KR102584311B1 - Quantitative discharge system for sludge handling hopper units - Google Patents

Abstract

The present invention relates to a fixed-quantity discharge system of a hopper device for sludge treatment, which has an improved structure so that the sludge stored in the hopper body is horizontally transported in a 360° direction through the side discharge port by a centrifugal feeder rotating on the base stage, sludge The hopper body (10), base stage (20), stage cover (30), outlet (40), and centrifugal feeder (50) are used to control the discharge amount quantitatively and, in particular, to precisely control the sludge discharge rate by centrifugal feeder rotation speed. The main components include:

Description

Quantitative discharge system for sludge handling hopper units}

The present invention relates to a fixed-quantity discharge system of a hopper device for sludge treatment, and more specifically, improves the structure so that the sludge stored in the hopper body is horizontally transported in a 360° direction through the side discharge port by a centrifugal feeder rotating on the base stage. The present invention relates to a fixed-quantity discharge system for a hopper device for sludge treatment in which the sludge discharge amount is controlled quantitatively, and in particular, the sludge discharge amount can be precisely controlled by the centrifugal feeder rotation speed.

Normally, sludge remaining after wastewater treatment is generated in sewage treatment plants or water purification facilities, and this sludge is stored in silos for drying and discharged in an appropriate amount to be taken outside. At this time, the silos are cylindrical or square tanks. It is formed and a discharge device for discharging sludge is installed at the bottom.

Looking at the conventionally disclosed silo discharge device, in Publication Patent No. 10-2004-0099481, an oval-shaped sliding frame is installed at the inner bottom of the storage silo that stores sludge generated during the treatment process of a sewage treatment plant or water purification facility, and this A cylinder for reciprocating the sliding frame is installed outside the storage silo, and a screw feeder is installed at the lower part of the sliding frame to discharge the sludge supplied to the screw feeder by the reciprocating movement of the sliding frame to the outside through the screw feeder. In a storage silo, a technology has been previously disclosed in which a plurality of auxiliary bars with upper ends protruding inward are installed on the inner surfaces of the outer bars and reinforcements constituting the sliding frame.

However, the prior art is intended to increase the sludge discharge efficiency by installing an auxiliary bar on the inside of the outer bar and reinforcement material constituting the sliding frame, but the screw feeder is locally exposed to the bottom area inside the storage silo, and the screw feeder and the corresponding Since only the sludge in the area was discharged locally, there was a problem that the sludge discharge by the screw feeder could not be controlled consistently.

KR 10-2004-0099481 A (2004.12.02.)

Accordingly, the present invention was conceived to solve the above problems, and the structure was improved so that the sludge stored in the hopper body is horizontally transported in a 360° direction through the side outlet by a centrifugal feeder rotating on the base stage, thereby reducing the sludge discharge. The purpose is to provide a fixed-quantity discharge system for a hopper device for sludge treatment that can precisely control the sludge discharge amount by controlling the quantity and, in particular, the rotational speed of the centrifugal feeder.

In order to achieve this purpose, a feature of the present invention is a hopper body in which an inlet 11 is formed at the top and an opening 12 is formed at the bottom to store sludge generated during the treatment process of a sewage treatment plant or water purification facility. (10); A base stage ( 20); A stage cover (30) whose lower end is connected to the outer peripheral surface of the base stage (20), and whose upper end extends to accommodate the lower area of the hopper body (10), forming a delivery compartment (32) in a closed state by the upper cover (31). ); An outlet 40 that penetrates the base stage 20 corresponding to the unloading compartment 32 and is provided to discharge sludge downward; And a centrifugal feeder (50) installed on the upper surface of the base stage (20) and rotated by a driving unit to discharge sludge toward the side outlet (21) formed at the edge of the base stage (20). It is characterized by

At this time, the centrifugal feeder 50 includes a drive shaft 51 rotated by a drive unit and a plurality of feeding wings 52 arranged radially around the drive shaft 51, and is driven by the drive shaft 51. As the feeding wing 52 rotates, the sludge contained in the hopper body 10 is transferred to the edge of the base stage 20 and discharged through the discharge port 40.

In addition, the centrifugal feeder 50 includes a drive shaft 51 rotated by a drive unit, and a spiral feeding blade 53, one end of which is connected to the drive shaft 51 and the other end of which extends helically, and the drive shaft As the spiral feeding blade 53 rotates by (51), the sludge contained in the hopper body 10 is transferred to the edge of the base stage 20 and discharged through the discharge port 40.

In addition, the centrifugal feeder 50 is formed in a conical structure whose height increases from the edge to the center of rotation, and the sludge contained in the hopper body 10 is fed downward by the conical structure of the centrifugal feeder 50. It is characterized by being

In addition, a ring-shaped milling piece 34 is installed in the unloading compartment 32 and transported up and down by a driving unit, and when the ring-shaped milling piece 34 moves upward, the internal volume of the unloading compartment 32 in which the sludge is accommodated is relatively small. The sludge capacity increases, and when the ring-shaped mill piece 34 moves downward, the internal volume of the unloading compartment 32 where the sludge is accommodated is relatively reduced, and the sludge capacity decreases. When the ring-shaped mill piece 34 moves downward, the sludge is carried out. It is characterized in that the sludge is extruded through the discharge port 40 as the pressure inside the compartment 32 increases.

In addition, the centrifugal feeder 50 is divided into upper and lower feeder parts 50A and 50B,

The lower feeder part (50B) is provided to be rotated by a drive shaft (51), and the upper feeder part (50A) is an inner shaft (51') installed through the center of the drive shaft (51) and rotated by a drive unit. It is connected to and rotates, and the inner shaft 51' is provided to rotate at an increased speed of 10 to 50% compared to the drive shaft 51 by a speed increase module, and the lower feeder part 50B is rotated by the drive shaft 51. It is formed of a plurality of feeding wings 52 or a spiral feeding blade 53, and is provided to transfer the sludge contained in the hopper body 10 to the edge of the base stage 20 and discharge it through the discharge port 40. , the upper feeder part (50A) includes a blade (54) disposed radially around the inner axis (51') to feed sludge downward, and the upper end of the blade (54) is positioned in the rotation direction of the feeder part (50A). It is formed to be inclined and is provided to transport the sludge downward to the lower feeder part (50B) by rotational movement, and the sludge is forcibly transported downward by the blade 54 so that the sludge is held at a predetermined pressure within the area of the lower feeder part (50B). It is characterized in that it is provided to be maintained.

According to the above configuration and operation, the present invention improves the structure so that the sludge stored in the hopper main body is horizontally transported in a 360° direction through the side discharge port by a centrifugal feeder rotating on the base stage, so that the sludge discharge is quantitatively controlled, especially , There is an effect of precisely controlling the sludge discharge amount by centrifugal feeder rotation speed.

1 is a configuration diagram showing the internal structure of a quantitative discharge system of a hopper device for sludge treatment according to an embodiment of the present invention.
Figure 2 is a plan view showing the discharge feeder of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention.
Figure 3 is a configuration diagram showing the conical structure of the discharge feeder of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention.
Figure 4 is a configuration diagram showing a ring-shaped mill piece of a fixed-quantity discharge system of a hopper device for sludge treatment according to an embodiment of the present invention.
Figure 5 is a configuration diagram showing the upper and lower feeder parts of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention.
Figure 6 is a configuration diagram showing the upper and lower feeder parts of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention in a plan view.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. Also, in describing the present invention, if it is determined that related known functions may unnecessarily obscure the gist of the present invention as they are obvious to those skilled in the art, the detailed description thereof will be omitted.

Figure 1 is a configuration diagram showing the internal structure of a quantitative discharge system of a hopper device for sludge treatment according to an embodiment of the present invention, and Figure 2 is a configuration diagram showing the quantitative discharge system of a hopper device for sludge treatment according to an embodiment of the present invention. It is a configuration diagram showing the discharge feeder in plan, and Figure 3 is a configuration diagram showing the conical structure of the discharge feeder of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention, and Figure 4 is an embodiment of the present invention. It is a configuration diagram showing the ring-shaped mill piece of the quantitative discharge system of the hopper device for sludge treatment according to , and Figure 5 is a configuration diagram showing the upper and lower feeder parts of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention. , and FIG. 6 is a plan view showing the upper and lower feeder parts of the quantitative discharge system of the hopper device for sludge treatment according to an embodiment of the present invention.

The present invention relates to a fixed-quantity discharge system of a hopper device for sludge treatment, which has an improved structure so that the sludge stored in the hopper body is horizontally transported in a 360° direction through the side discharge port by a centrifugal feeder rotating on the base stage, sludge The hopper body (10), base stage (20), stage cover (30), outlet (40), and centrifugal feeder (50) are used to control the discharge amount quantitatively and, in particular, to precisely control the sludge discharge rate by centrifugal feeder rotation speed. The main components include:

The hopper body 10 according to the present invention has an inlet 11 formed at the top and an opening 12 formed at the bottom to store sludge generated during the treatment process of a sewage treatment plant or water purification facility.

The hopper body 10 is formed in a cylindrical shape, is installed standing up on a pedestal, is connected to a sludge discharge line of a sewage treatment plant or water purification facility, stores sludge, and is equipped to discharge a fixed amount through a centrifugal feeder 50, which will be described later.

In addition, the base stage 20 according to the present invention is arranged to be spaced downward from the opening 12 of the hopper body 10 to form a side outlet 21 in a 360° side direction, and the hopper body 10 ) It is formed in an expanded size compared to the diameter.

The base stage 20 is formed as a circular plate as shown in FIGS. 1 and 2, and at this time, the base stage 20 is arranged to be spaced apart from the lower end of the hopper body 10 to form a side discharge port 21.

In addition, a centrifugal feeder 50, which will be described later, is disposed between the base stage 20 and the lower part of the hopper main body 10, and the sludge is horizontally transported outward from the center of the base stage 20 by the centrifugal feeder 50. is provided to be discharged in a 360° direction through the side outlet (21).

In addition, the stage cover 30 according to the present invention has a lower end connected to the outer peripheral surface of the base stage 20, and an upper end extended to accommodate the lower area of the hopper body 10 and closed by the upper cover 31. A carry-out compartment 32 is formed.

The stage cover 30 is a component that protects the edge area of the base stage 20, which is expanded relative to the diameter of the hopper body 10, and is provided to accommodate a portion of the sludge discharged through the side outlet 21.

In addition, the discharge port 40 according to the present invention is provided to penetrate the base stage 20 corresponding to the unloading compartment 32 and discharge sludge downward.

The outlet 40 is provided to be openable and closed by a valve, and is provided to discharge the sludge contained in the discharge compartment 32 by the rotational movement of the centrifugal feeder 50, which will be described later.

In addition, the centrifugal feeder 50 according to the present invention is installed on the upper surface of the base stage 20, and is rotated by a driving unit to discharge sludge toward the side discharge port 21 formed at the edge of the base stage 20. It is provided.

In Figure 2 (a), the centrifugal feeder 50 includes a drive shaft 51 rotated by a drive unit and a plurality of feeding wings 52 arranged radially around the drive shaft 51. Here, the feeding wing 52 may be formed with an arcuate curvature or may be formed in a straight line.

Accordingly, there is an advantage that the sludge contained in the hopper body 10 can be transferred to the edge of the base stage 20 and discharged in a fixed amount through the discharge port 40 as the feeding wing 52 is rotated by the drive shaft 51.

In Figure 2 (b), the centrifugal feeder 50 includes a drive shaft 51 rotated by a drive unit, one end connected to the drive shaft 51, and a spiral feeding blade 53 at the other end extending in a spiral shape. Includes.

In addition, the spiral feeding blade 53 is rotated by the drive shaft 51 to transfer the sludge contained in the hopper body 10 to the edge of the base stage 20 and discharge it through the discharge port 40.

As shown in FIG. 2, the sludge is discharged 360° outward from the center of the base stage 20 by the rotational movement of the centrifugal feeder 50, so that the sludge discharge amount is controlled quantitatively. In particular, the rotation of the centrifugal feeder 50 There is an advantage in that sludge discharge can be precisely controlled by speed.

In Figure 3, the centrifugal feeder 50 is formed in a cone-shaped structure whose height increases from the edge to the center of rotation.

Accordingly, due to the conical structure of the centrifugal feeder 50, the sludge contained in the hopper body 10 is fed downward while the centrifugal feeder 50 enters the hopper body 10 relatively deeply, so that the sludge is stored in the hopper body (10). 10) Blockage within the system is prevented.

In FIG. 4, a ring-shaped mill piece 34 is installed in the loading compartment 32 and is moved up and down by a driving unit.

At this time, when the ring-shaped mill piece 34 moves upward, the internal volume of the unloading compartment 32 in which the sludge is accommodated is relatively increased, thereby increasing the sludge capacity, and when the ring-shaped mill piece 34 moves downward, the unloading compartment 32 in which the sludge is accommodated ( 32) The internal volume is relatively reduced and the sludge capacity is reduced.

Also, when the ring-shaped mill piece 34 moves downward, the pressure inside the delivery compartment 32 increases and the sludge is extruded through the discharge port 40.

In this way, the internal volume of the unloading compartment 32 is flexibly adjusted by the vertical movement distance of the ring-shaped mill piece 34, and the amount of sludge contained inside the unloading compartment 32 is controlled, so that the sludge viscosity is relatively low depending on the sludge properties. In this case, the internal volume of the unloading compartment 32 is reduced, and if the sludge viscosity is relatively high, the internal volume of the unloading compartment 32 is expanded to discharge the sludge without interruption.

In FIG. 5, the centrifugal feeder 50 is divided into upper and lower feeder parts 50A and 50B, and the lower feeder part 50B is provided to rotate by a drive shaft 51, and the upper The feeder part 50A is installed through the center of the drive shaft 51 and is connected to and rotates the inner shaft 51' rotated by the drive unit, and the inner shaft 51' is rotated by the drive shaft 51 by the speed increase module. ) It is equipped to rotate at an increased speed of 10 to 50% compared to ).

On the other hand, if the speed of the inner shaft 51' is increased to less than 10% compared to the drive shaft 51, the effect of forced downward pressure of sludge due to the increased speed cannot be expected, and the inner shaft 51' is increased by 50% compared to the drive shaft 51. If it exceeds, there is a problem in that the blade 54, which will be described later, is overloaded and the lifespan of the driving unit is shortened.

At this time, the lower feeder part 50B includes a plurality of feeding wings 52 rotated by the drive shaft 51 as shown in Figure 6 (a) or a spiral feeding blade 53 formed in a spiral shape as shown in Figure 6 (b). It is formed to transfer the sludge contained in the hopper body 10 to the edge of the base stage 20 and discharge it through the discharge port 40.

In addition, the upper feeder part 50A includes blades 54 that are radially arranged around the inner axis 51' as shown in FIG. 6 to feed sludge downward.

At this time, the upper end of the blade 54 is formed to be inclined in the rotation direction of the feeder part (50A), and is provided to transport sludge downward toward the lower feeder part (50B) by rotational movement.

Accordingly, as the sludge is forcibly transported downward by the blade 54 and the sludge is maintained at a predetermined pressure within the lower feeder part (50B) area, the sludge is forcibly supplied to the lower feeder part (50B), thereby ensuring that the sludge is not interrupted. It has the advantage of being able to discharge in a fixed amount.

As described above, the most preferred embodiments of the present invention have been described in the detailed description of the present invention, but various modifications may be made without departing from the technical scope of the present invention. Therefore, the scope of protection of the present invention should not be limited to the above embodiments, but should be recognized to the technologies in the patent claims described later and to equivalent technical means from these technologies.

10: Hopper body 20: Base stage
30: stage cover 40: outlet
50: Centrifugal feeder

Claims (6)

A hopper body 10 having an inlet 11 formed at the top and an opening 12 formed at the bottom to store sludge generated during the treatment process of a sewage treatment plant or water purification facility; A base stage ( 20); A stage cover (30) whose lower end is connected to the outer peripheral surface of the base stage (20), and whose upper end extends to accommodate the lower area of the hopper body (10), forming a delivery compartment (32) in a closed state by the upper cover (31). ); An outlet 40 that penetrates the base stage 20 corresponding to the unloading compartment 32 and is provided to discharge sludge downward; And a centrifugal feeder (50) installed on the upper surface of the base stage (20) and rotated by a driving unit to discharge sludge toward the side outlet (21) formed at the edge of the base stage (20). ,
The centrifugal feeder 50 is divided into upper and lower feeder parts 50A and 50B,
The lower feeder part (50B) has a drive shaft (51) rotated by a drive unit, a plurality of feeding wings (52) arranged radially around the drive shaft (51), or one end connected to the drive shaft (51) and another First, it includes a spiral feeding blade (53) extending spirally,
As the feeding wing 52 or spiral feeding blade 53 is rotated by the drive shaft 51, the sludge contained in the hopper body 10 is transferred to the edge of the base stage 20 and discharged through the discharge port 40. And
The upper feeder part (50A) has an inner shaft (51') installed through the center of the drive shaft (51) and rotated by the drive unit, and is arranged radially around the inner shaft (51') to feed sludge downward. It includes a blade 54 that does,
The blade 54 has an upper end inclined in the direction of rotation of the feeder part 50A and is provided to transport sludge downward toward the lower feeder part 50B through rotational movement,
A fixed-quantity discharge system for a hopper device for sludge treatment, characterized in that the sludge is maintained at a predetermined pressure within the lower feeder part (50B) area by forcefully transporting the sludge downward by the blade (54).
delete delete According to clause 1,
The centrifugal feeder 50 is formed in a conical structure whose height increases from the edge to the center of rotation,
A fixed-quantity discharge system for a hopper device for sludge treatment, characterized in that the sludge contained in the hopper body (10) is fed downward by the conical structure of the centrifugal feeder (50).
According to clause 1,
A ring-shaped wheat piece (34) is installed in the unloading compartment (32) and transported up and down by a driving unit,
When the ring-shaped mill piece 34 moves upward, the internal volume of the unloading compartment 32 where the sludge is accommodated is relatively increased, thereby increasing the sludge capacity,
When the ring-shaped mill piece 34 moves downward, the internal volume of the unloading compartment 32 where the sludge is accommodated is relatively reduced, thereby reducing the sludge capacity,
A fixed-quantity discharge system for a hopper device for sludge treatment, characterized in that when the ring-shaped mill piece (34) moves downward, the internal pressure of the discharge compartment (32) increases and the sludge is extruded through the discharge port (40). delete

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