KR200391893Y1 - Sludge dehydration epuipment of screw type - Google Patents

Abstract

The present invention relates to a screw type sludge dewatering device, which is easy to replace the damaged plate when the fixed plate and the fluidized plate installed in the dewatering device is damaged, and by reducing the cost required for the production of the fixed plate and the fluidized plate as much as possible It is intended to bring down the cost.

In this configuration, the stationary plate 10 and the flow plate 12 are assembled innumerably into the respective shafts 20 and 22 in the casing 3, and the space 14 in the fixed plate 10 and the flow plate 12 is assembled. In the dewatering device in which the screw 30 is fitted, and the sludge supplied from one inlet port 60 of the casing 3 moves in one direction by the rotational force of the screw 30 to be dehydrated.

The fixed plate 10 and the fluidized plate 12 are divided into two pieces, each of which is formed on the fixed plate shaft 20 and the fluidized plate shaft 22 to form a circular space portion 14 for screw installation therein. Inserted and coupled, the eccentric shaft 40 for the up and down linear movement of the flow plate 12 fitted to the flow plate shaft 22 is connected to each other adjacent to the flow plate shaft 22 is installed separately As the fixed plate 10 and the fluidized plate 12 are divided into pieces, the plate 10 and 20 can be provided without a waste part at the time of cutting from the raw material. Since the plate 12 is divided and fitted to be combined, only the shafts 20 and 22 of the damaged plate need to be dismantled when the plate 10 or 20 is damaged during use, and replacement of the plate 12 is extremely easy.

Description

Sludge Dewatering Device of Screw Type {SLUDGE DEHYDRATION EPUIPMENT OF SCREW TYPE}

The present invention relates to a screw type sludge dewatering device, and more particularly, it is easy to replace the damaged plate when the fixed plate and the fluidized plate installed in the dehydrating device are damaged, and the cost required for the production of the fixed plate and the fluidized plate The main focus is on saving as much as possible.

In general, waste sludge generated in various wastewater treatment plants is dewatered to be solid by a dewatering device for environmental protection. The dewatering device is a filter press type or a belt press type dewatering device, and these sludges are covered by a filter cloth. While dehydration was performed by pressing roller while dehydration was performed, the filter / belt press-type dehydration device as described above caused clogging of the filter cloth, which lowered the dewatering efficiency and also required installation of various auxiliary equipment according to dehydration. As the bar apparatus is enlarged, manufacturing costs are increased, and the installation area has to be large.

On the other hand, in recent years, a screw type dewatering device for dewatering the sludge using the rotational force of the screw in consideration of the manufacturing cost and the installation area as described above has been proposed in Korea Patent Publication No. 97-0121732, which is a number of fixed plates Is placed in the gap, and the flow plate can be moved therebetween, and the screw is rotatably installed in the inner space of the fixed plate and the flow plate, and the sludge is inserted into the space and the screw is rotated. Water is removed as the sludge is compressed and moved, and the water is discharged to the outside through the microgap (gap) between the fluidized plate and the fixed plate, and the microgap is blocked by the sludge (solid content) by the movement of the fluidized plate. It is configured to facilitate the discharge of water without work.

Therefore, according to the screw-type dewatering device, it is possible to reduce the manufacturing cost by miniaturization and to have a small installation area.

7 to 8 show a screw type dewatering apparatus proposed by Korean Patent No. 372501 according to another prior art. According to this screw type dewatering apparatus, the automatic cleaning is improved, and the life of the fluidized plate and its driving means is improved. And a casing (100) having a supply part (110) and a discharge part (120) formed at both sides thereof, for the purpose of simplifying repair thereof when the fluidized plate driving means is worn out, and the casing (100). Separation means composed of a plurality of flow plates 104 are arranged so as to swing between the fixed plate 102 and the micro-gap (S) between the plurality of fixed plates 102 fixed in the axial direction at a predetermined interval to each other ( 101, a screw 130 inserted into the space portion 105 formed in the separating means 101 and the screw 130 and driving means for driving the fluid plate 104 in cooperation with the flow plate; The drive means supports at least two on the flow plate 104. A hole 104a is formed to be inserted into each of the connecting pipes 106 and the connecting pipes 106 so that the flow plates 104 are connected to each other. It is formed by the rotating shaft 108 provided with the cam 107 in contact with it, and is configured to evenly swing the fluid plate 104. Also, when the screw 130 is rotated, the sludge is rotated in one side by the screw 130 (the discharge part side). Moisture is removed as it is moved and compressed, and the water is discharged to the outside through the micro gap S between the flow plate 104 and the fixed plate 102, and the micro gap S is operated by the cam 107. The water was discharged without being blocked by the moving plate 104, which is also miniaturized, resulting in a reduction in manufacturing cost and minimizing the installation area compared to the filter / belt press type dehydrator.

On the other hand, the conventional screw-type dewatering device, compared to the filter / belt press type dewatering device is possible to reduce the manufacturing cost and installation in a narrow area, for example, a fixed plate 102 or a fluid plate 104 is a myriad of assembled ) If any damage occurs to the plate, the shafts assembled to the casing 100 in the axial direction must be removed, and the screw 130 must be dismantled and removed at the same time, and then the damaged plate must be repaired and replaced. It takes a lot of time in this case there was a problem that the treatment capacity of the sludge is reduced.

In addition, the spacer 109 is fitted to the inner surface of the fixed plate 102 to form a micro gap S between the fixed plate 102 and the flow plate 104, and its structure is complicated. 102) and the circular plate 105, in which the screw 130 is installed, takes a large area in cutting and manufacturing the fluidized plate 104. This part had to be disposed of, and a dehydration device was used due to high consumption of raw materials. The cost of the production has been a factor.

The present invention has been made to solve the above-mentioned conventional problems, and it is extremely easy to repair and replace the damaged plate when the fixing plate and the fluid plate are damaged, and also the moisture is transferred to the outside by assembling the plate and the fluid plate without the need for spacers. The purpose of the present invention is to provide a sludge dewatering device of a screw type that allows a clearance to be discharged, that is, clearance, and minimizes the consumption of raw materials when cutting the fixed plates and fluidized plates installed innumerably. It is done.

In order to achieve the above object, the present invention is cut to be divided into approximately 1/4 size when the fixed plate and the fluidized plate circumferentially, but when the combination of the two fixed plate, two fluidized plate combined may be installed inside the screw By forming the circular space part, it can be provided with a large amount of fixed plate and fluid plate, and minimizes the waste part, and it can replace the damaged plate by dismantling only the shaft on which the damaged plate is inserted when the fixed plate or the fluid plate is damaged during use. In order to facilitate the operation, the thickness of the fixed plate in the fixed plate and the fluidized plate each divided configuration is configured to be thicker than the fluidized plate is characterized in that the thickness variation of the fixed plate and the fluidized plate is configured to be a play that the water is discharged.

Figure 1 is an assembled cross-sectional view of an embodiment of the present invention, Figure 2 is a side view showing the assembled state of the stationary plate and the fluid plate of the present invention and the installation state of the fluid plate shaft and the eccentric shaft, Figure 3 is a state that is combined in a pair of the present invention Figure 4 is an explanatory view of the fixed plate and the fluid plate shown, Figure 4 is a perspective view for explaining a state in which the fixed plate and the fluid plate of the present invention is assembled to the shaft, Figure 5 is a front view of the fixed plate and the fluid plate of the present invention is fitted to the shaft coupled. .

Screw type sludge dewatering device (1) of the present invention is composed of a casing (3) divided into a plurality of integrally assembled in the longitudinal direction, in the casing (3) two pieces of fixed plate (10), flow plate ( 12) The two are fitted together to form a pair (see Fig. 3) to form a circular shape by being fitted to the fixed plate shaft 10 and the fluid plate shaft 12, the screw inside the assembly of the fixed plate 10 and the fluid plate 12 (30) A space portion 14 for installation is formed.

The fixing plate 10 and the fluidizing plate 12 are configured with different thicknesses, respectively.

That is, as shown in Figure 5, the fixed plate 10 is configured to be thicker than the thickness of the flow plate 12, for example, preferably the fixed plate 10 is 1.2t, the flow plate 12 is 0.8t Assuming that the stationary plate 10 is assembled on both sides of the flow plate 12, a clearance 15 of 0.2t is generated.

In addition, each of the divided fixing plate 10 is fitted into the two fixing plate shaft 20 by the shaft hole (10a) is drilled in two places at both ends of the two fixing plate 10 is fitted to the four fixing shaft 20 Each of the divided flow plates 12 is coupled to each of the four flow plate shaft 22 through one shaft hole 12a is drilled through the outer portion of the center.

On the other hand, when the fixed plate 10 and the fluid plate 12 is coupled to each of the shafts 20 and 22, as shown in FIG. That is, as a whole structure, the fluidized plate 12 is sandwiched between two fixed plates 10 (see FIG. 5), and as a result of the assembly, the thicknesses t between the fixed plate 10 and the fluidized plate 12 are different from each other. As much as the gap of the thickness (15) is generated, the water is discharged to the outside through the gap (15).

As described above, the fixed plate shaft 20 into which the fixed plate 10 is fitted is fixedly coupled to the casing 3 at both ends thereof, and the fluid plate shaft 22 to which the fluid plate 12 is fitted is supported at the casing 3 at both ends thereof. The fluid plate shaft 22 is coupled to the casing 3 freely to move so as to be able to linearly move up and down at a predetermined distance corresponding to the rotational operation of the eccentric shaft 40 which will be described later.

Reference numeral 40 is an eccentric shaft, the eccentric shaft 40 is provided with a gear 42 for power transmission in the front side, both ends are coupled to the casing 3 freely rotated by the bearing (44).

Four eccentric shafts are respectively provided in the outer proximal portions of the four flow shafts 22 (see Fig. 2), and the eccentric shaft 40 is formed with an eccentric rod 40a serving as a cam having a different axial center from the central shaft. The eccentric transfer member 46 is installed between the eccentric rod 40a and the flow shaft 22 so that the flow shaft 22 adjacent to the eccentric shaft 40 can be linearly moved up and down. .

In the drawings, reference numeral 50 denotes a motor for driving the dehydrating apparatus 1, and 52 denotes a gear installed for power transmission to the screw 30.

Referring to the operation of the present invention configured as described in the actual use state as follows.

In order to dewater the sludge by the dewatering device 1 of the present invention, first, when the motor 50 is operated, the screw 30 rotates, and at the same time, the gear 52 installed on the screw shaft is engaged, so that the eccentric shaft 40 ) Rotates together, and at this time, the eccentric force of the eccentric rod 40a installed on the eccentric shaft 40 is transmitted to the fluid plate shaft 22 by the eccentric transfer member 46, so that the fluid plate shaft 22 is moved within a certain distance. The linear motion is continuously performed repeatedly.

In such a state, when the diluted waste sludge is introduced through the input part 60, the sludge moves to the discharge part side 70 installed on the opposite side as the screw 30 rotates, thereby applying pressure to the sludge, thereby dehydrating the sludge. At this time, the water is drained to the outside through the gap 15 of each of the fixed plate 10 and the fluidized plate 12, the sludge is completed dehydration is to fall through the discharge portion 70 by the cake of the solid content.

On the other hand, when dehydration is performed as described above, the flow plate shaft 22 converts the rotational movement of the eccentric shaft 40 installed in a straight line to move up and down to move the flow plate 12 installed on the flow plate shaft 22 is the shaft By moving up and down with (22) to prevent the blockage between the clearances (15) is to be better discharge of water.

That is, the fluid plate 12 is a device for dewatering the sludge is connected with the fixed plate 10, and serves to perform a self-cleaning function to prevent clogging, while moving up and down while serving as a body.

In addition, according to the present invention, since the fixed plate 10 and the fluidized plate 12 made of stainless steel are not formed in a circular ring shape as in the prior art, but are formed as four pieces, they are formed by cutting from a plate-shaped raw material. In this case, the flow plate 12 can be cut innumerably as shown in FIG. 6A, and the fixed plate 10 can also be cut as shown in FIG. 6B, thereby minimizing the consumption of raw materials, and at the same time, a large number of fixed plates 10. ) And the liquid plate 12 can be obtained, which can lead to a significant reduction in the manufacturing cost, considering that the fixed plate 10 and the liquid plate 12 have a significant effect on the manufacturing cost when manufacturing the screw type sludge dewatering device. will be.

In addition, in the dewatering of the sludge by the device of the present invention as described above, if the damage occurs in the fixed plate 10 or the fluidized plate 12 and repair and replace it, only the shaft corresponding to the damaged plate is dismantled and then the damaged plate is removed. By removing and inserting a new plate in place and assembling the shaft, it is extremely easy to replace and repair as compared to having to remove the damaged shaft and remove the screw at the same time.

As described above, the present invention is manufactured by splitting and cutting the fixed plate and the fluidized plate, so that the fixed plate and the fluidized plate can be provided with a larger amount of the fixed plate and the fluidized plate from a smaller amount of raw materials than the conventional consumption of raw materials used for manufacturing the fixed plate and the fluidized plate. This breakthrough can lead to drastic savings, and in case of damage to the fixed plate or fluid plate during use, only the shaft of the damaged plate needs to be dismantled and repaired.

Figure 1 is a front sectional view of the assembled state of the embodiment of the present invention.

Figure 2 is a side view showing the assembled state of the stationary plate and the fluid plate of the present invention and the installation state of the fluid plate shaft and the eccentric shaft.

Figure 3 is an explanatory view of the assembly of the fixed plate and the fluid plate showing a state combined in a pair of the subject innovation.

Figure 4 is a perspective view for explaining a state in which the fixed plate and the fluid plate of the present invention is assembled to the shaft.

Figure 5 is a front view of a state in which the fixed plate and the fluid plate of the present invention is fitted into the shaft.

6a and 6b is a cutting state of the fixed plate and the fluid plate of the present invention.

Figure 7 is a cross-sectional view of the conventional screw type sludge dewatering device.

Figure 8 is a cross-sectional view of the coupling plate and the fixed plate installed in the conventional screw type sludge dewatering device.

※ Explanation of codes for main parts of drawing

1: dehydrator 3: casing

10: fixed plate 12: flow plate

14: space portion (screw installation portion) 15: play

20: fixed plate shaft 22: fluid plate shaft

30: screw 40: eccentric shaft

40a: eccentric rod 46: eccentric transmission member

50: motor 60: input part

70: discharge part

Claims (4)

In the casing 3, the fixed plate 10 and the flow plate 12 are assembled innumerably on each shaft 20, 22, and screwed to the space 14 in the fixed plate 10 and the flow plate 12. In the screw type dewatering device 30 is fitted, so that the sludge supplied from one side of the input unit 60 of the casing (3) is dewatered while compression movement in one direction by the rotational force of the screw (30), The fixed plate 10 and the fluidized plate 12 are divided into two pieces, each of which is formed on the fixed plate shaft 20 and the fluidized plate shaft 22 to form a circular space portion 14 for screw installation therein. Screw type, characterized in that the eccentric shaft (40) for connecting the up and down linear movement of the flow plate 12 fitted to the flow plate shaft 22 is separately connected to the adjacent portion of the flow plate shaft (22) Sludge dewatering device. The method of claim 1, Screw-type sludge dewatering, characterized in that the fixed plate 10 and the fluidized plate 12 fitted to the fixed plate shaft 20 and the fluidized plate shaft 22 are alternately assembled to change positions in different directions by 90 °. Device. The method of claim 1, Screw plate sludge dewatering device, characterized in that the thickness of the fixed plate 10 and the fluidized plate 12 is configured so that the play (15) for the discharge of water due to the thickness deviation during assembly. The method of claim 1, The eccentric shaft 40 has a cam-shaped eccentric rod 40a different from the axial center, so that the eccentric force due to the rotation of the eccentric rod 40a is transmitted to the flow plate shaft 22 by the eccentric transfer member 46. Screw-type sludge dewatering device, characterized in that the fluid plate (12) fitted to the plate shaft (22) to allow the vertical movement.