KR101289167B1 - Belt Conveyor Chute Sliding Impact device - Google Patents

Abstract

The present invention relates to an apparatus for supporting a lower belt of a belt conveyor chute and a conveyor belt shock alleviation stand comprising a belt support on top of the apparatus and a fluid supply in the interior of the apparatus. By reducing the impact of the belt due to the falling load of minerals and the sagging of the belt, the time and cost required to reduce the rate of falls and to prevent environmental pollution due to the scattering of the falls, You can expect the effect to save.

Description

Belt Conveyor Chute Sliding Impact device

The present invention relates to a stand for mitigating impact occurring on a lower belt of a belt conveyor chute, and more specifically, to install a device to support a lower belt, and the upper part of the apparatus is a drop load of transported goods from the upper chute to the lower chute. The belt support and the belt support designed to take into account the deflection of the lower belt due to the fluid supply to the belt support by allowing the belt support and the lower belt to proceed smoothly without friction to provide a shock caused by the lower belt and the deflection It is about a stand that alleviates.

In general, the transfer of raw materials used in steel mills uses a belt conveyor. At this time, a plurality of belt conveyors are combined to form a long distance transportation.

In the case of the belt conveyor chute 1, minerals, coke, etc. are transferred from the upper belt 4 to the lower belt 5 through the chute 2. At this time, in order to prevent the fall 8, the side skirt 3 etc. are provided in the lower part of the chute 2. As shown in FIG.

However, in the case of the conventional belt conveyor chute 1, the lower belt 5 is impacted in the process of falling ore from the upper belt 4 to the lower belt 5, so that the lower belt is bent.

At this time, although the roller 6 and the stand 7 were installed in the lower part in order to alleviate the falling load of the ore falling on the lower belt 5, the belt deflection 9 continued to be generated by the drop load due to the gap. do.

As a result, a space is generated between the side skirt 3 and the lower belt 5 to cause a fall light 8 through the space.

This not only causes environmental problems that pollute the environment of the fallen surrounding area, but also causes a problem that requires additional work to deal with the dropped transportation.

The present invention is to solve the problems as described above, the device is installed to support the lower belt of the belt conveyor chute and the belt support designed in a shape in consideration of the bending of the lower belt and the belt support to supply the fluid to the lower belt and By providing a fluid supply to reduce the frictional force that may occur between the belt support to allow the lower belt to proceed smoothly, to prevent the falling of the ore to prevent environmental pollution and to reduce the time and cost of treating the dropped ore It aims to reduce.

The present invention provides a belt conveyor chute shock absorbing device as follows to achieve the above object.

An apparatus 200 provided to support a conveyor belt on the underside of the belt conveyor chute and a belt support 300 provided to alleviate the sagging of the belt due to the drop load of the transport material placed on the upper portion of the apparatus 200 and falling through the chute. And a fluid supply unit 400 located inside the apparatus 200 and provided to reduce friction between the belt support 300 and the belt.

More preferably, the belt support portion may be composed of a central portion formed in a horizontal plane and a lead portion formed in an inclined surface on both sides of the central portion.

The fluid supply unit includes two injection nozzles located at the center portion for injecting fluid to the belt support portion and one injection nozzle located at the inclined portion, and a structure pipe for supplying fluid to the nozzles inside the main body. And a main pipe positioned on both sides of the main body and supplying a fluid to the structural pipe.

In addition, a plurality of the stand may be provided including a connection block on the left side and a connection holder on the right side of the main body to enable the connection.

The stand may include a fluid filtration unit for filtering the fluid collected by the collection unit.

More preferably, the collecting part may include a collecting tank for collecting the used fluid and a collecting pipe for transferring the fluid collected in the collecting tank to the fluid filtering unit.

The present invention supports the lower belt of the belt conveyor chute through the configuration as described above to prevent the lower belt from sagging due to the falling load of the ore and there is an effect that can suppress the fall.

In addition, by suppressing falling lights, not only can it prevent environmental pollution that can occur due to scattering of ore, but also save time and cost for treating scattered ore, and can increase the overall production efficiency. .

1 is a schematic diagram of a conventional belt conveyor chute.
Figure 2a is a left perspective view of the stand of the present invention.
2B is a right perspective view of the stand of the present invention.
Figure 2c is a perspective view of the present invention combined the stand.
Figure 3a is a cutaway side view of the stand of the present invention.
Figure 3b is a cutaway view showing the welding state of the fluid supply unit of the present invention stand.
Figure 4 is an overall configuration showing the operation and circulation of the fluid of the present invention.
Figure 5 is a perspective view of a belt conveyor chute equipped with the present inventors belt conveyor chute shock alleviation stand.

Hereinafter, a specific embodiment of the present invention will be described with reference to the accompanying drawings.

2A and 2B are left and right perspective views of the stand 100 of the present invention, and FIG. 2C is a perspective view of the stand 100 coupled to the present invention, and FIG. 3 is a cutaway side view of the stand 100 of the present invention. Is shown.

2A and 2B, the conveyor belt shock alleviation stand 100 includes a device 200 for supporting a lower belt, and a belt support 300 and an upper portion of the device 200. It consists of a fluid supply part 400 located inside.

Here, the belt support 300 is designed in consideration of the falling load of the transport object received by the lower belt 5 in the process of transporting the transport from the upper chute (4) to the lower chute (5), specifically, the belt The central portion 310 of the support portion 300 forms a horizontal plane and there is a lead portion 320 having inclined surfaces on both sides of the central portion.

This is a range in which the center portion of the lower belt 5 falls under the falling load and the left and right sides of the lower belt 5 are lifted up when transports such as ore and coke fall into the lower belt 5. Considered.

Accordingly, even if the lower belt 5 is deformed under the drop load of the transport material, the central portion 310 of the belt support portion supports the lower belt 5, thereby alleviating the deflection of the lower belt 5 and reducing the belt support portion. The lead portion 320 supports the left and right sides of the lower belt 5, thereby preventing the fall of light from occurring between the space caused by the sagging phenomenon of the side skirt 3 and the lower belt 5.

In addition, referring to Figures 2a and 2b, the fluid supply unit 400 is configured inside the conveyor belt shock alleviation stand 100, specifically, the main portion of the outer surface central portion of the lead portion 320 of the belt support portion There is a pipe connector 440 that can be connected to the pipe 410 to receive the fluid, the structural pipe 430 which is a line through which the fluid is supplied through the pipe connector 440 is designed in the interior of the stand 100 It is. The structural pipe 430 flows horizontally in the pipe connector 440 and is bent along the inclined surface of the lead portion 320 of the belt support, and is horizontally configured again in the central portion 310 of the belt support.

The structure of the structural pipe 430 as described above is related to the position of the nozzle 420 for injecting a fluid connected to the surface of the belt support 300. In detail, two nozzles 420 are positioned at the central portion 310 of the belt support, and one nozzle 420 is positioned at the lead portion 320 of the belt support. In order to supply smoothly, the structure pipe 430 is configured to flow in a horizontal or inclined direction according to the position of the nozzle 420.

Here, the position of the nozzle 420 is to consider the form in which the fluid is injected in order to reduce the friction force that may occur between the lower belt 5 and the belt support portion 300 for supporting the lower belt (5). That is, the two nozzles 420 of the central portion 310 of the belt support reduce friction due to contact with the central portion 310 of the belt support when the lower belt 5 is sagging under the drop load of the shipment. By spraying fluid from the two nozzles 420 to form a film, an oil film is formed to prevent direct contact between the lower belt 5 and the central portion 310 of the belt support, thereby reducing friction.

Further, each nozzle 420 located in the lead portion 320 of the belt support portion injects fluid to the left and right sides of the lower belt 5 to prevent direct contact with the lead portion 320 of the belt support portion. The frictional force is reduced to allow the lower belt 5 to move easily in the moving direction.

Structural pipe 430 of the fluid supply unit 400 formed in the stand 100 as described above is processed through a drill. Referring to Figure 3b first by a predetermined value for the horizontal structural pipe 430 A hole is drilled to form a length, and a hole is formed according to a predetermined value to a range in which a structural pipe is formed in a horizontal direction in accordance with an inclination angle on the belt support 320. When the structural pipe is formed on both sides, The casting is used to fill a portion other than the structure pipe 430. Then, the portion in which the fixing groove 230 is formed is welded to form the fluid supply part 400.

 Also, referring to FIGS. 2A and 2B, there is a connection block 210 drawn out below the center of the left side of the stand 100, and a connection holder recessed into the center of the right side of the stand 100. There is 220. This provides a structure in which a plurality of stands 100 can be connected. Referring to FIG. 2C, a structure in which two stands 100 are connected may be examined. That is, when the connection block 210 of the left side of one stand 100 is coupled to the connection holder 220 of the right side of the other stand 100, a more extended stand 100 may be provided. However, this is only one embodiment and it will be readily understood that a plurality of stands 100 may be connected according to the size of the belt conveyor lower chute.

2A and 2B, fixing grooves 230 exist at both side horizontal portions of the main body. The fixing groove 230 is coupled to the frame 10 by using bolts, screws, etc. to position the stand 100 to support the lower belt 5.

Figure 4 is a general diagram showing the operation of the present invention and the circulation of the fluid.

Referring to FIG. 4, first, the working fluid is provided to the fluid supply unit 400 through the main pipe 410 located at the left and right sides of the stand 100 and connected to the pipe connector 440 on the stand 100. do. In addition, the fluid moves along the structure pipe 430 of the fluid supply part 400 such that the fluid is supplied to the nozzle 420 connected to the belt support part 300.

As described above, two nozzles 420 are positioned at the central portion 310 of the belt support portion and one at the discharge portion 320, and the fluid is injected into the upper portion of the belt support portion 300. The injected fluid forms an oil film between the belt support 300 and the lower belt 5 of the belt conveyor chute. This oil film serves to reduce friction between the belt support 300 and the belt support 300 designed to reduce the deflection of the lower belt 5 and the lower belt 5. That is, by blocking direct contact between the lower belt 5 and the belt support 300, the lower belt 5 can move smoothly without friction.

Here, the fluid used to form the oil film flows along the moving direction of the lower belt 5. Since only the lower belt 5 moves while the stand 100 is fixed, the direction in which the used fluid flows will be the moving direction of the lower belt 5.

 In addition, a collecting part 500 is provided below the side surface of the stand 100 in the moving direction of the lower belt 5. This is to form an oil film and to collect the used fluid again. The used fluid flows in the direction of movement of the lower belt 5 and is contained in a collecting tank 510 located below the stand 100 at the end of the belt support 300 of the stand.

Here, the upper portion of the sump 510 may cover the whole of both sides of the belt support 300 so that the fluid may be collected in the sump 510, and the lower portion of the sump 510 gradually It is provided to be narrowed to move through the collecting pipe (520).

The fluid is moved to the fluid filtration unit 600 through the collecting pipe 520. Here, the fluid filtration unit 600 includes a filtration means 610 for separating the mineral and the fluid, a float valve 680 for supplying insufficient fluid, and the filtered fluid to the fluid supply unit 400 through the main pipe 440. It is configured to include a pump 670 to deliver.

In detail, the fluid moved through the collecting pipe 520 is collected in the collecting container 620 on the fluid filtering part 600. In addition, primary precipitation of the mineral occurs in the collecting container 620, and the fluid that has undergone the primary precipitation process moves to the filtration tank 630. Next, after the second precipitation occurs in the second stage of the filtration tank 630, the fluid which has undergone the second precipitation process through the porous filter medium 640 located between the second and second stages is moved from the second stage to the second stage. . When the fluid fills the filtration tank 630 in the first stage, the fluid moves to the first stage beyond the boundary membrane 650 of the first and second stages.

At this time, the fluid that is discharged with the sediment during the first and second sedimentation process is insufficient to replenish through the float belt (680). The filtration fluid and the fluid supplemented through the float valve 680 are supplied to the pump 670 through the intake valve 660, and drive the pump 670 to return the fluid to the main pipe 440. Will be provided.

The belt conveyor chute shock alleviation stand 100 of the present invention through the circulation process as described above is to operate.

5 is a perspective view of a belt conveyor chute equipped with a belt conveyor chute shock alleviating stand 100 according to the present invention. Practically, the stand 100 may observe the form of supporting the lower belt 5 of the belt conveyor chute.

Here, in FIG. 5, the roller 6 and the roller stand 7 located on the front of the stand 100 are omitted in order to clearly show the stand 100, and the roller 6 and the stand only on the rear side of the stand 100. (7) is shown.

Referring to Figure 5, the stand 100 is positioned below the lower belt 5 between the roller 6 and the roller stand 7 supporting the lower belt 5 on both sides. The fixing groove 230 of the stand 100 is fixed to the frame 10 through coupling holes such as bolts and screws. In addition, it is possible to check the specific position of the collecting portion 500 between the frame 10 and in the moving direction of the lower belt 5. In other words, it can be considered that the oil film 700 is formed and the used fluid flows toward the movement direction of the lower belt 5 and is collected by the collecting part 500. And the line of the collecting pipe 520 or the main pipe 440 is shown, which is a schematic display, the direction of the line can be changed according to the specific equipment.

This practice alleviates the deflection of the lower belt 5 of the belt conveyor chute, preventing the fall of light that may occur between the side skirt 3 and the lower belt 5, and the time taken to process scattered ore. It can be expected to save money and cost.

The foregoing merely illustrates specific embodiments of the conveyor belt impact relief stand.

Therefore, it should be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. do.

Conveyor Belt Shock Relief Stand 200 ...
210 ... Connection block 220 ... Connection holder
230 ... fixed groove 300 ... belt support
310 ... center part of belt support 320 ... inclined part of belt support
400 Fluid supply part 410 Main pipe
420 Nozzle 430 Rescuer
440 pipe connection 500
510 ... oil tank 520 ... oil pipe
600 fluid filtration 610 filtration means
620 ... distribution tank 630 ... filtration tank
640 porous filter media 650
660 ... Suction valve 670 ... Pump
680 float valve 700 oil film

Claims (7)

An apparatus 200 provided to support the conveyor belt on the underside of the chute for the belt conveyor; Wow
A belt support part 300 positioned above the apparatus 200 and provided to alleviate the sagging of the belt due to the falling load of the transport object falling through the chute; And
A fluid supply 400 located inside the apparatus 200 and provided to reduce friction between the belt support 300 and the belt;
Including but not limited to:
The belt support portion 300 is composed of a central portion 310 made of a horizontal plane and a lead portion 320 formed of inclined surfaces on both sides of the central portion,
The fluid supply unit 400 includes two injection nozzles 420 of the central portion 310 of the belt support portion and one leading portion 320 of the belt support portion for injecting fluid into the belt support portion 300. Injection nozzle 420; And a structural pipe 430 for supplying a fluid to the nozzle 420 inside the device 200. And a main pipe 410 positioned at both sides along the side of the apparatus 200 and supplying fluid to the structural pipe 430.
delete delete The method of claim 1,
Conveyor belt impact relief stand, characterized in that it comprises a connection block 210 and a connection holder 220 on the left side of the device 200, to connect a plurality of the device (200)
The method according to claim 1 or 4,
Conveyor belt impact relief stand, characterized in that further comprises a collecting portion 500 located on the side of the lower belt moving direction of the device 200, collecting the used fluid
The method of claim 5,
The collecting part 500 includes a collecting tank 510 for collecting the used fluid; And a collecting pipe 520 for moving the fluid collected by the collecting tank 500 from the lower portion of the collecting tank 510 to the fluid filtration unit 600.
The method of claim 5,
Conveyor belt impact relief stand characterized in that it comprises a fluid filtration unit 600 for filtering the fluid collected by the collecting unit 500

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