CN210449785U - Mineral separation device for industrial and mining - Google Patents

Abstract

The utility model discloses an industrial and mining division adopts ore dressing device, which comprises a housin, big footpath ore screening cylinder, well footpath ore screening cylinder, the workbin is received to the path ore has been placed to the bottom of path ore export, well footpath ore is received the workbin has been placed to the bottom of well footpath ore drainage board, big footpath ore is received the workbin has been placed to the bottom of big footpath ore drainage board, the wall of big footpath ore screening cylinder is inlayed and is had big footpath ore screening net, the inside welding of big footpath ore screening cylinder left end has branch, the left side fixedly connected with pivot of branch, the first motor of other end fixedly connected with of pivot, the wall of well footpath ore screening cylinder is inlayed and is had well footpath ore screening net, the teeth of a cogwheel have been seted up to the periphery of well footpath. Through a major diameter ore sieve selection section of thick bamboo and middle sieve selection section of thick bamboo, can sieve the ore of equidimension not, and the utility model discloses a nested mode is layer upon layer, simple structure, compactness, utilizes to place, maintain.

Description

Mineral separation device for industrial and mining

Technical Field

The utility model relates to an industrial and mining technical field especially relates to a mineral separation device for industrial and mining.

Background

In the mining process of industrial and mining, the ore that the diameter is not of uniform size can appear, for the convenience of later stage ore processing, all can sieve the ore, and present ore screening mostly uses the shaking table to sieve, and shaking table dressing efficiency is on the low side, and the shaking table volume is comparatively huge, and equipment is complicated, for this reason we have proposed a mining and have adopted ore dressing device to solve the above-mentioned technical problem who provides.

Disclosure of Invention

The utility model provides a current sieving mechanism ore screening efficiency is on the low side that mining exploitation adopted ore dressing device in order to solve above-mentioned background art and provide to it is bulky, the complicated problem of equipment.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a mineral processing device for mining, includes casing, major diameter ore sieve tube, the ore sieve tube of intermediate diameter, its characterized in that, the bottom welding of casing has the landing leg, the export of path ore has been seted up to the bottom of casing, the export of path ore has been placed to the bottom of path ore, the export of intermediate diameter ore has been seted up to the lower extreme of casing right-hand member face, the export welding of intermediate diameter ore export has the ore drainage plate of intermediate diameter, the ore of intermediate diameter is placed to the bottom of intermediate diameter ore drainage plate and is received the workbin, be provided with the major diameter ore drainage plate directly over the ore drainage plate of intermediate diameter, the welding of major diameter ore drainage plate is at the right-hand member face of casing, the ore of major diameter is received the workbin has been placed to the bottom of major diameter ore drainage plate, the rotation of the ore sieve tube of major diameter is set up in the inside of casing, the wall of the ore sieve, the inside welding of big footpath ore sieve tube left end has branch, the left side fixedly connected with pivot of branch, the first motor of other end fixedly connected with of pivot, the fixed conveyer belt that is provided with of left end face of big footpath ore sieve tube, well footpath ore sieve tube rotates and sets up between big footpath ore sieve tube and casing, the wall of well footpath ore sieve tube is inlayed and is had well footpath ore sieve screen, the teeth of a cogwheel have been seted up to the periphery of well footpath ore sieve tube left end, the top meshing of the teeth of a cogwheel has the driving gear, the upper end of driving gear runs through casing and fixedly connected with second motor, the junction of big footpath ore sieve tube, well footpath ore sieve tube and casing is inlayed and is had the roller.

Furthermore, the rollers are distributed symmetrically and uniformly in the center by taking the axis of the shell as the center of a circle.

Further, the shell is arranged in a downward inclined mode.

Furthermore, the mesh diameter of the large-diameter ore screening net is larger than that of the medium-diameter screening net.

Furthermore, the power input ends of the first motor and the second motor are electrically connected with an external power supply, and are provided with control switches in a matching manner.

Compared with the prior art, the utility model discloses the beneficial effect who realizes:

through a major diameter ore sieve selection section of thick bamboo and middle sieve selection section of thick bamboo, can sieve the ore of equidimension not, and the utility model discloses a nested mode is layer upon layer, simple structure, compactness, utilizes to place, maintain.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a partially enlarged schematic view of a portion a of fig. 1 according to the present invention.

Fig. 3 is the side structure schematic diagram of the large-diameter ore screening cylinder of the present invention.

In FIGS. 1-3: 1-shell, 101-supporting legs, 102-small-diameter ore outlet, 103-medium-diameter ore outlet, 104-medium-diameter ore flow guide plate, 105-large-diameter ore flow guide plate, 2-large-diameter ore screening cylinder, 201-large-diameter ore screening net, 202-supporting rod, 203-rotating shaft, 204-first motor, 3-medium-diameter ore screening cylinder, 301-medium-diameter ore screening net, 302-gear teeth, 303-driving gear, 304-second motor, 4-conveying belt, 5-roller, 6-small-diameter ore collecting box, 7-medium-diameter ore collecting box and 8-large-diameter ore collecting box.

Detailed Description

The following description is provided for illustrative purposes, and other advantages and features of the present invention will become apparent to those skilled in the art from the following detailed description.

It should be understood that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limit conditions that the present invention can be implemented, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the scope that the technical content disclosed in the present invention can cover without affecting the function that the present invention can produce and the purpose that the present invention can achieve. Meanwhile, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for convenience of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof may be made without substantial technical changes, and the present invention is also regarded as the scope of the present invention.

Please refer to fig. 1 to 3:

the utility model provides a mineral separation device for industrial and mining, which comprises a shell 1, a large-diameter ore screening cylinder 2 and a medium-diameter ore screening cylinder 3, wherein each part of the mineral separation device for industrial and mining is described in detail below;

the bottom of the shell 1 is welded with the supporting legs 101, the bottom of the shell 1 is provided with a small-diameter ore outlet 102, the bottom of the small-diameter ore outlet 102 is provided with a small-diameter ore collecting box 6, the lower end of the right end face of the shell 1 is provided with a medium-diameter ore outlet 103, an outlet of the medium-diameter ore outlet 103 is welded with a medium-diameter ore drainage plate 104, the bottom of the medium-diameter ore drainage plate 104 is provided with a medium-diameter ore collecting box 7, a large-diameter ore drainage plate 105 is arranged right above the medium-diameter ore drainage plate 104, the large-diameter ore drainage plate 105 is welded on the right end face of the shell 1, and a large-diameter ore collecting box 8 is;

specifically, the small-diameter ore outlet 102 can discharge small-diameter ores from the shell 1 and automatically fall into the small-diameter ore receiving box 6, the medium-diameter ore outlet 103 can discharge screened medium-diameter ores out of the shell 1, the medium-diameter ore flow guide plate 104 can guide ores and discharge the ores into the medium-diameter ore receiving box 7, and the large-diameter ore flow guide plate 105 can guide large-diameter ores and discharge the large-diameter ores into the large-diameter ore receiving box 8;

the large-diameter ore screening cylinder 2 is rotatably arranged inside the shell 1, a large-diameter ore screening net 201 is inlaid on the wall surface of the large-diameter ore screening cylinder 2, a supporting rod 202 is welded inside the left end of the large-diameter ore screening cylinder 2, a rotating shaft 203 is fixedly connected to the left side of the supporting rod 202, a first motor 204 is fixedly connected to the other end of the rotating shaft 203, and a conveying belt 4 is fixedly arranged on the left end surface of the large-diameter ore screening cylinder 2;

specifically, the first motor 204 can drive the large-diameter ore screening cylinder 2 to rotate in the shell 1 through the rotating shaft 203 and the supporting rod 202, the conveying belt 4 can pour unscreened ores into the large-diameter ore screening cylinder 2, then the rotating large-diameter ore screening cylinder 2 screens the ores through the large-diameter ore screening net 201, during screening, some small and medium-diameter ores can fall onto the medium-diameter screening cylinder 3 from the large-diameter ore screening net 201, and the rest large-diameter ores can slide into the large-diameter ore drainage plate 105 from the right end of the large-diameter ore screening cylinder 2, and then the large-diameter ores are guided into the large-diameter ore receiving box 8 through the large-diameter ore drainage plate 105;

as described above, the intermediate-diameter ore screening cylinder 3 is rotatably disposed between the large-diameter ore screening cylinder 2 and the housing 1, the wall surface of the intermediate-diameter ore screening cylinder 3 is inlaid with the intermediate-diameter ore screening net 301, the periphery of the left end of the intermediate-diameter ore screening cylinder 3 is provided with gear teeth 302, the upper portion of the gear teeth 302 is engaged with the driving gear 303, and the upper end of the driving gear 303 penetrates through the housing 1 and is fixedly connected with the second motor 304;

specifically, the middle and small-diameter ores falling from the large-diameter ore screening net 201 fall into the middle-diameter ore screening cylinder 3, the middle-diameter ore screening cylinder 3 can be driven to rotate in the shell 1 through the meshing of the driving gear 303 and the gear teeth 302 by the second motor 304, the rotating middle-diameter ore screening cylinder 3 can further screen the ores by using the middle-diameter ore screening net 301, when the ores are screened, some small-diameter ores in the ores fall downwards from the middle-diameter ore screening net 301, then the small-diameter ores fall onto the shell 1, then the small-diameter ores slide into the small-diameter ore outlet 102 and fall into the small-diameter ore receiving box 6, the middle-diameter ores on the middle-diameter ore screening net 301 slide down from the middle-diameter ore screening cylinder 3 and are discharged out of the shell 1 through the middle-diameter ore outlet 103, and then the middle-diameter ores are discharged into the middle-diameter ore receiving box 7 through the middle-diameter ore drainage plate 105;

the junction of the large-diameter ore screening cylinder 2, the medium-diameter ore screening cylinder 3 and the shell 1 is inlaid with a roller 5, the large-diameter ore screening cylinder 2 and the medium-diameter ore screening cylinder 3 can rotate in the shell 1 through the roller 5, and the effect of the large-diameter ore screening cylinder and the medium-diameter ore screening cylinder is equal to that of a rolling bearing.

To sum up, when making the utility model discloses the use: unscreened ore is conveyed to the large-diameter ore screening cylinder 2 by the conveyor belt 4, then the rotating large-diameter ore screening cylinder 2 screens the ore by the large-diameter ore screening net 201, during screening, some small-diameter ore falls from the large-diameter ore screening net 201 onto the medium-diameter screening cylinder 3, and the rest large-diameter ore slides into the large-diameter ore drainage plate 105 from the right end of the large-diameter ore screening cylinder 2, then the large-diameter ore drainage plate 105 guides the large-diameter ore into the large-diameter ore receiving box 8, and the small-diameter ore falling into the medium-diameter ore screening cylinder 3 can be further screened by the rotating medium-diameter ore screening cylinder 3 by the medium-diameter ore screening net 301, during screening, some ore in the ore can fall from the medium-diameter ore screening net 301, then the small-diameter ore falls onto the shell 1, then the small-diameter ore slides into the small-diameter ore outlet 102 and falls into the ore receiving box 6, the medium-diameter ore on the medium-diameter ore screening net 301 slides down from the medium-diameter ore screening cylinder 3 and is discharged out of the shell 1 through the medium-diameter ore outlet 103, and then the medium-diameter ore is discharged into the medium-diameter ore collecting box 7 through the medium-diameter ore flow guide plate 105, so that the layer-by-layer screening of the ore is completed.

The above embodiments are merely illustrative of the principles and effects of the present invention, and are not to be construed as limiting the invention. Modifications and variations can be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (5)

1. The utility model provides an ore dressing device for industrial and mining exploitation, includes casing (1), major diameter ore sieve tube (2), pitch diameter ore sieve tube (3), its characterized in that:

the supporting legs (101) are welded at the bottom of the shell (1), a small-diameter ore outlet (102) is formed in the bottom of the shell (1), a small-diameter ore collecting box (6) is placed at the bottom of the small-diameter ore outlet (102), a medium-diameter ore outlet (103) is formed in the lower end of the right end face of the shell (1), a medium-diameter ore drainage plate (104) is welded at the outlet of the medium-diameter ore outlet (103), a medium-diameter ore collecting box (7) is placed at the bottom of the medium-diameter ore drainage plate (104), a large-diameter ore drainage plate (105) is arranged right above the medium-diameter ore drainage plate (104), the large-diameter ore drainage plate (105) is welded at the right end face of the shell (1), and a large-diameter ore collecting box (8) is placed at the bottom of the large-diameter ore drainage;

the large-diameter ore screening cylinder (2) is rotatably arranged inside the shell (1), a large-diameter ore screening net (201) is inlaid in the wall surface of the large-diameter ore screening cylinder (2), a support rod (202) is welded inside the left end of the large-diameter ore screening cylinder (2), a rotating shaft (203) is fixedly connected to the left side of the support rod (202), a first motor (204) is fixedly connected to the other end of the rotating shaft (203), and a conveying belt (4) is fixedly arranged on the left end surface of the large-diameter ore screening cylinder (2);

the middle-diameter ore screening drum (3) is rotatably arranged between the large-diameter ore screening drum (2) and the shell (1), a middle-diameter ore screening net (301) is inlaid in the wall surface of the middle-diameter ore screening drum (3), gear teeth (302) are formed in the periphery of the left end of the middle-diameter ore screening drum (3), a driving gear (303) is meshed above the gear teeth (302), and the upper end of the driving gear (303) penetrates through the shell (1) and is fixedly connected with a second motor (304);

rollers (5) are embedded at the connecting parts of the large-diameter ore screening cylinder (2), the medium-diameter ore screening cylinder (3) and the shell (1).

2. The ore dressing device according to claim 1, wherein: the rollers (5) are uniformly distributed in a centrosymmetric manner by taking the axis of the shell (1) as a circle center.

3. The ore dressing device according to claim 1, wherein: the shell (1) is arranged in a downward inclined mode.

4. The ore dressing device according to claim 1, wherein: the mesh diameter of the large-diameter ore screening net (201) is larger than that of the medium-diameter ore screening net (301).

5. The ore dressing device according to claim 1, wherein: the power input ends of the first motor (204) and the second motor (304) are electrically connected with an external power supply, and are provided with control switches in a matching manner.

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