating liquid (or stripping liquid) discharge port installed on one side, and then discharged to the separating liquid (or stripping liquid) outlet, and the dewatering cake (or concentrate) is screw conveyor. Method for adjusting the recovery rate of the separated liquid of the decanted, concentrated screw decanter centrifuge comprising the sludge injected into the external taper bowl direction and then discharged to the dewatered cake (or concentrate) outlet through the dehydration cake (or concentrate) outlet To Arbitrary separation is achieved by installing a multi-stage adjusting slot dam plate corresponding to each separation liquid outlet outside the one or more separation liquid outlets and linearly moving in the direction of the center of the large diameter axis to variably control the opening area of the separation liquid outlet in multiple stages. A multistage control method for separating liquid recovery rate of a centrifuge using a multi-stage adjusting slot dam plate, characterized in that the separation liquid having a liquid recovery rate is discharged. The method according to claim 9, The multistage control slot plate has a size that can cover the area of the separation liquid discharge port and at the same time having an extra left and right areas; Slots each formed on both sides of the dam so as not to contact the separation liquid discharge port; A pitch circle diameter formed in plural to have different diameters imprinted or printed on the surface of the dam; A hole is formed in the large diameter shaft, and the fixing bolt penetrates the slot while the separation liquid recovery rate of the centrifuge using a multi-stage control slot dam plate, characterized in that configured to bolt fastening to the hole formed in the large diameter shaft. The method according to claim 9, The method of variably adjusting the opening area in multiple stages includes a pitch circle diameter formed with a plurality of different diameters imprinted or printed on the surface of the dam of the multi-stage adjusting slot plate on the dam height reference line imprinted or printed on the circular surface of the large diameter shaft. Multi-stage control method of the separation liquid recovery rate of the centrifuge using a multi-stage control slot dam plate, characterized in that for controlling the recovery of the separation liquid by linearly moving to adjust to a desired diameter.

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