KR200489350Y1 - Waste transfer apparatus of anti-abrasion structure using compressed air - Google Patents

Abstract

The present invention is characterized in that a contaminant receiving portion 11 in which a contaminant 1 is received is formed therein and an inlet 12 and an outlet 13 are formed in the upper and lower ends, (10) having a conveying device (15) formed thereon; Is inserted into the conveying apparatus main body 10 through the through hole 15 of the conveying apparatus main body 10 and supplies the compressed air to the contaminant receiving portion 11 of the conveying apparatus main body 10, A compressed air supply pipe (20) provided with an inclined nozzle portion (21) inclined upwards toward an inlet (12) of the nozzle (10); A closing valve 30 for opening and closing the inlet 12 of the conveying apparatus body 10 by the closing valve driving unit 40; And a shock absorbing member (50) provided on a bottom surface of the feed valve (30) closing the feed port (12) of the feeder body (10) Device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-abrasive structure using compressed air,

The present invention relates to a non-abrasive structure for transporting contaminants by compressed air at high pressure, and more particularly, to an apparatus and a method for transporting contaminants by a high- Abrasion of the abrasive grains is effectively prevented, thereby improving the durability of the abrasive grains.

Industrial sewage or industrial wastewater generated in an industrial society is treated in a sewage treatment plant. A sludge lifting device is used to remove sediments such as sand, which is a sediment introduced together with sewage and wastewater. This sludge lifting machine discharges the sand and other foreign substances accumulated on the bottom of the sludge settlement to the outside of the sludge sludge so as to prevent contamination such as odor generation or scattering when the sludge is transported. So as to feed the contaminants.

Figs. 1 and 2 show an example of a device for transferring contaminants using compressed air. As shown in the figure, the apparatus main body 2 has a hollow portion formed therein and an inlet 3 through which the obstacle 1 is inserted and an outlet 4 through which the obstacle 1 is discharged, A compressed air supply pipe 5 connected to an upper portion of the apparatus main body 2 for supplying compressed air at a high speed to the inside thereof and a closing valve 6 for opening and closing the loading port 3 of the apparatus main body 2 . At this time, when a part of the impurities 1 attracted by the high-speed compressed air injected into the compressed air supply pipe 5 collides with a specific part inside the apparatus main body 2 and a certain pressure is formed, (4).

2, the high-pressure compressed air injected at a high speed through the compressed air supply pipe 5 rotates in the form of a cyclone, and the impurities 1 are moved in the same manner as the compressed air There is a problem that the apparatus main body 2 is abraded due to the collision of the needle component in the rotating impurity 1 with the inner wall of the apparatus main body 2, thereby shortening the service life of the apparatus.

Korean Registered Utility Model No. 20-0354039

The object of the present invention is to reduce the speed of the compressed air injected into the conveying device at high speed during the injection of the high-pressure compressed air to minimize the residual speed and to maintain the pressure only. Therefore, it is possible to prevent rapid rupture of the inside of the conveying apparatus due to high-speed compressed air and impurities, thereby improving the durability of the conveying apparatus due to the minimization of the abrasion inside the conveying apparatus and improving the hermeticity of the conveying apparatus. Which is capable of preventing the leakage of the compressed air more effectively and spreading the compressed air evenly, thereby improving the conveyance efficiency of the impurities.

According to a feature of the present invention, a contaminant receiving portion 11 in which a contaminant 1 is accommodated is formed therein, and an inlet 12 for introducing and discharging the contaminant 1 and an outlet 13 And a through hole 15 is formed in an upper side of the side wall of the conveying apparatus main body 10; Is inserted into the conveying apparatus main body 10 through the through hole 15 of the conveying apparatus main body 10 and supplies the compressed air to the contaminant receiving portion 11 of the conveying apparatus main body 10, A compressed air supply pipe (20) provided with an inclined nozzle portion (21) inclined upwards toward an inlet (12) of the nozzle (10); A closing valve 30 for opening and closing the inlet 12 of the conveying apparatus body 10 by the closing valve driving unit 40; And an inlet valve (12) for closing the feeder body (10), and is provided on the bottom surface of a feed valve (30) when the feed air is collided with the compressed air injected from the inclined nozzle part (21) And a shock absorbing member (50) for absorbing impact to reduce a collision speed. The apparatus for transporting a contaminant of a non-abrasive structure using compressed air is provided.

According to another feature of the present invention, the closing valve driving part 40 for driving the closing valve 30 is mounted on the outer circumferential surface of the conveying device body 10 and its tip is coupled to the upper surface of the closing valve 30, The closing valve 30 is moved by the closing valve driving part 40 in a state where the edge of the closing valve 30 is hooked on the inner circumferential part of the closing port 12 of the conveying device body 10 and the closing port 12 is closed The inlet valve 12 is lowered to the inside of the apparatus body 10 to open the inlet port 12 of the transfer apparatus main body 10 and the bottom surface of the inlet valve 30 is recessed upwardly and radially outward There is provided a contaminant transfer apparatus of a non-abrasive structure using compressed air, characterized in that a curved surface portion 31 forming a downwardly curved surface is formed.

As described above, according to the present invention, in order to jet compressed air at a high speed toward the charging port 12 of the transfer device body 10 at the end of the compressed air supply pipe 20 protruding into the transfer device body 10, And a shock absorbing member 50 is provided on the inner surface of the loading valve 30 for opening and closing the loading port 12 of the conveying apparatus main body 10. [ As a result, the high-pressure compressed air is supplied to the bottom surface of the inlet valve 30 while the obstruction 1 in the conveying apparatus main body 10 is fed, The sealing performance of the inlet valve 30 is improved and leakage of the compressed air through the inlet valve 30 is prevented and the compressed air can discharge the obstacle 1 to a higher pressure. In addition, since the impact velocity of the compressed air injected at a high speed collides with the impact absorbing member 50, the compressed air containing the impurities due to the action of the high-speed compressed air (1) 10, the damage to the conveying apparatus main body 10 is fundamentally prevented, so that the durability is improved.

The curved surface portion 31 concaved upward is formed on the bottom surface of the closing valve 30 which closes the inlet 12 of the conveying apparatus main body 10 so that the compressed air injected at a high speed is guided to the curved surface portion The pressure is converted to pressure and spreads evenly over the entire impureance receiving portion 11 of the conveying apparatus main body 10 so that the impurities 1 are pressed more uniformly, It can be discharged more quickly to the discharge port 13 on the lower side, and the contaminant 1 can be transported more efficiently.

1 is a view showing an example of a conventional transfer apparatus using air;
Fig. 2 is a cross-sectional view taken along line AA in Fig.
3 is a view showing an embodiment of a transfer device using air according to the present invention.
Fig. 4 is a flowchart showing the operation state of the embodiment

The objects, features and advantages of the present invention will become more apparent from the following detailed description. Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 3 and FIG. 4 are views showing a non-abrasive structure of a contaminant transferring apparatus using compressed air according to a preferred embodiment of the present invention. As shown in FIG. 1, according to an embodiment of the present invention, a non-abrasive structured contaminant transfer apparatus using compressed air is provided with a hopper or a container (not shown) using compressed air to remove impurities such as sludge or dewatered sludge in a wastewater treatment plant, A conveying apparatus main body 10 having an inlet port 12 and an outlet port 13 through which the impurities 1 are introduced and discharged into the upper and lower portions, A compressed air supply pipe 20 for supplying compressed air to the upper side of the transfer apparatus main body 10 and a closing valve 30 for opening and closing the loading port 12 of the transfer apparatus main body 10. At this time, the discharge port (13) of the transfer device body (10) is connected to an unillustrated transfer pipe as is well known.

The transfer apparatus main body 10 is provided with an impregnation accommodating portion 11 for accommodating the impurities 1 therein and an inlet 12 through which the impurities 1 are introduced into the upper surface thereof, A discharge port 13 connected to the transfer pipe is formed. At this time, a charging chute 14 is provided in the charging port 12 of the conveying apparatus main body 10 for facilitating the insertion of the obstacle 1. A through hole 15 is formed in the upper side of the side wall of the transfer device body 10 to connect the compressed air supply pipe 20.

The compressed air supply pipe 20 is connected to an unillustrated air compressor and a compressed air storage tank and the other end is coupled to the through hole 15 of the transfer device body 10 to supply the compressed air to the impregnation receptacle (11). 3, the other end of the compressed air supply pipe 20 protrudes into the contaminant receiving portion 11 of the conveying apparatus main body 10 and has an inclined slope upwardly inclined toward the inlet 12 of the conveying apparatus body 10 And a nozzle unit 21 is provided. At this time, the inclined nozzle unit 21 may be formed by bending or bending the end portion of the compressed air supply pipe 20 upwardly, and no separate parts may be used. Thus, the compressed air is injected at a high speed into the inlet 12 of the transfer device body 10 through the inclined nozzle portion 21 of the compressed air supply pipe 20.

The charging valve 30 opens and closes the charging port 12 of the transfer device body 10 by the charging valve driving unit 40. 4, the inlet valve 30 is rotated to the inside of the conveying apparatus main body 10 to open and close the inlet port 12, and the bottom surface of the inlet valve 30, in which the inlet port 12 is closed, 31 are formed. At this time, it is preferable that the concave portion 31 forms a spherical surface in the form of a dome. It is preferable that the introduction valve 12 is formed in the form of a dome as a whole. 3, the introduction valve 30 itself is formed in a dome shape forming a part of a spherical surface, and is provided in the impurity containing portion 11 of the transfer device body 10 and has an edge, The closing valve 30 closes the charging port 12 in a state in which the charging port 30 is in contact with the charging port 30.

The closing valve driving unit 40 includes a cylinder 41 mounted on a side portion of one side wall of the conveying apparatus body 10 and an opening / closing valve 40 having one end connected to the cylinder 41 and the other end connected to the outer peripheral surface of the closing valve 30 And a rod 42. At this time, the cylinder 41 may be an air cylinder or a hydraulic cylinder. The opening and closing rod 42 performs a seesaw movement vertically about a hinge shaft 43 formed horizontally on one side of a circumferential portion of the loading port 12 of the conveying apparatus body 10 and moves up and down with respect to the hinge shaft 43 A part of the opening / closing rod 42 positioned between the inlet valves 30 is bent or curved. When the cylinder 41 is extended, the loading valve 30 is lowered as the opening / closing rod 42 is rotated around the hinge shaft 43, The inlet 12 is completely opened.

3, the impact absorbing member 50 is formed so that the impact absorbing member 50 is in contact with the bottom surface of the inflow valve 30 (the inner side surface of the impact absorbing member 50) . At this time, the shock absorbing member 50 is provided in the concave portion 31, which is the bottom surface of the injection valve 30, so that the compressed air injected at high speed from the oblique nozzle portion 21 of the compressed air supply pipe 20, And absorbs the impact when it collides with the vehicle body 50, thereby reducing the collision speed. Such an impact absorbing member 50 may be formed in various forms that can reduce the impact speed by absorbing the impact when high-speed compressed air such as a pull-up seminar, synthetic resin porous foam or the like is collided. As a result, the compressed air injected at a high speed is absorbed by the collision with the porous surface of the impact absorbing member 50, and the speed is reduced. Therefore, the impurity (1) The air does not collide with the inner wall surface of the transfer apparatus main body 10, so that the transfer apparatus main body 10 is not damaged or damaged. Reference numeral 51 denotes a retainer that firmly fixes the shock absorbing member 50 to the closing valve 30. The retainer 51 is configured to divide the concave portion 31 of the closing valve 30 into a plurality of ≪ / RTI >

The apparatus for conveying contaminants of a non-abrasive structure using compressed air according to an embodiment of the present invention is characterized in that the closing valve 30 of the conveying apparatus main body 10 is connected to the conveying apparatus main body 10 by the closing valve driving section 40, And the closing valve 30 closes the inlet 12 of the conveying apparatus main body 10 after the inlet 12 of the conveying apparatus main body 10 is opened and the contaminant 1 is introduced into the contaminant receiving section 11 of the conveying apparatus main body 10, The compressed air is injected at a high speed into the bottom surface of the closing valve 30 through the inclined nozzle portion 21 of the compressed air supply pipe 20. Thus, the compressed air injected at high speed is reflected by the bottom surface of the inlet valve 30 to reduce the velocity, but the impurities 1 contained in the impurity containing portion 11 of the transfer device main body 10, So that the impurities 1 are discharged through the discharge port 13. At this time, the shock absorbing member 50 is provided on the bottom surface of the injection valve 30, so that the compressed air injected at a high speed through the compressed air supply pipe 20 collides with the impact absorbing member 50, (1) Due to the attracting action, compressed air containing contaminants does not collide with the inner wall surface of the conveying apparatus main body 10, so that the conveying apparatus main body 10 is not damaged or damaged. 3, the concave portion 31 of the inlet valve 30 forms a spherical surface, so that the compressed air is reflected by the concave portion 31 of the inlet valve 30 and spreads radially outward of the inlet valve 30 I'm going. 3, the compressed air spreads evenly over the entire impurity containing portion 11 of the conveying apparatus main body 10, so that the impurities 1 can be pressed more uniformly and conveyed more efficiently have.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

1: Contaminant 10: Feeder body
12: inlet 13: outlet
20: compressed air supply pipe 21: inclined nozzle part
30: closing valve 40: closing valve driving section
50: shock absorbing member

Claims (2)

And a discharge port 13 and a discharge port 13 through which the contaminant 1 is injected and discharged are formed in the upper and lower ends of the impurity accommodating portion 11, (10) having a conveying device (15) formed thereon;
Is inserted into the conveying apparatus main body 10 through the through hole 15 of the conveying apparatus main body 10 and supplies the compressed air to the contaminant receiving portion 11 of the conveying apparatus main body 10, A compressed air supply pipe (20) provided with an inclined nozzle portion (21) inclined upwards toward an inlet (12) of the nozzle (10);
A closing valve 30 for opening and closing the inlet 12 of the conveying apparatus body 10 by the closing valve driving unit 40; And
Is provided on the bottom surface of the closing valve 30 which closes the inlet 12 of the conveying apparatus main body 10 and is in contact with the compressed air injected through the inclined nozzle portion 21 of the compressed air supply pipe 20 And a shock absorbing member (50) for reducing a collision speed of the impurities. The apparatus according to claim 1, wherein the closing valve driving part (40) for driving the closing valve (30) is mounted on the outer circumferential surface of the conveying device body (10) and its tip is coupled to the upper surface of the closing valve The closing valve 30 is closed by the closing valve driving part 40 in a state in which the rim of the feeding device 30 is hooked to the inner circumferential part of the feeding port 12 of the feeding device body 10, The inlet port 12 of the transfer apparatus main body 10 is closed and the bottom surface of the inlet valve 30 is recessed upward and downward in the radial direction outward from the center, And a curved surface portion (31) forming a curved surface is formed on the upper surface of the upper surface.

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