CN218925260U - Mining is with circulating filter - Google Patents

Abstract

The utility model discloses a mining circulating filter, which comprises a vibrating machine, wherein the output end of the vibrating machine is connected with a vibrating shaft, the outer side surface of the vibrating shaft is sequentially provided with a primary filtering shell and a secondary filtering shell from top to bottom, and the bottoms of the inner side surfaces of the primary filtering shell and the secondary filtering shell are respectively provided with a cone core mirror plate, so that ores can be continuously and efficiently filtered, the filtering efficiency and the filtering quality are effectively improved, meanwhile, the secondary filtering of the ores is improved, and the waste of resources is effectively avoided; ore materials needing sieving are conveyed to the middle of the first-stage filtering shell through an external belt conveyor, the vibrating machine is started to drive the vibrating shaft to work, the vibrating shaft drives the first-stage filtering shell and the second-stage filtering shell to vibrate, the materials inside the first-stage filtering shell gradually diffuse towards the edge along the spiral linear guide plate, fine materials enter the circular receiving disc, and coarse materials enter the second-stage filtering shell through the guide pipe.

Description

Mining is with circulating filter

Technical Field

The utility model relates to the technical field of mineral separation filters, in particular to a circulating filter for mining.

Background

In the mineral exploitation process, mineral separation and ore washing are needed, a filter is needed to be used for filtering in the mineral separation and ore washing processes, and when the existing disc type mineral separation filter is used, ore is fed from the middle part of a vibration disc. After the unloading, owing to vibrations of vibrations dish, the edge of vibrations dish can be moved to the ore to pile up at the edge of vibrations dish, cause raw materials and vibrations net contact time to shorten, the ore raw materials hardly fully filters, and current disc filter can only once filter the raw materials simultaneously, and filter effect is not good when the unloading speed is very fast.

Disclosure of Invention

The utility model aims to overcome the existing defects, and provides the circulating filter for mining, which can continuously and efficiently filter ores, effectively improve the filtering efficiency and the filtering quality, simultaneously improve the secondary filtering of the ores, effectively avoid the waste of resources and effectively solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a mining is with circulating filter, includes the vibrating machine, and the output of vibrating machine is connected with the vibration axle, the lateral surface of vibration axle is equipped with one-level filter housing and second grade filter housing from last down in proper order, one-level filter housing and second grade filter housing's medial surface bottom all is equipped with the cone core mirror panel.

The upper surface of the cone core mirror panel is provided with filter meshes, the upper surface of the cone core mirror panel is provided with spiral line type guide plates, the number of the spiral line type guide plates is two, the two spiral line type guide plates are a spiral line type guide plate I and a spiral line type guide plate II respectively, the spiral line type guide plate I is arranged in the first-stage filter shell, and the spiral line type guide plate II is arranged in the second-stage filter shell.

The inner side surface of the primary filtering shell is provided with a discharging opening near the tail end of the spiral line type guide plate, the discharging opening is connected with a guide pipe, and the tail end of the guide pipe is arranged at the center of the secondary filtering shell.

Preferably, the height of the outer side surface of the conical mirror plate is gradually reduced from the middle to the edge.

Preferably, the lower surfaces of the primary filtering shell and the secondary filtering shell are respectively provided with a round receiving disc.

Preferably, the round receiving tray is obliquely arranged, the edge of the upper surface of the round receiving tray is provided with an anti-overflow plate, and the lowest end of the outer side surface of the round receiving tray is provided with a fine material outlet.

Preferably, the outer side surface of the secondary filtering shell is provided with a slag discharging port close to the tail end of the spiral line type guide plate II.

Compared with the prior art, the utility model has the beneficial effects that: the mining circulating filter has the following advantages:

1. the ore can be continuously and efficiently filtered, the filtering efficiency and the filtering quality are effectively improved, and meanwhile, the secondary filtering of the ore is improved, so that the waste of resources is effectively avoided;

2. ore materials needing sieving are sent to the middle part of the first-stage filtering shell through an external belt conveyor, the vibrating machine is started to drive the vibrating shaft to work, the vibrating shaft drives the first-stage filtering shell and the second-stage filtering shell to vibrate, materials inside the first-stage filtering shell gradually diffuse towards the edge along the first spiral line type guide plate, fine materials enter the circular receiving disc, coarse materials enter the second-stage filtering shell through the guide pipe, coarse materials gradually diffuse towards the edge along the second spiral line type guide plate inside the second-stage filtering shell, and slag is finally discharged through a slag discharge port.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a front view of the present utility model;

fig. 3 is a top view of the present utility model.

In the figure: the device comprises a first-stage filtering shell, a second-stage filtering shell, a 3-vibration machine, a 4-round receiving disc, a 5-flow guide pipe, a 6-fine material outlet, a 7-slag discharge port, an 8-vibration shaft, a 9-spiral linear guide plate, a 10-feed port and an 11-cone core mirror panel.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-3, the present utility model provides a technical solution: the utility model provides a mining circulation filter, includes vibrating machine 3, and vibrating machine 3's output is connected with vibration axle 8, and vibration axle 8's lateral surface is equipped with one-level from last down in proper order and filters casing 1 and second grade and filter casing 2, and one-level is filtered casing 1 and second grade and is filtered casing 2's medial surface bottom and all is equipped with cone core mirror panel 11.

Specifically, the ore materials needing to be screened are conveyed to the middle of the first-stage filtering shell 1 through an external belt conveyor, the vibrating machine 3 is started to drive the vibrating shaft 8 to work, and the vibrating shaft 8 drives the first-stage filtering shell 1 and the second-stage filtering shell 2 to vibrate.

The upper surface of the cone core mirror panel 11 is provided with filter meshes, the upper surface of the cone core mirror panel 11 is provided with spiral line type guide plates 9, the number of the spiral line type guide plates 9 is two, the two spiral line type guide plates 9 are respectively a spiral line type guide plate I and a spiral line type guide plate II, the spiral line type guide plate I is arranged in the primary filter shell 1, and the spiral line type guide plate II is arranged in the secondary filter shell 2.

Specifically, the material inside the primary filtering shell 1 gradually diffuses towards the edge along the first spiral guide plate, the fine material enters the circular receiving tray 4, the coarse material enters the secondary filtering shell 2 through the guide pipe 5, the coarse material gradually diffuses towards the edge along the second spiral guide plate inside the secondary filtering shell 2, and the slag is finally discharged through the slag discharge port 7

The inner side of the primary filtering shell 1 is provided with a blanking opening 10 near the tail end of the spiral line type guide plate 9, the blanking opening 10 is connected with a guide pipe 5, and the tail end of the guide pipe 5 is arranged at the center of the secondary filtering shell 2.

Further, the height of the outer side of the axicon panel 11 becomes gradually lower from the middle to the edge.

In particular, the axicon panel 11 facilitates the diffusion of material from the center to the edges.

Further, the lower surfaces of the primary filtering shell 1 and the secondary filtering shell 2 are respectively provided with a round receiving disc 4.

Specifically, the round receiving tray 4 can collect the materials produced in the vibration process.

Furthermore, the round receiving tray 4 is obliquely arranged, the edge of the upper surface of the round receiving tray 4 is provided with an anti-overflow plate, and the lowest end of the outer side surface of the round receiving tray 4 is provided with a fine material outlet 6.

Specifically, the circular material receiving tray 4 which is obliquely arranged facilitates the discharge of materials.

Further, the outer side surface of the secondary filtering shell 2 is provided with a slag discharging port 7 near the tail end of the spiral line type guide plate II.

Specifically, slag can be discharged through the slag discharge opening 7.

When in use: ore materials needing sieving are conveyed to the middle of the first-stage filtering shell 1 through an external belt conveyor, the vibrating machine 3 is started to drive the vibrating shaft 8 to work, the vibrating shaft 8 drives the first-stage filtering shell 1 and the second-stage filtering shell 2 to vibrate, materials inside the first-stage filtering shell 1 gradually diffuse towards the edge along the first spiral line type guide plate, fine materials enter the circular receiving disc 4, coarse materials enter the second-stage filtering shell 2 through the guide pipe 5, coarse materials gradually diffuse towards the edge along the second spiral line type guide plate inside the second-stage filtering shell 2, and slag is finally discharged through the slag discharge port 7.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a mining circulation filter, includes vibrating machine (3), and the output of vibrating machine (3) is connected with vibration axle (8), its characterized in that: the outer side surface of the vibration shaft (8) is sequentially provided with a primary filtering shell (1) and a secondary filtering shell (2) from top to bottom, and the bottoms of the inner side surfaces of the primary filtering shell (1) and the secondary filtering shell (2) are respectively provided with a cone-core mirror panel (11);

the upper surface of the cone core mirror panel (11) is provided with filter meshes, the upper surface of the cone core mirror panel (11) is provided with spiral line type guide plates (9), the number of the spiral line type guide plates (9) is two, the two spiral line type guide plates (9) are respectively a spiral line type guide plate I and a spiral line type guide plate II, the spiral line type guide plate I is arranged in the first-stage filter shell (1), and the spiral line type guide plate II is arranged in the second-stage filter shell (2);

the inner side surface of the primary filtering shell (1) is provided with a discharging opening (10) near the tail end of the spiral line type guide plate (9), the discharging opening (10) is connected with a guide pipe (5), and the tail end of the guide pipe (5) is arranged at the central part of the secondary filtering shell (2).

2. A mining circulation filter according to claim 1, wherein: the height of the outer side surface of the conical mirror panel (11) gradually becomes lower from the middle to the edge.

3. A mining circulation filter according to claim 1, wherein: the lower surfaces of the primary filtering shell (1) and the secondary filtering shell (2) are respectively provided with a round receiving disc (4).

4. A mining circulation filter according to claim 3, wherein: the round receiving tray (4) is obliquely arranged, an anti-overflow plate is arranged at the edge of the upper surface of the round receiving tray (4), and a fine material outlet (6) is formed in the lowest end of the outer side surface of the round receiving tray (4).

5. A mining circulation filter according to claim 1, wherein: the outer side surface of the secondary filtering shell (2) is provided with a slag discharging port (7) close to the tail end of the spiral line-type guide plate II.

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