KR970000509Y1 - Apparatus for moving bulk material in closed conduits - Google Patents

Abstract

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Description

Chain Conveyor System of Feed Pipeline

Figure 1 is an installation example of the transfer pipeline to which the subject innovation chain conveyor device is applied.

2 is a partial perspective view of the present invention chain conveyor.

Figure 3 (a) is an exemplary cross-sectional view showing the operation of the chain conveyor when the pipeline has a reverse direction of the bending direction,

(b) is a plan view showing the operation of the chain conveyor when the pipeline is curved at 45 °.

Figure 4 (a) and (b) is to show the rotational operation of the conveying plate of the chain conveyor of the present invention, Figure 4 (a) is a cross-sectional view A-A of Figure 3,

4B is a cross-sectional view of the line B-B.

Figure 5 is a perspective view showing the action of the rotational movement and the curved guide plate of the present invention chain conveyor.

6 is a state of movement of the transfer disc when the pipeline is horizontal.

7 is a driving example of the chain conveyor of the present invention.

* Explanation of symbols for main parts of the drawings

a: pipeline b: surface

b1, b2: reverse bending surface 1: feed outlet

2: drive unit 3: main drive roller

4: ring chain 5: transfer disc

6: surface movement guide plate 7: guide roller

The present invention has been made to improve the conveying conveyor in the conveying apparatus using pipelines. The purpose of the present invention is to obtain an efficient conveying apparatus by using a ring chain, a disc and a guide plate for an endless pipeline and an endless conveying conveyor installed therein. .

The conveying device of pipelines is applied evenly to convey various industrial wastes, and it is a conveying device suitable for sludge of toxic substance or metal processing sludge.

Conventionally known pipeline conveying apparatus uses a pneumatic pressure to convey waste to a certain distance, and when the pipeline is long and the pneumatic pressure does not reach the end, a compressed air supply pump is installed at several places in the pipeline.

However, such a device requires a lot of installation cost and heavy weight, such as metal sludge that generates a lot of noise is a problem that is difficult to transport.

In order to solve such a problem, a known prior art is known as Japanese Utility Model Publication No. Hei 1-34612 (injection conveying device), but it is a bending direction when a blade connected to a connecting chain passes through a bent feed path of a pipe. As the connecting chain is twisted at this opposite part, the clearance space is generated between the connecting chain and the inner wall of the pipe. When the amount of waste supply is not constant, the position fixing function due to the self weight of the blade is lost and excessive twisting of the connecting chain occurs. As a result, the length of the connecting chain is reduced and the connecting chain is cut or the overload is generated in the driving motor, and the overload is damaged due to the damage of the driving parts and the friction between the inner wall of the pipe and the chain transfer speed. There is a problem that does not stand.

The present invention was devised to improve the problem of the transfer apparatus in the above-described conventional pipeline, and the curved guide plate is installed in a symmetrical state at the part where the bending direction is opposite to remove the clearance space between the ring chain and the transfer pipeline. By doing so, the ring chain can be twisted while contacting the arc inner surface of the curved guide plate, thereby suppressing the endless flow caused by the frictional force, so that excessive twisting over the proper range will not occur even if the waste supply is not constant.

Hereinafter, the configuration and operation of the present invention will be described based on the accompanying drawings.

A drive unit (2) installed at a feed discharge port (1) side of a known feed pipe line (a) having curved surfaces (b) of various angles and including a main drive roller (3); A ring chain (4) installed in a continuous state over the entire length of the conveying pipeline (a) and wound on the main drive roller (3) to be forced to continuously rotate; A plurality of transfer discs 5 fixedly installed at fixed intervals on the ring chain 4; It is installed on the inner side of the curved surface (b) of the conveying pipe line (a) and is provided with a guide roller (7) for preventing the smoothness and friction of movement in the curved surface (b) portion of the ring chain (4) In the structure of; Among the curved surfaces (b) of the conveying pipe line (a), diagonally alternately connected to the upper surface inside the straight portion between the reverse bending surfaces (b1) and (b2) in which the mutual bending directions are opposite to each other, and the conveying pipeline (a) It is to be equipped with a curved guide plate 6 of the arc-shaped cross section for excluding the gap between the inner surface and the ring chain (4).

Unexplained reference numeral 10 in the drawing shows a conveying feed hopper.

Referring to the effect of the present invention made in detail as follows.

The feeder supply hopper is transported by the transfer disc 5 of the ring chain 4 which is wound around the main drive roller 3 rotated by the driving force of the drive unit 2 and circulates while passing through the feed pipe line a. The waste supplied to 10 is discharged to the conveying outlet 1 while passing through the inside of the conveying pipeline (a). At this time, the conveying pipe ring chain (4) passes through each curved surface (b) and has a guide roller installed therein ( 7) by being moved in a third space (a) (b), as shown in Figure 3 (a) is spaced apart at a predetermined interval from the inner bent portion of the curved surface, so that the friction with the inner wall of the curved portion can be excluded, wear of the feed pipeline (a) It can prolong the life by preventing damage and induce smooth movement.

On the other hand, as shown in FIG. 3 (a), the ring chain 4 is rotated by 180 ° so that the ring chain 4 passes through the curved surface of the shape, that is, the reverse bending surfaces b1 and b2 having opposite bending directions. The transfer disc 5 of the ring chain 4 diagonally spanning the guide roller 7 provided between the reverse bending surfaces b1 and b2, which is possible only when the position of the transfer disc 5 in the pipeline a is changed. ) Is rotated toward the bottom center of the feed pipe line (a) as the position of the center of gravity is changed by its own weight while passing through one side reverse curved surface (b1), and the ring chain (4) is gradually twisted and the other side When the reverse bending surface b2 is reached, as shown in FIG. 5, the ring chain 4 is twisted 180 degrees, and the position of the transfer disc 5 is changed to the opposite position.

Meanwhile, when the ring chain 4 passes through the reverse bending surfaces b1 and b2 while twisting, the ring chain 4 is moved in friction contact with the arc inner surface of the curved induction plate 6. ), The clearance space between the ring chain 4 and the inner surface of the feed pipeline (a) is generated when the ring chain 4 is twisted, and when the supply amount of waste is not constant, Due to the loss of the position fixing function according to its own weight, excessive twisting of the ring chain 4 occurs, which results in cutting of the ring chain 4 or damage conveying pipe of the driving unit 2 due to reduction of the overall length of the ring chain 4. In order to prevent such damage due to friction with the inner wall of the line (a), the curved induction plate 6 is symmetrical between the reverse bending surfaces b1 and b2 as shown in FIG. Installation so as to be connected in a state that the clearance space between the ring chain (4) and the inner surface of the feed pipeline (a) By eliminating it, the ring chain 4 can be twisted while being in contact with the arc inner surface of the curved guide plate 6, thereby suppressing stepless flow due to frictional force, so that excessive twisting over the proper range will not occur even if the supply of waste is not constant. It is.

At this time, the contact surface of the curved guide plate 6 is to be located in the center of the straight distance between the two guide rollers (7).

On the other hand, as shown in (b) of FIG. 3, in the curved surface b having the same bending direction among the transfer pipe lines a, the torsion of the ring chain 4 does not occur, and only the guide roller 7 moves smoothly.

On the other hand, the ring chain (4) twisted while passing through the reverse bending surfaces (b1) and (b2) is naturally loosened slowly while circulating the feed pipeline (a), so that no continuous twisting occurs.

Claims (1)

A drive unit (2) installed at a feed discharge port (1) side of a known feed pipe line (a) having curved surfaces (b) of various angles and including a main drive roller (3); A ring chain (4) installed in a continuous state over the entire length of the conveying pipeline (a) and wound on the main drive roller (3) to be forced to continuously rotate; A plurality of transfer discs 5 fixedly installed at fixed intervals on the ring chain 4; It is installed on the inner side of the curved surface (b) of the conveying pipe line (a) and is provided with a guide roller (7) for preventing the smoothness and friction of movement in the curved surface (b) portion of the ring chain (4) In the structure of; Among the curved surfaces (b) of the conveying pipe line (a), diagonally alternately connected to the upper surface inside the straight portion between the reverse bending surfaces (b1) and (b2) in which the mutual bending directions are opposite to each other, and the conveying pipeline (a) Chain conveying device of the conveying pipeline, characterized in that it is provided with a coupling of the curved surface guide plate (6) of the arc-shaped cross section to exclude the play between the inner surface and the ring chain (4).