CN217568254U - Ore dressing test ore pulp sample separating device - Google Patents

Abstract

The utility model provides a ore dressing test ore pulp divides appearance device, belongs to mineral processing engineering field, the utility model discloses an in-process that solution ore dressing plant carries out flotation test or detection, the ore pulp divides the appearance inhomogeneous, and divides the problem of appearance inefficiency. Comprises a stirring motor, a stirring barrel, an equipment frame body, a sample separation rotating barrel, a sample separation disc, a sample receiving container, a receiving container positioning and placing disc and a rotating barrel motor; the ore pulp sample stirs evenly in the agitator, and the even distribution of the drainage tube of the rotatory bucket of rethread branch appearance is fought in each branch appearance, with a plurality of sample receiving container one-to-ones according to the sign line setting on the receiving container location is placed the dish, distribute the sample that divides the appearance to fight and flow into the sample receiving container that corresponds automatically through the export that divides the appearance fill bottom, through this device, realized dividing the even appearance of target ore pulp sample, divide the appearance representativeness good, also easy to operate.

Description

Ore dressing test ore pulp sample separating device

Technical Field

The utility model belongs to mineral processing engineering field especially relates to a mineral separation test ore pulp divides appearance device.

Background

In the process of carrying out flotation test or detection on ore pulp taken from the site of an ore dressing plant, the ore pulp taken from the site needs to be subjected to sample separation or division, and the ore pulp is subjected to grouping test or detection after the sample separation is carried out to the weight determined by pre-calculation. In order to ensure the accuracy of the test or detection, the sample dividing or reduction process plays a very crucial role, and therefore, how to evenly distribute the ore pulp sample is a key process. The traditional sample dividing method is that large ore pulp samples taken on site are put into a bucket to be stirred, and then are divided into test containers one by a siphon method and weighed, so that the weight of the ore pulp divided by each test container is kept consistent. The method is simple to operate, but sample separation is not uniform enough, particularly, the difference between the samples of the first group and the samples of the last group is large, and the sample separation efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a mineral processing test ore pulp divides appearance device to solve the in-process that the ore dressing plant carries out the flotation test or detects, the ore pulp divides the appearance inhomogeneous, and divides the problem of appearance inefficiency. The utility model discloses the technical scheme who adopts as follows:

a mineral separation test ore pulp sample separation device comprises a stirring motor, a stirring barrel, an equipment frame body, a sample separation rotary barrel, a sample separation disc, a sample receiving container, a receiving container positioning and placing disc and a rotary barrel motor;

the equipment frame body comprises four frame body stand columns distributed at four corners, a first frame body main beam layer, a second frame body main beam layer, a third frame body main beam layer, a fourth frame body main beam layer, a fifth frame body main beam layer, a sixth frame body main beam layer and a seventh frame body main beam layer are sequentially arranged along the frame body stand columns from top to bottom, each frame body main beam layer consists of four main beams, and the four main beams of each frame body main beam layer sequentially connect the four frame body stand columns along the circumferential direction;

the stirring motor is connected with the first frame main beam layer through a stirring motor supporting and fixing frame, a stirring barrel positioning frame is arranged on the inner side of the second frame main beam layer, four cross beams of the stirring barrel positioning frame abut against the periphery of the stirring barrel, a stirring barrel supporting frame is arranged on the inner side of the third frame main beam layer, the bottom wall of the stirring barrel abuts against the stirring barrel supporting frame, a circulating inner barrel is arranged in the middle of the stirring barrel, a plurality of circulating pipes which are obliquely arranged upwards are arranged on the periphery of the circulating inner barrel, a plurality of through holes are formed in the side wall of the circulating inner barrel, the plurality of circulating pipes are communicated with the inner side of the circulating inner barrel in a one-to-one correspondence mode, the top end of the stirring shaft is connected with an output shaft of the stirring motor, the stirring shaft penetrates through the circulating inner barrel and extends to the bottom of the stirring barrel, a rotating gap is formed between the stirring shaft and the circulating inner barrel, a stirring impeller is arranged at the bottom of the stirring barrel, a discharging pipe is arranged at the bottom of the stirring barrel, and a discharging valve is arranged on the discharging pipe;

the sample separating disc is connected with the fourth frame body girder layer through a sample separating disc mounting frame, the receiving container positioning and placing disc is connected with the fifth frame body girder layer through a positioning and placing disc supporting frame, the sample separating disc is provided with a plurality of sample separating hoppers which are uniformly distributed in the circumference, the plurality of sample separating hoppers are sequentially abutted, a plurality of identification lines which are uniformly distributed in the circumference are arranged on the receiving container positioning and placing disc, a plurality of sample receiving containers are arranged on the receiving container positioning and placing disc in a one-to-one correspondence mode according to the identification lines, and the plurality of sample receiving containers are used for bearing outlets of the plurality of sample separating hoppers in a one-to-one correspondence mode;

the bottom of pivot protective barrel links to each other with rotatory bucket motor, rotatory bucket motor supports the mount through rotatory bucket motor and links to each other with sixth support body girder layer, the pivot protective barrel runs through the receiving container location in proper order and places the dish and divide the appearance dish, the pivot protective barrel is placed the dish with the receiving container location and is linked to each other, the output shaft of rotatory bucket motor links to each other with rotatory bucket pivot, rotatory bucket pivot runs through the pivot protective barrel, and be equipped with the turning gap between rotatory bucket pivot and the pivot protective barrel, the top of rotatory bucket pivot links to each other with the rotatory bucket of branch appearance, divide the rotatory bucket of appearance to accept the discharging pipe, the bottom of dividing the rotatory bucket of appearance is equipped with the drainage tube, the export of drainage tube is followed a plurality of branch appearance fill tops and is rotated.

Furthermore, a stirring motor variable frequency controller is arranged on the stand column of the frame body, and the stirring motor controller is electrically connected with the stirring motor.

Furthermore, a variable frequency controller of a rotating barrel motor is arranged on the stand column of the frame body, and the controller of the rotating barrel motor is electrically connected with the rotating barrel motor.

Further, an output shaft of the stirring motor is connected with the stirring shaft through a coupler, and a motor protective cover is arranged outside the coupler.

Furthermore, the diameter of the stirring barrel is 40-60 cm, the height is 30-50 cm, and the stirring barrel is a funnel-shaped bottom.

Furthermore, the diameter of the sample separation rotating barrel is 20-30 cm, and the height of the sample separation rotating barrel is 20-30 cm.

Furthermore, the upper opening of the sample separating hopper is in a fan-shaped ring shape, a plurality of sample separating hoppers are sequentially connected in an annular shape, the number of the sample separating hoppers is 4-8, the outer diameter of each sample separating disc is 40-60 cm, the inner diameter of each sample separating disc is 10-15 cm, the inner end and the outer end of each sample separating disc are provided with edges, the height of each edge is 2-5 cm, the height of a partition plate between every two adjacent sample separating hoppers is 2-4 cm, and the sample separating discs are fixed on the sample separating disc mounting frame through bolts.

Furthermore, the inner end and the outer end of the receiving container positioning and placing disc are respectively provided with a convex edge, and the height of the convex edge is 2-5 cm.

Furthermore, the frame body upright posts and each frame body main beam layer are made of square steel with the side length of 50-80 mm.

Furthermore, the stirring motor supporting and fixing frame, the stirring barrel positioning frame, the stirring barrel supporting frame, the sample separating disc mounting frame, the positioning placing disc supporting frame and the rotating barrel motor supporting and fixing frame are made of angle steel with the side length of 30-50 mm.

Compared with the prior art, the beneficial effects of the utility model reside in that:

the ore pulp samples to be divided into a plurality of parts are all added into a stirring barrel, a stirring motor is started, the stirring motor drives a stirring impeller to rotate through a stirring shaft, the ore pulp flows into a circulating inner barrel through a circulating pipe, the circulation can be fully stirred, a plurality of sample receiving containers are arranged on a receiving container positioning placing disc in a one-to-one correspondence mode according to identification lines, a rotating barrel motor is started, the speed is regulated through a rotating barrel motor controller, the rotating speed of a sample dividing rotating barrel is controlled to be 20-40 circles/min, then a discharging valve at the bottom of the stirring barrel is opened, the sample ore pulp in the stirring barrel automatically flows into the sample dividing rotating barrel, then a drainage pipe of the sample dividing rotating barrel is uniformly distributed into each sample dividing hopper, the samples distributed into the sample dividing hoppers automatically flow into the corresponding sample receiving containers through outlets at the bottom of the sample dividing hoppers, the uniform sample dividing of the target ore pulp sample is realized through the device, the sample dividing representativeness of the sample is good, the sample dividing is easy to operate, the device is high in practicability and novel in structural design, the source of the simultaneous manufacturing materials and accessories is wide in the easy to process of processing and manufacturing the ore pulp.

Drawings

FIG. 1 is a schematic view of the present invention;

FIG. 2 is a schematic structural view of the mixing tank;

fig. 3 is a top view of the present invention;

FIG. 4 isbase:Sub>A cross-sectional view A-A of FIG. 1;

FIG. 5 is a cross-sectional view B-B of FIG. 1;

FIG. 6 is a cross-sectional view C-C of FIG. 1;

FIG. 7 is a cross-sectional view D-D of FIG. 1;

FIG. 8 is a cross-sectional view E-E of FIG. 1;

FIG. 9 is a cross-sectional view F-F of FIG. 1;

FIG. 10 is a sectional view taken along line G-G of FIG. 8;

FIG. 11 is a schematic view of the attachment of the motor protector;

FIG. 12 is a top view of the motor protection cover;

FIG. 13 is a half sectional view of the shaft protection sleeve;

FIG. 14 is a top view of the shaft protection sleeve;

in the figure: 1-equipment frame body, 11-first frame body main beam layer, 12-second frame body main beam layer, 13-third frame body main beam layer, 14-fourth frame body main beam layer, 15-fifth frame body main beam layer, 16-sixth frame body main beam layer, 17-seventh frame body main beam layer, 18-frame upright post, 19-stirring motor supporting and fixing frame, 110-stirring barrel positioning frame, 111-stirring barrel supporting frame, 112-stirring motor frequency conversion controller, 113-rotating barrel motor frequency conversion controller, 114-sample separation disc mounting frame, 115-positioning placing disc supporting frame, 116-rotating barrel motor supporting and fixing frame, 2-stirring motor, 21-motor protective cover, 3-stirring barrel, 31-circulating inner barrel, 32-stirring shaft, 33-stirring impeller, 34-circulating pipe, 35-discharging pipe, 36-discharging valve, 37-connecting beam, 4-sample separation rotating barrel, 41-drainage pipe, 5-sample separation disc, 51-sample separation bucket, 6-receiving container positioning placing disc, 61-sample receiving container, 62-sample identification, 7-rotating shaft, 7-rotating lug and 8-rotating lug connecting lug.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described below with reference to specific embodiments shown in the accompanying drawings. It should be understood that the description is illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

The utility model discloses the connection that mentions divide into fixed connection and can dismantle the connection, fixed connection is for can not dismantle conventional fixed connection modes such as connection including but not limited to hem connection, rivet connection, adhesive connection and welded connection for the connection, can dismantle the connection including but not limited to conventional dismantlement modes such as bolted connection, buckle connection, pin joint and hinged joint, when not clearly prescribing a limit to concrete connection mode, the default is approved to find at least one kind connected mode in current connected mode and realize this function, and the technical staff in the art can select by oneself as required. For example: the fixed connection selects welding connection, and the detachable connection selects bolt connection.

The present invention will be described in further detail with reference to the accompanying drawings, and the following embodiments are illustrative of the present invention, but the present invention is not limited to the following embodiments.

Example (b): as shown in the figure, the ore pulp sample separating device for the mineral separation test comprises a stirring motor 2, a stirring barrel 3, an equipment frame body 1, a sample separating rotary barrel 4, a sample separating disc 5, a sample receiving container 61, a receiving container positioning placing disc 6 and a rotary barrel motor 8;

the equipment frame body 1 comprises four frame body upright columns 18 distributed at four corners, a first frame body main beam layer 11, a second frame body main beam layer 12, a third frame body main beam layer 13, a fourth frame body main beam layer 14, a fifth frame body main beam layer 15, a sixth frame body main beam layer 16 and a seventh frame body main beam layer 17 are sequentially arranged along the frame body upright columns from top to bottom, each frame body main beam layer consists of four main beams, and the four main beams of each frame body main beam layer sequentially connect the four frame body upright columns 18 along the circumferential direction;

the stirring motor 2 is connected with the first frame main beam layer 11 through a stirring motor supporting fixing frame 19, a stirring barrel positioning frame 110 is arranged on the inner side of the second frame main beam layer 12, four beams of the stirring barrel positioning frame 110 abut against the periphery of the stirring barrel 3, equipment shaking during stirring is avoided, a stirring barrel supporting frame 111 is arranged on the inner side of the third frame main beam layer 13, the bottom wall of the stirring barrel 3 abuts against the stirring barrel supporting frame 111, a circulating inner barrel 31 is arranged in the middle of the stirring barrel 3, a plurality of circulating pipes 34 which are obliquely arranged upwards are arranged on the periphery of the circulating inner barrel 31, a plurality of through holes are formed in the side wall of the circulating inner barrel 31, the plurality of circulating pipes 34 are communicated with the inner side of the circulating inner barrel 31 through the plurality of through holes in a one-to-one correspondence mode, the outer wall of the stirring barrel 3 is connected with the circulating inner barrel 31 through a connecting cross beam 37, the top end of the stirring shaft 32 is connected with an output shaft of the stirring motor 2, the stirring shaft 32 penetrates through the circulating inner barrel 31 and extends to the bottom of the stirring barrel 3, a rotating gap is formed between the stirring shaft 32 and the stirring barrel 31, a stirring impeller 33 is arranged at the bottom end of the stirring barrel 3, a discharge pipe 35 is arranged on the bottom of the stirring barrel, and a valve 36 is arranged on the discharge pipe 35;

the sample distributing disc 5 is connected with the fourth frame body main beam layer 14 through a sample distributing disc mounting frame 114, the receiving container positioning and placing disc 6 is connected with the fifth frame body main beam layer 15 through a positioning and placing disc supporting frame 115, the sample distributing disc 5 is provided with a plurality of sample distributing hoppers 51 which are uniformly distributed on the circumference, the plurality of sample distributing hoppers 51 are sequentially abutted, a plurality of identification lines 62 which are uniformly distributed on the circumference are arranged on the receiving container positioning and placing disc 6, a plurality of sample receiving containers 61 are correspondingly arranged on the receiving container positioning and placing disc 6 one by one according to the identification lines 62, and a plurality of sample receiving containers 61 correspondingly bear outlets of the plurality of sample distributing hoppers 51 one by one;

the bottom of pivot guard cylinder 71 links to each other with rotatory bucket motor 8, rotatory bucket motor 8 supports the mount 116 through rotatory bucket motor and links to each other with sixth support body girder layer 16, pivot guard cylinder 71 runs through the receiving container location in proper order and places dish 6 and branch appearance dish 5, pivot guard cylinder 71 and receiving container location place dish 6 and link to each other, the output shaft of rotatory bucket motor 8 links to each other with rotatory bucket pivot 7, rotatory bucket pivot 7 runs through pivot guard cylinder 71, and be equipped with the turning gap between rotatory bucket pivot 7 and the pivot guard cylinder 71, the top of rotatory bucket pivot 7 links to each other with branch appearance rotary barrel 4, divide appearance rotary barrel 4 to accept discharging pipe 35, the bottom of dividing appearance rotary barrel 4 is equipped with drainage tube 41, the export of drainage tube 41 is followed a plurality of branch appearance fill 51 tops and is rotated.

The pivot protection section of thick bamboo 71 includes two half tubular construction, the middle part of half tubular construction is equipped with first engaging lug 72, first engaging lug 72 supports and leans on the lower extreme of placing dish 6 in the receiving container location, and place dish 6 with the receiving container location and pass through bolted connection, the bottom of half tubular construction is equipped with second engaging lug 73, second engaging lug 73 passes through bolted connection with rotatory bucket motor 8, two half tubular construction clamp fits the outside of rotatory bucket pivot 7, and link to each other through the bolt, thereby the combination of pivot protection section of thick bamboo 71 and the fixed of position have been realized.

The frame body upright post 18 is provided with a stirring motor variable frequency controller 112, and the stirring motor controller 112 is electrically connected with the stirring motor 2. Is convenient for operation and control.

The frame body upright post 18 is provided with a rotating barrel motor variable frequency controller 113, and the rotating barrel motor controller 113 is electrically connected with the rotating barrel motor 8. Is convenient for operation and control.

The output shaft of the stirring motor 2 is connected with the stirring shaft 32 through a coupler, and a motor protective cover 21 is arranged outside the coupler. The motor protective cover 21 comprises two half-pipe structures, the top of each half-pipe structure is provided with a connecting lug, the two half-pipe structures are clamped outside the coupler and connected through bolts, and the connecting lugs are connected with the stirring motor supporting fixed beam frame 19 through bolts. Thereby achieving the combination and the position fixation of the motor guard 21.

The diameter of the stirring barrel 3 is 40-60 cm, the height is 30-50 cm, and the stirring barrel 3 is a funnel-shaped bottom.

The diameter of the sample separation rotating barrel 4 is 20-30 cm, and the height is 20-30 cm.

The upper shed of branch appearance fill 51 is the fan-shaped ring form, and a plurality of branch appearance fill 51 are the annular and link to each other in proper order, and branch appearance fill 51 is 4 ~ 8, and the external diameter of dividing sample dish 5 is 40 ~ 60cm, the internal diameter is 10 ~ 15cm, divides the inner and the outer end of sample dish 5 all to be equipped with the border, the border height is 2 ~ 5cm, and the baffle height between the adjacent branch appearance fill 51 is 2 ~ 4cm, divides sample dish 5 to pass through the bolt fastening on dividing sample dish mounting bracket 114.

The inner end and the outer end of the receiving container positioning and placing disc 6 are respectively provided with a convex edge, and the height of the convex edge is 2-5 cm.

The frame upright posts 18 and each frame main beam layer are made of square steel with the side length of 50-80 mm.

The stirring motor supporting and fixing frame 19, the stirring barrel positioning frame 110, the stirring barrel supporting frame 111, the sample separating disc mounting frame 114, the positioning placing disc supporting frame 115 and the rotating barrel motor supporting and fixing frame 116 are made of angle steel with the side length of 30-50 mm.

The stirring motor supporting and fixing frame 19, the stirring barrel positioning frame 110, the stirring barrel supporting frame 111, the sample separating disc mounting frame 114, the positioning placing disc supporting frame 115 and the rotating barrel motor supporting and fixing frame 116 are welded with the corresponding frame body main beam layers, and the main beam of each frame body main beam layer is welded with the frame body upright post 18.

The ore pulp sample to be divided into a plurality of parts is completely added into the stirring barrel 3, the stirring motor 2 is started, the stirring motor 2 drives the stirring impeller 33 to rotate through the stirring shaft 32, the ore pulp flows into the circulating inner barrel 31 through the circulating pipe 34, the stirring is fully performed in the circulating mode, a plurality of sample receiving containers 61 are correspondingly arranged on the receiving container positioning placing disc 6 in a one-to-one mode according to identification lines 62, the rotating barrel motor 8 is started, the speed is adjusted through the rotating barrel motor controller 113, the rotating speed of the sample dividing rotating barrel 4 is controlled to be 20-40 circles/min, then the discharging valve 36 at the bottom of the stirring barrel 3 is opened, the sample ore pulp in the stirring barrel 3 automatically flows into the sample dividing rotating barrel 4 and is uniformly distributed into the sample dividing hoppers 51 through the drainage pipes 41 of the sample dividing rotating barrel 4, the samples distributed to the sample dividing hoppers 51 automatically flow into the corresponding sample receiving containers 6 through outlets at the bottoms of the sample dividing hoppers 51, and the device can realize uniform sample dividing of the target ore pulp samples, the sample representative is good, and the operation is easy.

The above embodiments are merely illustrative of the present patent and do not limit the scope of the patent, and those skilled in the art can make modifications to the parts thereof without departing from the spirit and scope of the patent.

Claims (10)

1. The utility model provides a mineral separation test ore pulp divides appearance device which characterized in that: comprises a stirring motor (2), a stirring barrel (3), an equipment frame body (1), a sample separation rotating barrel (4), a sample separation disc (5), a sample receiving container (61), a receiving container positioning placing disc (6) and a rotating barrel motor (8);

the equipment frame body (1) comprises four frame body upright columns (18) distributed at four corners, a first frame body main beam layer (11), a second frame body main beam layer (12), a third frame body main beam layer (13), a fourth frame body main beam layer (14), a fifth frame body main beam layer (15), a sixth frame body main beam layer (16) and a seventh frame body main beam layer (17) are sequentially arranged along the frame body upright columns (18) from top to bottom, each frame body main beam layer consists of four main beams, and the four main beams of each frame body main beam layer sequentially connect the four frame body upright columns (18) along the circumferential direction;

the stirring motor (2) is connected with the first frame main beam layer (11) through a stirring motor supporting and fixing frame (19), a stirring barrel positioning frame (110) is arranged on the inner side of the second frame main beam layer (12), four beams of the stirring barrel positioning frame (110) abut against the periphery of the stirring barrel (3), a stirring barrel supporting frame (111) is arranged on the inner side of the third frame main beam layer (13), the bottom wall of the stirring barrel (3) abuts against the stirring barrel supporting frame (111), a circulating inner barrel (31) is arranged in the middle of the stirring barrel (3), a plurality of circulating pipes (34) which are obliquely arranged upwards are arranged on the periphery of the circulating inner barrel (31), a plurality of through holes are formed in the side wall of the circulating inner barrel (31), the plurality of circulating pipes (34) are communicated with the inner side of the circulating inner barrel (31) through the plurality of through holes in a one-to-one correspondence manner, the top end of the stirring shaft (32) is connected with an output shaft of the stirring motor (2), the stirring shaft (32) penetrates through the circulating inner barrel (31) and extends to the bottom of the stirring barrel (3), a rotating gap is formed between the stirring shaft (32) and a discharge pipe (35) of the stirring barrel (33) is arranged at the bottom of the stirring barrel, and a discharge pipe (35) is arranged on the stirring shaft (35);

the sample distributing disc (5) is connected with a fourth frame body main beam layer (14) through a sample distributing disc mounting frame (114), the receiving container positioning placing disc (6) is connected with a fifth frame body main beam layer (15) through a positioning placing disc supporting frame (115), the sample distributing disc (5) is provided with a plurality of sample distributing hoppers (51) which are uniformly distributed in the circumference, the plurality of sample distributing hoppers (51) are sequentially abutted, a plurality of identification lines (62) which are uniformly distributed in the circumference are arranged on the receiving container positioning placing disc (6), a plurality of sample receiving containers (61) are correspondingly arranged on the receiving container positioning placing disc (6) one by one according to the identification lines (62), and a plurality of sample receiving containers (61) correspondingly receive outlets of the plurality of sample distributing hoppers (51);

the bottom of a rotating shaft protection barrel (71) is connected with a rotating barrel motor (8), the rotating barrel motor (8) is connected with a sixth frame body main beam layer (16) through a rotating barrel motor supporting fixing frame (116), the rotating shaft protection barrel (71) sequentially penetrates through a receiving container positioning placing disc (6) and a sample separating disc (5), the rotating shaft protection barrel (71) is connected with the receiving container positioning placing disc (6), an output shaft of the rotating barrel motor (8) is connected with a rotating barrel rotating shaft (7), the rotating barrel rotating shaft (7) penetrates through the rotating shaft protection barrel (71), a rotating gap is formed between the rotating barrel rotating shaft (7) and the rotating shaft protection barrel (71), the top end of the rotating barrel rotating shaft (7) is connected with a sample separating rotating barrel (4), a sample separating rotating barrel (4) is connected with a discharge pipe (35), a drainage pipe (41) is arranged at the bottom of the sample separating rotating barrel (4), and an outlet of the drainage pipe (41) rotates along the upper side of a plurality of sample separating buckets (51).

2. The ore dressing test pulp sample separation device according to claim 1, characterized in that: a stirring motor variable frequency controller (112) is arranged on the frame body upright post (18), and the stirring motor variable frequency controller (112) is electrically connected with the stirring motor (2).

3. The ore dressing test pulp sample separation device according to claim 1, characterized in that: a rotating barrel motor variable frequency controller (113) is arranged on the frame body upright post (18), and the rotating barrel motor variable frequency controller (113) is electrically connected with the rotating barrel motor (8).

4. The ore dressing test pulp sample separation device according to claim 1, characterized in that: the output shaft of the stirring motor (2) is connected with the stirring shaft (32) through a coupler, and a motor protective cover (21) is arranged outside the coupler.

5. The ore dressing test pulp sample separating device according to claim 1, characterized in that: the diameter of the stirring barrel (3) is 40-60 cm, the height is 30-50 cm, and the stirring barrel (3) is a funnel-shaped bottom.

6. The ore dressing test pulp sample separation device according to claim 1, characterized in that: the diameter of the sample separation rotating barrel (4) is 20-30 cm, and the height is 20-30 cm.

7. The ore dressing test pulp sample separating device according to claim 1, characterized in that: the upper opening of the sample separating hopper (51) is in a fan-shaped ring shape, the sample separating hoppers (51) are sequentially connected in a ring shape, the number of the sample separating hoppers (51) is 4-8, the outer diameter of each sample separating plate (5) is 40-60 cm, the inner diameter of each sample separating plate is 10-15 cm, the inner end and the outer end of each sample separating plate (5) are provided with edges, the height of each edge is 2-5 cm, the height of a partition plate between every two adjacent sample separating hoppers (51) is 2-4 cm, and the sample separating plates (5) are fixed on the sample separating plate mounting frame (114) through bolts.

8. The ore dressing test pulp sample separation device according to claim 1, characterized in that: the inner end and the outer end of the receiving container positioning placing disc (6) are respectively provided with a convex edge, and the height of the convex edge is 2-5 cm.

9. A mineral processing test pulp sample separation device according to any one of claims 1-8, characterized in that: the frame body upright posts (18) and each frame body main beam layer are made of square steel with the side length of 50-80 mm.

10. The ore dressing test pulp sample separation device according to claim 9, characterized in that: the stirring motor supporting fixing frame (19), the stirring barrel positioning frame (110), the stirring barrel supporting frame (111), the sample separating disc mounting frame (114), the positioning placing disc supporting frame (115) and the rotating barrel motor supporting fixing frame (116) are made of angle steel with the side length of 30-50 mm.

Images