KR102731626B1 - Centrifugal dehydrator with improved dehydration efficiency of solids - Google Patents

Abstract

The present invention relates to a centrifugal dehydrator with improved dewatering efficiency of solids, and more specifically, to a centrifugal dehydrator comprising: a cylindrical bowl rotator (10); a cone rotator (20) installed at one end of the bowl rotator (10) and provided with a sludge discharge port (21) for discharging sludge; a filtrate discharge portion (15) installed at the other end of the bowl rotator (10) and for discharging separated filtrate; a screw body (30) rotatably installed at the inner center of the bowl rotator (10); a screw blade (40) forming a flow path on the outer peripheral surface of the screw body (30) and installed to rotate integrally with the screw body (30); a fine aggregate recovery member (60) installed on one surface of the screw blade (40) facing the cone rotator (20) and guiding fine aggregates to move toward the inner peripheral surface of the bowl rotator (10); And a feed pipe (50) installed at the center of the cone rotator (20) and formed to supply the original liquid into the interior of the screw body (30); When the bowl rotator (10) and the screw body (30) rotate, the supernatant is discharged to the filtrate discharge section (15) through the flow path of the screw body (30), and the fine aggregates are moved toward the bowl rotator (10) by the fine aggregate recovery member (60) and additionally sedimented.
According to a centrifugal dehydrator according to one embodiment of the present invention, stable recovery of suspended solids is possible regardless of the instability of the concentration of incoming water in the dehydration treatment using a pharmaceutical liquor method, thereby reducing the cost of chemical treatment and/or minimizing the use of coagulants, and in the dehydration separation of wastewater, the purity of the separated filtrate can be secured through maximum recovery of suspended solids, and the dehydration efficiency of the separated and discharged solids can be maximized.

Description

Centrifugal dehydrator with improved dehydration efficiency of solids

The present invention relates to a centrifugal dehydrator that centrifuges sludge, livestock manure, various industrial wastewaters, etc. extracted from sewage/water into a filtrate and a solid substance, and more specifically, to a centrifugal dehydrator that can secure the cleanliness of a separated filtrate through maximum recovery of suspended solids and maximize the dewatering efficiency of the separated and discharged solid substances.

In general, manure and livestock wastewater generated from various animal farms and high-concentration organic wastewater generated from various industrial sites cause serious environmental pollution, so it is very important to treat them efficiently.

If these are disposed of by landfill, they contaminate the soil and groundwater and cause secondary environmental pollution by producing foul odors, so incineration is mainly used recently.

However, since these manures, livestock wastewater, organic wastewater, etc. contain sludge with a moisture content of over 90%, if they are incinerated as is without a drying process, not only will a lot of heat energy be required to evaporate the large amount of moisture contained therein, but combustion efficiency will also decrease, causing a large amount of pollutants to be generated. Therefore, in order to quickly and efficiently incinerate them, a process of separating various wastewaters into moisture and sludge through a separate dehydration process is essential.

For this purpose, various types of dehydration devices are used in the industry, and among them, centrifugal dehydration devices that separate solids and filtrate by using the difference in specific gravity are representative and widely used.

The basic principle of a centrifugal dehydrator is that when a raw liquid mixed with sludge and liquid is fed into a dehydrator, the centrifugal force caused by the rotation of the bowl rotor (10) increases the settling speed of solids with a high specific gravity, and they are deposited on the inner wall of the bowl rotor (10) at a high speed, and a screw blade (40) that rotates inside the bowl rotor (10) at a different rotation speed from the bowl rotor (10) transports the sludge deposited on the inner wall of the bowl rotor (10) forward and discharges the sludge through the discharge port, and the filtrate from which solids have been removed from the raw liquid is continuously separated and discharged through the discharge port at the rear.

Prior art related to centrifugal dewatering devices includes a centrifuge having a stirring rotor in Korean Patent Publication No. 10-1127015, a centrifuge for dewatering sewage or wastewater sludge in Korean Patent Publication No. 10-1599328, and many others.

However, conventional centrifugal dehydrators simply separate solids and liquids in the raw liquid, and the discharged residue is turbid, so it cannot be applied to industrial fields that require a residue with excellent cleanliness. In addition, since the discharged solids must be coagulated and then discharged to increase the discharge efficiency, a coagulant is injected into the raw liquid supply section to coagulate fine particles in the raw liquid inside the centrifugal dehydrator and then separated and discharged. However, the use of such coagulants has the problems of complicating the work process, causing economic losses due to the purchase of coagulants, and being inefficient in terms of maintenance.

Therefore, there is a need for a centrifugal dewatering device that can discharge ideal solids by recovering suspended solids while minimizing the use of coagulants.

The present invention has been created in consideration of the above problems, and aims to provide a centrifugal dehydrator capable of reducing the cost of chemical treatment and/or minimizing the use of coagulants by enabling stable recovery of floating substances regardless of the instability of the concentration of incoming substances in the dehydration treatment using the pharmaceutical method.

In addition, the present invention aims to provide a centrifugal dehydrator capable of securing the cleanliness of a separated filtrate through maximum recovery of suspended solids in the dehydration separation of wastewater and maximizing the dehydration efficiency of the separated and discharged solids.

In order to achieve the above-described object of the present invention, a centrifugal dehydrator according to one embodiment of the present invention comprises: a cylindrical bowl rotator (10); a cone rotator (20) installed at one end of the bowl rotator (10) and provided with a sludge discharge port (21) for discharging sludge; a filtrate discharge portion (15) installed at the other end of the bowl rotator (10) and for discharging separated filtrate; a screw body (30) rotatably installed at the inner center of the bowl rotator (10); a screw blade (40) forming a flow path on the outer peripheral surface of the screw body (30) and installed to rotate integrally with the screw body (30); a fine aggregate recovery member (60) installed on one surface of the screw blade (40) facing the cone rotator (20) and guiding fine aggregates to move toward the inner peripheral surface of the bowl rotator (10); And it includes a feed pipe (50) installed at the center of the cone rotator (20) and formed to supply the original liquid into the interior of the screw body (30); When the bowl rotator (10) and the screw body (30) rotate, the supernatant is discharged to the filtrate discharge unit (15) through the flow path of the screw body (30), and the fine aggregates can be moved toward the bowl rotator (10) by the fine aggregate recovery member (60) and additionally settled.

According to a centrifugal dehydrator according to one embodiment of the present invention, the outer surface of the fine aggregate recovery member (60) can be formed into a concave curved surface.

According to a centrifugal dehydrator according to one embodiment of the present invention, the screw body (30) may include a water level blocking plate (70) detachably installed at a portion corresponding to one end of the bowl rotor (10) coupled with the cone rotor (20).

According to a centrifugal dehydrator according to one embodiment of the present invention, the screw body (30) may include a sludge compression member (80) formed in a cone shape and installed at a portion facing the sludge discharge port (21) of the cone rotor (20).

According to a centrifugal dehydrator according to one embodiment of the present invention, the sludge compression member (80) may include a fixing member (81) formed in a hollow cylindrical shape and fixed to the screw body (30); and a conical member (82) installed at one end of the fixing member (81) and formed in a conical shape to guide sludge to the sludge discharge port (21).

According to a centrifugal dehydrator according to one embodiment of the present invention having the structure as described above, stable recovery of floating substances is possible regardless of the instability of the concentration of inlet materials in the dehydration treatment using the pharmaceutical method, and thus the cost of chemical treatment can be reduced and/or the use of coagulants can be minimized.

In addition, according to a centrifugal dehydrator according to one embodiment of the present invention, the cleanliness of the separated filtrate can be secured through maximum recovery of floating substances in the dehydration separation of wastewater, and the dehydration efficiency of the separated and discharged solids can be maximized.

Figure 1 is a cross-sectional view showing a centrifugal dehydrator according to one embodiment of the present invention.
FIG. 2 is a partially enlarged cross-sectional view showing a state in which a fine aggregate recovery member (60) is installed on the left end of a bowl rotor (10) of a centrifugal dehydrator according to one embodiment of the present invention.
FIG. 3 is a partially enlarged cross-sectional view showing a state in which a fine aggregate recovery member (60) is installed in the central portion of a bowl rotor (10) of a centrifugal dehydrator according to one embodiment of the present invention.
FIG. 4 is a partially enlarged cross-sectional view showing a state in which a water level blocking plate (70) is installed on the right end of a bowl rotor (10) of a centrifugal dehydrator according to one embodiment of the present invention.
Figure 5 is a perspective view showing the water level blocking plate (70) of Figure 4.
Figure 6 is a partially enlarged cross-sectional view showing a state in which a sludge compression member (80) is installed on the right end of a cone rotor (20) of a centrifugal dehydrator according to one embodiment of the present invention.
Fig. 7 is a perspective view showing the sludge compression member (80) of Fig. 6.

The embodiments described below are provided as examples to help understand the present invention, and it should be understood that the present invention can be implemented by modifying variously different from the embodiments described herein. However, in describing the present invention below, if it is determined that a specific description of a related known function or component may unnecessarily obscure the gist of the present invention, the detailed description and specific illustration thereof will be omitted. In addition, the attached drawings are not drawn to scale to help understand the present invention, and the dimensions of some components may be exaggerated.

Terms used in the embodiments of the present invention may be interpreted as having meanings commonly known to a person of ordinary skill in the art, unless otherwise defined.

In addition, the terms 'leading end', 'rear end', 'upper end', 'lower end', 'top end', 'bottom end', etc. used in the present invention are defined based on the drawings, and the shape and position of each component are not limited by these terms.

Hereinafter, a centrifugal dehydrator (1) with improved dehydration efficiency of solids according to one embodiment of the present invention will be described in detail with reference to the attached drawings.

Fig. 1 is a cross-sectional view showing a centrifugal dehydrator (1) according to one embodiment of the present invention. Fig. 2 is a partially enlarged cross-sectional view showing a state in which a fine aggregate recovery member (60) is installed on the left end of a bowl rotor (10) of a centrifugal dehydrator (1) according to one embodiment of the present invention. Fig. 3 is a partially enlarged cross-sectional view showing a state in which a fine aggregate recovery member (60) is installed on the central portion of a bowl rotor (10) of a centrifugal dehydrator (1) according to one embodiment of the present invention.

Referring to FIG. 1, a centrifugal dehydrator (1) according to one embodiment of the present invention may include a bowl rotor (10), a cone rotor (20), a screw body (30), a screw blade (40), and a feed pipe (50).

The Paul rotor (10) is formed in a cylindrical shape. That is, the Paul rotor (10) can be formed in a hollow cylindrical shape. The Paul rotor (10) is installed so as to be rotatable.

The cone rotor (20) is installed at one end of the pole rotor (10). The cone rotor (20) can be formed in a hollow cone shape. The cone rotor (20) is fixed to the right end of the pole rotor (10) and is installed so as to rotate integrally with the pole rotor (10).

The cone rotator (20) is installed to rotate by the main motor (3). That is, the right end of the cone rotator (20) is connected to the main motor (3) by a belt and can rotate. When the cone rotator (20) rotates, the ball rotator (10) can rotate integrally with the cone rotator (20).

The cone rotator (20) may include a sludge discharge port (21) through which sludge is discharged. The sludge discharge port (21) may be provided at one end of the cone rotator (20). In the present embodiment, the sludge discharge port (21) is provided adjacent to the right end of the cone rotator (20).

Sludge separated from the original liquid can be discharged through the sludge discharge port (21) by centrifugal force generated by the rotation of the bowl rotor (10) and the cone rotor (20).

A filtrate discharge unit (15) may be installed at the other end of the ball rotor (10). The filtrate discharge unit (15) is formed so that the separated filtrate can be discharged. Specifically, the filtrate discharge unit (15) is installed at the left end of the ball rotor (10) and may be formed so as to block the left end of the ball rotor (10). The filtrate discharge unit (15) may include a filtrate discharge port (151) formed adjacent to the screw body (30). The filtrate separated from the original liquid by centrifugal force generated by the rotation of the ball rotor (10) and the cone rotor (20) may be discharged through the filtrate discharge port (151).

The screw body (30) can be rotatably installed at the inner center of the bowl rotator (10). Specifically, the screw body (30) can be rotatably installed inside the bowl rotator (10) and the cone rotator (20).

The screw body (30) may include a cylindrical portion (31) formed in a hollow cylindrical shape and a cone portion (32) formed in a truncated cone shape.

The cone (32) is fixed to one end of the cylindrical portion (31) to form the screw body (30). Therefore, the cone (32) and the cylindrical portion (31) can be formed integrally. The cone (32) can include a hollow portion formed in the longitudinal direction.

The cylindrical portion (31) is installed so as to be able to rotate inside the ball rotor (10), and the cone portion (32) is installed so as to be able to rotate inside the cone rotor (20).

A feed pipe (50) formed to supply the original liquid into the interior of the screw body (30) may be installed at the other end of the screw body (30). That is, the feed pipe (50) may be installed inside the screw body (30) through the right end of the cone rotor (20). The feed pipe (50) penetrates the hollow portion of the cone portion (32) of the screw body (30), and one end of the feed pipe (50) may be located inside one end of the cylindrical portion (31).

An inlet hole (33) may be formed at the end of the cylindrical portion (31) adjacent to the cone portion (32) of the screw body (30). Through the inlet hole (33), the raw material supplied through the feed pipe (50) may be supplied to the sedimentation section (S1) between the screw body (30) and the bowl rotor (10).

A blocking plate (331) is installed inside the cylindrical portion (31) adjacent to the inlet hole (33) to prevent the original liquid from flowing along the internal space of the cylindrical portion (31).

The screw body (30) can be installed to rotate by the differential motor (4). For example, one end of the cylindrical portion (31) of the screw body (30) and the differential motor (4) are connected by a belt. Therefore, when the differential motor (4) operates, the screw body (30) can rotate.

A reducer (5) may be installed at one end of the screw body (30). The reducer (5) may be connected to the speed motor (4) by a belt. Therefore, when the speed motor (4) operates, the screw body (30) may rotate through the reducer (5).

The screw blade (40) may be installed on the outer surface of the screw body (30). The screw blade (40) may be formed in a spiral shape. The screw blade (40) may be formed to rotate integrally with the screw body (30). When the screw blade (40) rotates integrally with the screw body (30), the solid sludge deposited on the inner surface of the bowl rotor (10) is moved toward the sludge discharge port (21) provided in the cone rotor (20), and the separated filtrate is formed to be discharged through the filtrate discharge port (151) provided at the rear end of the bowl rotor (10).

In the embodiment shown in Fig. 1, when the screw blade (40) rotates, the solid sludge deposited on the inner surface of the bowl rotor (10) moves to the right side of the bowl rotor (10) by the screw blade (40), and the filtrate moves to the left side of the bowl rotor (10).

A water flow path (41) may be formed between the screw blade (40) and the screw body (30). The path (41) may be formed so that water may flow in the longitudinal direction of the screw body (30). The path (41) may be formed between the outer surface of the screw body (30) and the lower end of the screw blade (40).

A plurality of installation stands may be installed on the outer surface of the cylindrical portion (31) of the screw body (30). The plurality of installation stands are formed in a long rod shape corresponding to the length of the cylindrical portion (31) and may be installed at regular intervals in the circumferential direction along the outer surface of the screw body (30). For example, four installation stands may be installed parallel to each other at 90-degree intervals on the outer surface of the screw body (30).

A screw blade (40) may be installed on the upper surface of a plurality of installation stands. When the screw blade (40) is fixed on a plurality of installation stands, a gap corresponding to the thickness of each of the plurality of installation stands may be formed between the lower end of the screw blade (40) and the outer surface of the screw body (30). Water may flow through this gap. That is, a water flow path (41) is formed between the screw body (30) and the screw blade (40) by the plurality of installation stands.

A fine aggregate recovery member (60) can be installed on the screw blade (40) to additionally sediment fine aggregates.

The fine aggregate recovery member (60) can be installed on the screw blade (40). The fine aggregate recovery member (60) can be installed on one side of the screw blade (40). The fine aggregate recovery member (60) is installed on one side of the screw blade (40) facing the cone rotor (20).

The fine aggregate recovery member (60) may be installed in a portion of the screw blade (40) corresponding to the cylindrical portion (31) of the screw body (30). That is, the fine aggregate recovery member (60) may be installed in a portion of the screw blade (40) corresponding to the sedimentation section (S1) of the centrifugal dehydrator (1). The fine aggregate recovery member (60) is not installed in a portion of the screw blade (40) corresponding to the cone portion (32). That is, the fine aggregate recovery member (60) may not be installed in a portion of the screw blade (40) corresponding to the dehydration section (S2) of the centrifugal dehydrator (1).

The fine aggregate recovery member (60) can be installed along the screw blade (40). The fine aggregate recovery member (60) can be installed approximately perpendicular to one surface of the screw blade (40). The fine aggregate recovery member (60) can be formed in a spiral shape along one surface of the screw blade (40).

The fine aggregate recovery member (60) may be installed along the lower end of the screw blade (40), that is, along the end adjacent to the screw body (30). Accordingly, a flow path (60) may be formed between the fine aggregate recovery member (60) and the outer surface of the screw body (30). The fine aggregate recovery member (60) may be installed on the screw blade (40) so that only the supernatant containing no fine aggregates passes through the upper side of the fine aggregate recovery member (60), that is, the flow path (41), and the inferior water containing fine aggregates does not enter the flow path (41) but moves toward the inner surface of the bowl rotor (10).

The fine aggregate recovery member (60) can be installed away from the inner surface of the bowl rotor (10). Therefore, the fine aggregate recovery member (60) may not affect the solid sludge deposited on the inner surface of the bowl rotor (10).

The fine aggregate recovery member (60) can be formed into a shape capable of guiding the fine aggregate to move toward the inner surface of the bowl rotation body (10).

The outer surface (60a) of the fine aggregate recovery member (60) may be formed as a concave curved surface. For example, as shown in FIGS. 2 and 3, the cross-section of the fine aggregate recovery member (60) may be formed as a concave curved surface at the outer surface (60a). For example, the outer surface (60a) of the fine aggregate recovery member (60) may be formed as an arc shape. Here, the outer surface (60a) of the fine aggregate recovery member (60) refers to the surface facing the bowl rotation body (10).

When the outer surface (60a) of the fine aggregate recovery member (60) is formed into a concave curve, the fine aggregates floating on the upper side of the lower water level based on Fig. 2 move toward the inner surface of the bowl rotation body (10) along the curve of the fine aggregate recovery member (60). In other words, the fine aggregates are guided by the fine aggregate recovery member (60) and further sedimented.

A sub-fine aggregate recovery member (61) may be installed on the inner surface of the filtrate discharge portion. The sub-fine aggregate recovery member (61) may be installed around the filtrate discharge port (151). The sub-fine aggregate recovery member (61) may be formed in a ring shape. The sub-fine aggregate recovery member (61) may rotate integrally with the bowl rotation body (10).

The outer surface (61a) of the sub-fine aggregate recovery member (61) can be formed into a curved surface in the same manner as the outer surface (60a) of the fine aggregate recovery member (60). Accordingly, the sub-fine aggregate recovery member (61) can cause the fine aggregates remaining in the supernatant that have passed through the fine aggregate recovery member (60) rotating together with the screw blade (40) to settle again toward the inner surface of the bowl rotation body (10).

The space between the inner surface of the ball rotor (10) and the outer surface of the cylindrical portion (31) of the screw body (30) forms a sedimentation section (S1). The space between the inner surface of the cone rotor and the outer surface of the cone portion of the screw body forms a dehydration section (S2).

When the Paul rotor (10) rotates, the original liquid can be separated into three layers of solid sludge, low-level water, and high-level water by centrifugal force in the sedimentation section (S1).

By centrifugal force, solid sludge is deposited on the inner surface of the bowl rotor (10), and the lower water is located above the solid sludge, and the upper water is located above the lower water.

The supernatant can be discharged to the outside through the residual liquid discharge portion (15) via the path (41) formed between the screw body (30) and the screw blade (40).

When the screw blade (40) rotates, the solid sludge deposited on the outer surface of the screw body (30) moves to the dewatering section (S2) and is discharged through the sludge discharge port (21).

In the case of a centrifugal dehydrator (1), a coagulant is injected into the interior of the centrifugal dehydrator (1) so that the solids contained in the raw liquid are sufficiently coagulated to form a floc in the shape of a tofu and then settle. If a coagulant is injected into the raw liquid in this way, there is a problem that the dehydration cost increases. In addition, if a large amount of coagulant is used, a large amount of coagulant remains in the supernatant discharged from the centrifugal dehydrator (1), so there is a problem that additional purification work is required for the supernatant.

When the amount of coagulant injected is reduced, the flocculation of the flocs is weak and scum-shaped floating substances exist on the upper side of the bottom water, which causes a problem in that it is difficult to stably recover solid sludge only by centrifugal force and the rotation of the screw blade (40). That is, when the amount of coagulant injected in a conventional centrifugal dehydrator (1), the amount of solid substances that settle to the inner surface of the bowl rotor (10) decreases and the fine flocs that float on the upper side of the bottom water increase. Here, the fine flocs refer to substances that do not settle to the inner surface of the bowl rotor (10) but float on the upper side of the bottom water, such as weakly coagulated flocs and scum.

However, when a fine aggregate recovery member (60) is installed on a screw blade (40) as in the present invention, as shown in FIGS. 2 and 3, the fine aggregate moves along the outer surface (60a) of the fine aggregate recovery member (60) to the inner surface of the bowl rotor (10), so that the fine aggregate additionally settles.

In addition, since the centrifugal dehydrator (1) according to the present invention has a sub-fine aggregate recovery member (61) installed on the inner side of the filtrate discharge port (151) of the filtrate discharge section (15), the fine aggregates can move to the inner surface of the bowl rotor (10) and be deposited.

Accordingly, the centrifugal dehydrator (1) according to the present invention can block or minimize fine aggregates from being discharged to the filtrate discharge port (151), thereby improving the cleanliness of the filtrate discharged to the filtrate discharge port (151).

Therefore, the centrifugal dehydrator (1) according to the present invention can efficiently separate solid sludge and improve the cleanliness of the filtrate even if the amount of coagulant injected is reduced compared to the amount of coagulant injected used in the centrifugal dehydrator (1) according to the prior art.

Meanwhile, the centrifugal dehydrator (1) according to one embodiment of the present invention may include a water level blocking plate (70) to prevent low-grade water from being discharged to the sludge discharge port (21). The water level blocking plate (70) may be detachably installed on a portion of the screw body (30) corresponding to one end of the bowl rotor (10) coupled with the cone rotor (20).

Fig. 4 is a partially enlarged cross-sectional view showing a state in which a water level blocking plate (70) is installed on the right end of a bowl rotor (10) of a centrifugal dehydrator (1) according to one embodiment of the present invention. Fig. 5 is a perspective view showing the water level blocking plate (70) of Fig. 4.

Referring to FIG. 4, the water level blocking plate (70) may be installed at one end of the cone portion (32) of the screw body (30), that is, at the left end of the cone portion (32) connected to the cylindrical portion (31). The water level blocking plate (70) may be installed vertically with respect to the cylindrical portion (31). The cone portion (32) may include a blocking plate installation portion (34) on which the water level blocking plate (70) is installed. The blocking plate installation portion (34) may be formed vertically with respect to the rotational axis of the screw body (30).

The water level blocking plate (70) can be detachably installed in the blocking plate installation part (34). For example, the water level blocking plate (70) can be installed in the blocking plate installation part (34) of the cone part (32) with a plurality of bolts. To this end, the blocking plate installation part (34) can include a plurality of fixing holes (341) having female screws formed on the inner surface.

The water level blocking plate (70) can be formed in a circular shape. An insertion hole (71) having a diameter corresponding to the outer diameter of the cylindrical portion (31) is formed at the center of the water level blocking plate (70). The outer diameter of the water level blocking plate (70) can be formed smaller than the diameter of the screw blade (40). The space between the outer surface of the water level blocking plate (70) and the inner surface of the bowl rotor (10) can form a passage through which solid sludge (D) is discharged.

The outer diameter of the water level blocking plate (70) can be determined to various sizes. In the case of a raw liquid with a large amount of solid sludge, a water level blocking plate (70) with a small outer diameter can be used. In addition, in the case of a raw liquid with a small amount of solid sludge, a water level blocking plate (70) with a large outer diameter can be used. In this way, by using a water level blocking plate (70) with an appropriate outer diameter according to the amount of solid sludge, it is possible to prevent or minimize low-grade water from being discharged together with solid sludge to the sludge discharge port (21).

The water level blocking plate (70) includes a plurality of through holes (72) corresponding to a plurality of fixing holes (341) of the blocking plate installation portion (34). Accordingly, the water level blocking plate (70) can be fixed to the blocking plate installation portion (34) of the cone section (32) using a plurality of bolts.

In addition, as shown in Fig. 4, the water level barrier plate (70) can be formed in half for convenience of installation.

A centrifugal dehydrator (1) according to one embodiment of the present invention may include a sludge compression member (80) formed to be capable of compressing sludge discharged through a sludge discharge port (21). The sludge compression member (80) is installed in a portion of the screw body (30) facing the sludge discharge port (21) of the cone rotor (20), and may be formed in a cone shape. The sludge compression member (80) may be detachably installed in the screw body (30).

Fig. 6 is a partially enlarged cross-sectional view showing a state in which a sludge compression member (80) is installed on the right end of a cone rotor (20) of a centrifugal dehydrator (1) according to one embodiment of the present invention. Fig. 7 is a perspective view showing the sludge compression member (80) of Fig. 6.

Referring to FIG. 6, the sludge compression member (80) can be installed in the cone portion (32) of the screw body (30). The sludge compression member (80) can be installed in the portion of the cone portion (32) of the screw body (30) facing the sludge discharge port (21) of the cone rotor (20).

The sludge compression member (80) may be formed in a cone shape. For example, the sludge compression member (80) may include a fixing member (81) fixed to the screw body (30) and a conical member (82) formed in a cone shape.

The fixed part (81) is formed in a hollow cylindrical shape, and a plurality of through holes (85) are formed on the outer surface. The plurality of through holes (85) can be formed at regular intervals in the circumferential direction of the fixed part (81). The sludge compression member (80) can be fixed to the screw body (30) using the plurality of through holes (85).

The cone part (82) is provided at one end of the fixed part (81) and can be formed in a cone shape to guide the sludge to the sludge discharge port (21). The cone part (82) faces the sludge discharge port (21) and can adjust the area of the sludge discharge port (21) that is opened. The solid sludge (D) that has moved along the inner surface of the cone rotator (20) can be moved to the sludge discharge port (21) by the cone part (82).

When the cone (82) narrows the open area of the sludge discharge port (21), the solid sludge (D) is compressed and the moisture contained in the solid sludge (D) is recovered, thereby forming an ideal sludge cake.

The portion of the cone (32) facing the sludge discharge port (21) of the cone rotator (20) may be formed in a cylindrical shape. The cone (32) may include a compression member installation portion (35) in which a sludge compression member (80) is installed.

The compression member installation part (35) may include a plurality of fixing hole groups (351, 352, 353) having female screws formed on the inner surface. The plurality of fixing hole groups (351, 352, 353) may be formed at regular intervals along the length direction of the compression member installation part (35). That is, the plurality of fixing hole groups (351, 352, 353) may be formed at a plurality of positions along the length of the compression member installation part (35).

Referring to Fig. 6, the compression member installation part (35) may include three fixing hole groups (351, 352, 353). Each of the fixing hole groups (351, 352, 353) may include a plurality of fixing holes formed at regular intervals in the circumferential direction of the compression member installation part (35).

A plurality of fixing holes can be formed at regular intervals in the circumferential direction of the outer surface of the compression member installation portion (35). The plurality of fixing holes are formed to correspond to the plurality of through holes (85) of the sludge compression member (80). Accordingly, the sludge compression member (80) can be fixed to the cone portion (32) of the screw body (30) using a plurality of bolts.

The first fixed hole group (351) may be formed closest to the sludge discharge port (21) of the cone rotator (20), and the third fixed hole group (353) may be formed furthest from the sludge discharge port (21). The second fixed hole group (352) may be positioned between the first fixed hole group (351) and the third fixed hole group (352).

When the sludge compression member (80) is fixed to the first fixed hole group (351), the sludge discharge port (21) can be opened to a minimum. When the sludge compression member (80) is fixed to the third fixed hole group (353), the sludge discharge port (21) can be opened to a maximum. When the sludge compression member (80) is fixed to the second fixed hole group (352), the sludge discharge port (21) can be opened to a medium degree.

When a sludge compression member (80) is installed in the screw body (30) as in the present invention, the sludge compression member (80) can control the open area of the sludge discharge port (21) according to the amount of solid sludge (D) separated from the raw liquid. Therefore, according to the centrifugal dehydrator (1) according to the present invention, the sludge discharged from the sludge discharge port (21) is sufficiently compressed, so that an ideal sludge cake with minimized moisture content can be obtained.

According to a centrifugal dehydrator according to one embodiment of the present invention having the structure as described above, stable recovery of floating substances is possible regardless of the instability of the concentration of inlet materials in the dehydration treatment using the pharmaceutical method, and thus the cost of chemical treatment can be reduced and/or the use of coagulants can be minimized.

In addition, according to a centrifugal dehydrator according to one embodiment of the present invention, the cleanliness of the separated filtrate can be secured through maximum recovery of floating substances in the dehydration separation of wastewater, and the dehydration efficiency of the separated and discharged solids can be maximized.

While the present disclosure has been illustrated and described above with reference to various embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the present disclosure as defined by the appended claims and their equivalents.

1; Centrifugal dehydrator 3; Main motor
4; Speed motor 5; Reducer
10; Paul Rotor 15; Liquid Discharge Port
20; Cone rotator 21; Sludge discharge port
30; Screw body 31; Cylindrical part
32; Conbu 34; Block installation part
35; Compression member installation part 40; Screw wing
50; Feed pipe 60; Fine aggregate recovery member
61; Sub-fine aggregate recovery member 70; Water level cut-off plate
80; Sludge pressing member 81; Fixing member

Claims (5)

Cylindrical ball rotor (10);
A cone rotor (20) installed at one end of the above-mentioned ball rotor (10) and provided with a sludge discharge port (21) through which sludge is discharged;
A residual liquid discharge unit (15) installed at the other end of the above-mentioned ball rotor (10) and through which the separated residual liquid is discharged;
A screw body (30) rotatably installed at the inner center of the above-mentioned ball rotor (10);
A screw blade (40) that forms a path on the outer surface of the screw body (30) and is installed to rotate integrally with the screw body (30);
A fine aggregate recovery member (60) that is installed in a spiral shape along the screw blade (40) closer to the screw body (30) than the tip of the screw blade (40) on one side of the screw blade (40) facing the cone rotor (20) and guides the fine aggregate to move toward the inner surface of the bowl rotor (10);
A sub-fine aggregate recovery member (61) having a ring shape, installed on the inner surface of the liquid discharge part (15), and rotating integrally with the bowl rotation body (10); and
It includes a feed pipe (50) installed at the center of the cone rotator (20) and formed to supply the raw material into the interior of the screw body (30);
One side of the above fine aggregate recovery member (60) formed in a spiral shape and facing the above-mentioned ball rotation body (10) is formed as a concave curved surface,
One side of the sub-fine aggregate recovery member (61) facing the above-mentioned Paul rotating body (10) is formed with the same curve as the above-mentioned fine aggregate recovery member (60).
A centrifugal dehydrator characterized in that when the above-mentioned bowl rotator (10) and the above-mentioned screw body (30) rotate, the supernatant is discharged through the flow path of the above-mentioned screw body (30) to the above-mentioned filtrate discharge portion (15), and the fine aggregates move toward the above-mentioned bowl rotator (10) by the above-mentioned fine aggregate recovery member (60) and are additionally sedimented.
delete In paragraph 1,
A centrifugal dehydrator characterized in that the screw body (30) includes a water level blocking plate (70) that is detachably installed at a portion corresponding to one end of the bowl rotor (10) coupled with the cone rotor (20).
In paragraph 1,
A centrifugal dehydrator characterized in that the screw body (30) is installed at a portion facing the sludge discharge port (21) of the cone rotor (20) and includes a sludge compression member (80) formed in a cone shape.
In paragraph 4,
The above sludge compression member (80) is
A fixing part (81) formed in a hollow cylindrical shape and fixed to the screw body (30); and
A centrifugal dehydrator characterized by including a conical portion (82) installed at one end of the fixed portion (81) and formed in a conical shape to guide sludge to the sludge discharge port (21).

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