KR101453886B1 - Disk valve for discharging device of activated carbon - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a valve for discharging activated carbon, and more particularly to a disc valve for discharging activated carbon used for controlling discharge of activated carbon in a sintering plant or the like. A disk valve for exhausting activated carbon according to the present invention comprises: a disk for opening / closing a discharge path while being in contact with a bottom surface of an exhaust path outside the activated carbon discharge path; A disk drive cylinder provided for movement of the disk outside the discharge path; And a link member rotatably installed outside the discharge path and connecting the disk and the disk drive cylinder to rotate the disk drive cylinder to move the disk. According to the disk valve for discharging activated carbon of the present invention, the disk is not in contact with the inner surface of the discharge path through which the activated carbon is discharged. Instead, the disk is brought into contact with the end surface of the discharge path from the outside of the discharge path, It is possible to prevent the activated carbon powder from being coated on the inner surface of the disk and the discharge path.

Description

DISK VALVE FOR DISCHARGING DEVICE OF ACTIVATED CARBON

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a valve for discharging activated carbon, and more particularly to a disc valve for discharging activated carbon used for controlling discharge of activated carbon in a sintering plant or the like.

Generally, since exhaust gas generated during operation in sinter plants contains nitrogen oxides and sulfur oxides, when they are discharged into the atmosphere, they cause serious environmental pollution. Therefore, in the sintering plant or the like, exhaust gas cleaning equipment for removing harmful gas contained in the exhaust gas using activated carbon is installed.

The hopper is installed in the flue gas cleaner, and the activated carbon discharged from the flue gas cleaner is firstly stored in the hopper and discharged to the bottom conveyor. In the process of discharging the activated carbon powder from the hopper, the discharge amount is controlled through the discharge valve.

Conventionally, the amount of fluid powdered fluid, such as activated carbon powder, was controlled by a knife gate valve. A technique for a knife gate valve is disclosed in Korean Patent Registration No. 0938865 and Korean Registered Utility Model No. 0385285 (hereinafter referred to as "prior art").

The knife gate valve according to the prior art documents has a conveying path through which fluids such as various powders are conveyed and has a knife gate which is vertically operated on the conveying path to open and close the conveying path.

According to the prior art in which the amount of activated carbon powder is controlled by using the knife gate valve, when the knife gate valve is used for a long time, the powder coating on the surface of the knife gate and the wall surface of the transfer path occurs. That is, the knife gate opens / closes the transporting passage while being vertically moved forward and backward with respect to the transporting path. When the opening is closed, the end portion contacts the inner wall surface of the transporting path, so that the activated carbon powder is transported to the inner wall surface of the transporting path and to the surface A phenomenon occurs in which the coating layer is coated.

The operation of the knife gate is precisely controlled by sensing by the sensor. Since the powder is coated on the wall surface of the knife gate and the transfer path, the sensor can not normally detect movement of the knife gate, so that precise movement control of the knife gate becomes difficult . Therefore, it may interfere with normal operation of the equipment.

DISCLOSURE OF THE INVENTION An object of the present invention is to solve the above-mentioned problems of the related art, and it is an object of the present invention to provide a disc valve for discharging activated carbon, which can precisely open / close a discharging path of activated carbon powder, .

A disk valve for exhausting activated carbon according to the present invention comprises: a disk for opening / closing a discharge path while being in contact with a bottom surface of an exhaust path outside the activated carbon discharge path; A disk drive cylinder provided for movement of the disk outside the discharge path; And a link member rotatably installed outside the discharge path and connecting the disk and the disk drive cylinder to rotate the disk drive cylinder to move the disk.

The disk valve for discharging activated carbon according to the present invention further includes a housing in which the disk is moved in position and the lower end of the discharge path is located therein.

The link member is formed with a disk coupling portion into which a lower end of the disk is inserted and coupled. The lower end of the disk is elastically supported by the elastic member in the disk coupling portion, and the elastic member is urged in a direction in which the disk is in close contact with the bottom surface of the discharge path .

The disc valve for discharging activated carbon according to the present invention is located on the movement path of the disc and the bottom surface is located on the same horizontal plane as the bottom surface of the discharge path so that the top surface of the disc slides when the disc is moved to the open position, To prevent the guide member from being detached from the moving path.

On the upper surface of the disk, coating grooves coated with ceramics are formed, and the upper surface of the ceramic coating layer is aligned with the upper surface of the disk.

In order to prevent the discharge path and the disk from being broken when the disk is brought into contact with the bottom surface of the discharge path, an inclined surface is formed at the inner surface of the discharge path at the bottom.

According to the disk valve for discharging the activated carbon of the present invention, there are the following effects.

First, the disc is not in contact with the inner surface of the discharge path through which the activated carbon is discharged, but is made to contact the bottom surface of the discharge path from the outside of the discharge path to open or close the discharge path, It is possible to prevent coating on the inner surface.

Second, since the upper surface of the disk is moved while being in contact with the departure-avoiding guide in the process of being moved to the open or closed position, the position of the disk can be prevented from being displaced even if the force of the elastic member acts on the disk.

Thirdly, by applying a ceramic coating on the top surface of the disk, it is possible to prevent the top surface of the disk from being worn when it comes into contact with the bottom surface of the discharge path, and to prevent the active carbon powder from being coated on the top surface of the disk due to moisture.

Fourthly, since the disc housing is provided to prevent the disc from being exposed to the outside when the disc is opened, it is possible to safely protect the disc when the disc is opened and to disassemble the disc housing without disassembling the other parts when repairing or replacing the disc The disc can be easily repaired or replaced. Particularly, the operation of the disk can be easily observed by disassembling the disk housing.

Fifth, a force is applied so that the disc is elastically supported by the elastic member, but the elastic member is brought into close contact with the bottom surface of the discharge path, so that the discharge path can be precisely opened or closed by using the disc.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing an installation state of an activated carbon discharge disc valve according to a preferred embodiment of the present invention. FIG.
FIG. 2 is a cross-sectional view illustrating an installation state of an activated carbon discharge disc valve according to a preferred embodiment of the present invention. FIG.
3 is a sectional view of the first connection portion shown in Fig.
4 is a cross-sectional view of the second connection portion shown in Fig.
FIG. 5 is an enlarged cross-sectional view showing an installation state of the disk shown in FIG. 2;
6 is a plan view showing the operating state of the disk shown in FIG. 2;

Hereinafter, a disc valve for discharging activated carbon according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing an installation state of an activated carbon discharge disc valve according to a preferred embodiment of the present invention.

The disc valve 1 for discharging activated carbon according to the present invention is provided at the discharge port side of the hopper 2 filled with activated carbon to open or close the discharge port to control the discharge amount of activated carbon. A conveyor (not shown) for conveying the activated carbon to be discharged is provided below the disc valve 1 for discharging the activated carbon.

The disc valve for exhausting activated carbon according to the present invention comprises a valve housing 10, a disc housing 20, a disc drive cylinder 30, a rotary shaft 40, a first link member 50, and a pair of limit switches (60) and (61).

The valve housing 10 is installed on the discharge port side of the hopper 2, and the disk 100 to be described later is operated inside. Activated carbon powder discharged from the hopper 2 is primarily discharged into the valve housing 10 and then discharged through the lower end of the valve housing 10 to the conveyor.

The disc housing 20 is coupled to the side of the valve housing 10 to protect and enclose the disc 100 when the disc 100 is open, (100) can be easily repaired or replaced. When the disk housing 20 is disassembled, the operating state of the disk 100 can be visually confirmed.

The disk drive cylinder 30 is installed outside the valve housing 10 in a horizontal state, and rotates in the left and right direction when the disk drive cylinder 30 is operated.

The rotary shaft (40) is rotatably installed while passing through the valve housing (10). The installation position of the rotary shaft 40 is not overlapped with the movement range of the disc 100 and is not overlapped with the discharge path of the activated carbon. The upper end and the lower end of the rotary shaft (40) protrude above and below the valve housing (10). The rotary shaft 40 is connected to the piston end of the disk drive cylinder 30 through the first link member 50 and is connected to the disk 100 through a second link member 110 which will be described later.

The first link member 50 connects the disk drive cylinder 30 and the rotary shaft 40. One end of the first link member 50 is rotatably connected to the piston end of the disk drive cylinder 30 in the left and right direction and the other end of the first link member 50 is connected to the rotary shaft 40 As shown in Fig.

The limit switches 60 and 61 are fixed to the upper portion of the valve housing 10 so as to be in contact with the rotary plate 41 fixed to the upper end of the rotary shaft 40 from above the valve housing 10 when the rotary shaft 40 rotates, Thereby detecting the position of the disc 100. [ That is, since the disc 100 rotates together with the rotating shaft 40, it can be detected through the two limit switches 60 and 61 that the disc 100 is in the opened state or closed state of the activated carbon discharge port .

FIG. 2 is a cross-sectional view showing a state in which an activated carbon discharge disc valve according to a preferred embodiment of the present invention is installed, FIG. 3 is a sectional view of the first connection portion shown in FIG. 2, Fig.

The disc valve 1 for discharging activated carbon according to the present invention includes a first connecting portion 70, a second connecting portion 80, a discharge sheet 90, a disc 100, a second link member 110, 120).

The first connection portion 70 is connected to the outlet of the lower end of the hopper 2, and has a wide upper end and a narrow bottom end, and an inner side thereof is hollow to discharge activated carbon. The upper and lower ends of the first connection portion 70 are respectively formed with flanges for coupling with other components.

The second connection portion 80 is coupled to the lower end flange of the first connection portion 70 so that the discharge hole 81 for discharging the lower portion of the activated carbon discharged from the first connection portion 70 is connected to the hollow portion of the first connection portion 70, Respectively. The second connection portion 80 is formed with a rotation shaft through hole 82 through which the rotation shaft 40 passes.

A hermetic sealing member 130 is interposed between the first and second connecting portions 70 and 80 to maintain airtightness when the activated carbon is discharged.

The discharge seat 90 is coupled to the bottom surface of the second connection portion 80 in the valve housing 10, and the disk 100 is brought into contact with the bottom surface of the lower end portion. The discharge seat (90) is hollowed inward to communicate with the discharge hole (81) of the second connection portion (80). A flange for coupling with the second connection portion 80 is formed at the upper end of the discharge sheet 90.

A hermetic sealing member 130 is interposed between the second connection portion 80 and the valve housing 10 and between the second connection portion 80 and the discharge sheet 90 to maintain airtightness during the discharge of activated carbon.

The disk 100 is formed in a circular shape on its upper surface by making the hollow of the discharge sheet 90 open / close while being in contact with the lower end bottom surface of the discharge sheet 90. The disk 100 is formed to have a reduced cross-sectional area from the upper end to the lower end, and the lower end of the disk 100 is connected to the second link member 110.

The second link member 110 connects the disc 100 and the rotary shaft 40 with one end connected to the disc 100 and the other end fixed to the rotary shaft 40.

The departure prevention guide 120 is installed along the path for moving the disc 100 from the lower end side surface of the discharge sheet 90 in the space in the valve housing 10 and the disc housing 20, Is slid, thereby preventing the disc 100 from being detached. The bottom surface of the departure prevention guide 120 is positioned on the same horizontal plane as the bottom surface of the discharge sheet 90. [

5 is an enlarged cross-sectional view showing an installation state of the disk shown in FIG.

At one end of the second link member 110, a disk coupling portion 111 to which a lower portion of the disk 100 is coupled is formed. A disk coupling groove 112 opened upward is formed in the disk coupling portion 111 and a coupling projection 101 formed on a lower portion of the disk 100 is inserted into the disk coupling groove 112.

A spring 140 for resiliently supporting the disc 100 is inserted in the disc coupling groove 112 to exert a force in a direction to push the disc 100 upward.

An elastic force adjusting bolt 113 is screwed to the lower portion of the disc coupling portion 111 to adjust a force acting on the disc 100 from the spring 140. That is, when the spring 140 is pushed upward by tightening the elasticity adjusting bolt 113, the force applied from the spring 140 to the disk 100 becomes large, and the elastic force adjusting bolt 113 is released to lower the position of the spring 140 The force applied from the spring 140 to the disc 100 is weakened. When the force applied to the disc 100 from the spring 140 is increased, the degree of contact between the disc 100 and the bottom surface of the discharge sheet 90 becomes strong, and the force applied from the spring 140 to the disc 100 becomes weak The degree to which the disc 100 is brought into close contact with the bottom surface of the discharge sheet 90 is weakened.

A top surface of the ceramic coating layer 103 formed on the coating groove 102 coincides with the top surface of the disc 100. The top surface of the ceramic coating layer 103 is formed on the top surface of the disc 100. The ceramic coating layer 103 prevents the disc 100 from being abraded when it contacts the bottom surface of the discharge sheet 90 and prevents dust from contacting the top surface of the disc 100 due to moisture.

The inclined surface 91 is formed at the bottom of the inner surface of the discharge sheet 90 to prevent the discharge sheet 90 and the disk 100 from being damaged when the disk 100 is contacted.

FIG. 6 is a plan view showing an operating state of the disk shown in FIG. 2. FIG.

When the piston of the disk drive cylinder 30 advances, the first link member 50, the rotary shaft 40 and the second link member 110 rotate clockwise, and the disk 100 moves from the closed position to the open position Position. At this time, the rotary plate 41 coupled to the upper end of the rotary shaft 40 is connected to the limit switch 60 located on the front side of the drawing of the pair of limit switches 60 and 61, Is detected.

On the contrary, when the piston of the disk drive cylinder 30 is retracted, the first link member 50, the rotation shaft 40 and the second link member 110 are rotated counterclockwise, and the disk 100 is rotated in the open position And is moved to the closed position. At this time, the rotary plate 61 coupled to the upper end of the rotary shaft 40 is connected to the limit switch 61 positioned behind the drawing of the pair of limit switches 60 and 61, Is detected.

According to the disc valve for discharging activated carbon of the present invention having the above-described structure and action, the following functional features are provided.

The disc 100 is not in contact with the inner surface of the discharge path through which the activated carbon is discharged but rather is brought into contact with the bottom surface of the discharge path outside the discharge path to open or close the discharge path, And the inner surface of the discharge path.

Since the upper surface of the disc 100 is moved while being in contact with the departure prevention guide 120 in the process of being moved to the open or closed position, even if the force of the spring 140 acts on the disc 100, It is possible to prevent the position from being deviated. That is, since the upper portion of the disc 100 is clogged by the departure prevention guide 120 and the elastic force from the spring 140 is continuously applied to the lower portion of the disc 100, the disc 100 is moved to the horizontal state .

By providing a ceramic coating on the top surface of the disc 100, it is possible to prevent the top surface of the disc 100 from being worn when it comes into contact with the bottom surface of the discharge path, and the activated carbon powder is coated on the top surface of the disc 100 due to moisture Can be prevented.

It is possible to safely protect the disc 100 when the disc 100 is opened and to prevent the disc 100 from being damaged when the disc 100 is opened, by providing the disc housing 20 that prevents the disc 100 from being exposed to the outside when the disc 100 is opened. It is possible to easily repair or replace the disc 100 by disassembling only the disc housing 20 without disassembling the other parts. Particularly, the operation of the disc 100 can be easily observed by disassembling the disc housing 20.

The disc 100 is elastically supported by the spring 140 so that the spring 140 exerts a force such that the disc 100 is brought into close contact with the bottom surface of the discharge path so that the discharge path can be precisely opened or closed using the disc 100, . That is, when the disc 100 is closed, there is no gap between the disc 100 and the discharge path, so there is no possibility that the powder of active carbon leaks to the outside. When the disc 100 is moved, The activated carbon powder is completely removed by the bottom surface of the discharge path, so there is no possibility that the surface of the disk 100 is coated with the activated carbon powder.

As described above, the disk valve for discharging activated carbon according to the present invention has been described on the basis of the preferred embodiment, but the present invention is not limited to the specific embodiment. Can be changed.

1: disc valve for discharging activated carbon 10: valve housing
20: disk housing 30: disk drive cylinder
40: rotary shaft 41: rotary plate
50: first link member 60, 61: limit switch
70: first connection part 80: second connection part
90: discharge sheet 91: inclined surface
100: Disk 101:
102: coating groove 103: ceramic coating layer
110: second link member 111: disk coupling portion
112: disk coupling groove 113: elastic force adjusting bolt
120: departure prevention guide 130: airtightness maintaining member
140: spring

Claims (6)

A disk that opens / closes the discharge path in contact with the bottom surface of the discharge path outside the activated carbon discharge path;
A disk drive cylinder provided for movement of the disk outside the discharge path;
A link member rotatably installed outside the discharge path and connecting the disk and the disk driving cylinder to rotate the disk driving cylinder to move the disk;
A housing in which a position of the disk is moved inside and a lower end of the discharge path is located inside; And
The disc is slid while being in contact with the upper surface of the disc when the disc is moved to the open position so that the disc is separated from the moving path And an anti-departure guide for guiding the movement of the activated carbon in the closed state. delete The method according to claim 1,
The link member is formed with a disk coupling portion into which a lower end of the disk is inserted and coupled. The lower end of the disk is elastically supported by an elastic member in the disk coupling portion. The elastic member is in contact with the bottom surface of the discharge path And a force is applied to the activated carbon in the direction of the arrow. delete The method according to claim 1,
Wherein the upper surface of the disc is formed with a coating groove coated with ceramic and the upper surface of the ceramic coating layer is coincident with the upper surface of the disc. The method according to claim 1,
Wherein an inclined surface is formed at an inner bottom surface of the discharge path to prevent the discharge path and the disk from being damaged when the disk contacts the bottom surface of the discharge path.

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