CN113953077B - Efficient shaking table convenient for tailing treatment for mineral separation - Google Patents

Abstract

The invention relates to the field of mineral separation, in particular to a high-efficiency shaking table for mineral separation, which is convenient for treating tailings, and comprises a supporting base, a reciprocating assembly, an outflow assembly, a collecting assembly and the like; the support base is provided with a reciprocating assembly, the reciprocating assembly is provided with an outflow assembly, and the support base is provided with a collecting assembly. After concentrate and middling are separated through cooperation of the swinging plate and the upper device of the swinging plate, the swinging plate and the upper device of the swinging plate swing, so that the residual tailings on the multi-groove sliding plate are fully poured onto the first guide frame, and the aim of fully and effectively treating the tailings is fulfilled.

Description

Efficient shaking table convenient for tailing treatment for mineral separation

Technical Field

The invention relates to the field of mineral separation, in particular to a high-efficiency shaking table convenient for tailings treatment for mineral separation.

Background

The ore is a mineral stone block which is extracted from mines and contains a certain value, the ore can be applied to the engineering fields of metal mines, metallurgical industry, chemical industry, building industry and the like after being processed step by crushing, grinding and the like, however, the ore extraction and processing are not separated from ore dressing, and the purpose of achieving good effect with low investment can be realized by reasonable ore dressing.

At present, the common mineral separation methods mainly comprise a gravity separation method, a flotation method, a magnetic separation method and an electric separation method, wherein the gravity separation method is used for separating minerals according to the difference of the relative densities of the minerals, a mineral separation table is common equipment for separating fine ore based on the gravity separation method, water flow is needed to be utilized to flush ore particles in the mineral separation process of the mineral separation table, the water flow is needed to be manually controlled by a person through a traditional table, the traditional table does not have the function of stirring the ore particles to be separated, the separation efficiency is low, more tailings are left after separation, and the treatment is inconvenient.

Disclosure of Invention

Based on the above, it is necessary to provide an efficient shaking table which can automatically control water flow, effectively improve the separation efficiency of ore particles and facilitate the treatment of tailings for the ore dressing of tailings, so as to solve the problems that the existing device provided in the prior art needs manual control of water flow, has low separation efficiency and is inconvenient to treat tailings.

The technical scheme is as follows: the utility model provides a high-efficient shaking table of ore dressing with being convenient for handle tailing, including supporting base, reciprocal subassembly, outflow subassembly and collection subassembly:

the reciprocating assembly is arranged on the supporting base and used for reciprocating shaking ore particles;

the outflow assembly is arranged on the reciprocating assembly and is used for enabling water to flow onto the reciprocating assembly so as to play a role in flushing ore particles on the reciprocating assembly;

the collecting assembly is arranged on the supporting base and used for collecting the separated ore particles.

In addition, it is particularly preferred that the reciprocating component comprises a first supporting frame, a swinging plate, a limiting block, a multi-groove sliding plate, a pushing clamping frame, a supporting baffle frame, a motor, a rotating wedge frame, a first straight gear, a second supporting frame and a limiting frame, wherein the first supporting frame is connected to the supporting base through bolts, the swinging plate is connected to the first supporting frame in a rotating mode, the limiting block is fixedly connected to the supporting base, the limiting block is contacted with the swinging plate, the top of the swinging plate is connected with the multi-groove sliding plate in a sliding mode, one side of the bottom of the multi-groove sliding plate is fixedly connected with the pushing clamping frame, the supporting baffle frame is fixedly connected to the multi-groove sliding plate, the motor is fixedly installed on the supporting base, one end of an output shaft of the motor is fixedly connected with the rotating wedge frame, the rotating wedge frame is connected with the supporting base in a rotating mode, the second straight gear is meshed with the first straight gear, the second supporting frame is fixedly connected to the second supporting base, the limiting frame is connected to the second supporting frame in a sliding mode on the second supporting base, the limiting frame is in a limiting mode with the second straight gear, and the limiting frame is in a limiting mode contacted with the pushing clamping frame.

In addition, particularly preferred, the outflow subassembly is including fluting frame, inlet tube, gag lever post, backup pad and spacing loop bar, and the rotation is connected with fluting frame on the swinging plate, and the intercommunication has the inlet tube on the fluting frame, and fluting frame outer wall one side fixedly connected with gag lever post, stopper upper portion one side has the backup pad through bolted connection, and the slip type is connected with the spacing loop bar in the backup pad, and the spacing loop bar is connected with the gag lever post slip type.

In addition, it is particularly preferred that the collecting assembly comprises a first guide frame, a third support frame, a second guide frame and a third guide frame, wherein the first guide frame is connected to the first support frame through bolts, the third support frame is fixedly welded to the support base, the second guide frame is fixedly connected to the third support frame, and the third guide frame is fixedly connected to the third support frame.

In addition, particularly preferred is, still including the separation subassembly, the separation subassembly is located on the supporting rib frame, the separation subassembly is including fourth support frame, the separation frame, first spring, L shape bracing piece and C shape transmission frame, there is the fourth support frame through bolted connection on the supporting rib frame, sliding connection has the separation frame on the fourth support frame, symmetrical connection has first spring between separation frame and the fourth support frame, fixed welding has L shape bracing piece on the third support frame, sliding connection has C shape transmission frame on the L shape bracing piece, C shape transmission frame and separation frame fixed connection.

In addition, particularly preferred is, still including stirring the subassembly, stir the subassembly and locate on the support base, stir the subassembly and including fifth support frame, slip and dial frame and fluting swing frame, fixedly connected with fifth support frame on the support base, the slip is connected with the slip and dials the frame on the fifth support frame, and the rotation is connected with fluting swing frame on the fifth support frame, fluting swing frame and C shape transmission frame, the equal spacing cooperation of slip and dial the frame.

In addition, it is particularly preferable that the swing plate further comprises a turning top frame, and the bottom of the swing plate is fixedly connected with the turning top frame.

In addition, particularly preferred is, still including stirring the subassembly, stirring the subassembly and locate on the support base, stirring the subassembly and including the sixth support frame, promote the frame, return to the position the spring, T shape support frame, the rack, the second spring, stir the frame, overrun clutch and third straight-tooth wheel, fixedly connected with sixth support frame on the support base, sliding connection has the promotion frame on the sixth support frame, promote frame and rotating wedge frame contact, be connected with return to the position the spring between promotion frame and the sixth support frame, fixedly connected with T shape support frame on the slotted frame outer wall, sliding connection has the rack on the T shape support frame, be connected with the second spring between rack and the slotted frame, inside swivelling type of slotted frame is connected with stirs the frame, fixedly connected with overrun clutch on the stirring frame, fixedly connected with third straight-tooth wheel on the overrun clutch, third straight-tooth wheel and rack meshing.

In addition, particularly preferred is, still including outflow control assembly, outflow control assembly locates on the fluting frame, outflow control assembly is including baffle frame, slide rail frame, fluting buoyancy frame, jam frame and screen cloth, and the outside bottom sliding type of fluting frame is connected with the baffle frame, symmetrical fixedly connected with slide rail frame on the fluting frame inner wall, and common sliding type is connected with fluting buoyancy frame between two slide rail frames, fluting buoyancy frame and baffle frame spacing cooperation, fixedly connected with jam frame on the fluting buoyancy frame, jam frame and fluting frame contact, fixedly connected with screen cloth on the fluting frame.

Compared with the prior art, the invention has the following advantages:

through the cooperation of separation frame and last device, the separation frame separates into two parts with multislot sliding plate, can increase the rivers that flow to third guide frame and second guide frame to increase the separation efficiency of concentrate and middling, reached the effect that can select separately the ore grain with high efficiency.

Through stirring the cooperation of frame and last device, stirring the frame and can be close to the interior ore grain of frame of T shape support frame one side to the slotting frame and stir fully to further improve the separation efficiency of ore grain, make ore grain intensive mixing, realized the purpose that can improve the separation efficiency of ore grain effectively.

After concentrate and middling are separated through cooperation of the swinging plate and the upper device of the swinging plate, the swinging plate and the upper device of the swinging plate swing, so that the residual tailings on the multi-groove sliding plate are fully poured onto the first guide frame, and the aim of fully and effectively treating the tailings is fulfilled.

Through the cooperation of jam frame and last device, when the interior water yield of fluting frame is too much, the jam frame can be with the inlet tube shutoff for the inlet tube no longer imports water to the fluting frame in, so as to prevent that the water in the fluting frame is too much and spill over, saved the trouble that the manual control inlet tube was intake, realized the purpose that can control the water yield in the fluting frame automatically.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a schematic perspective view of a first part of the reciprocating assembly of the present invention.

Fig. 4 is a schematic perspective view of a second portion of the reciprocating assembly of the present invention.

Fig. 5 is a schematic perspective view of a third portion of the reciprocating assembly of the present invention.

Fig. 6 is a schematic perspective view of a fourth portion of the reciprocating assembly of the present invention.

Fig. 7 is a schematic perspective view of a fifth portion of the reciprocating assembly of the present invention.

Fig. 8 is a schematic perspective view of a collection assembly according to the present invention.

Fig. 9 is a schematic perspective view of a blocking assembly and a toggle assembly according to the present invention.

Fig. 10 is a schematic perspective view of a toggle assembly according to the present invention.

Fig. 11 is a schematic perspective view of the flip top frame of the present invention.

Fig. 12 is a schematic view of a first partial perspective view of the agitating assembly of the present invention.

Fig. 13 is a schematic view of a second partial perspective view of the agitating assembly of the present invention.

Fig. 14 is a schematic view of a third partial perspective view of the agitating assembly of the present invention.

FIG. 15 is a schematic cross-sectional perspective view of an outflow control assembly according to the present invention.

Fig. 16 is a schematic perspective view of a baffle frame according to the present invention.

In the figure: 1. a supporting base, 2, a reciprocating assembly, 21, a first supporting frame, 22, a swinging plate, 23, a limiting block, 24, a multi-groove sliding plate, 25, a pushing clamping frame, 26, a supporting baffle frame, 27, a motor, 28, a rotating wedge frame, 29, a first straight gear, 210, a second straight gear, 211, a second supporting frame, 212, a limiting frame, 3, an outflow assembly, 31, a slotted frame, 3101, a water inlet pipe, 32, a limiting rod, 33, a supporting plate, 34, a limiting sleeve rod, 4, a collecting assembly, 41, a first guide frame, 42, a third supporting frame, 43, a second guide frame, 44, a third guide frame, 5 and a blocking assembly, 51, fourth support frame, 52, separation frame, 53, first spring, 54, L-shaped support rod, 55, C-shaped transmission frame, 6, toggle assembly, 61, fifth support frame, 62, sliding toggle frame, 63, slotting swing frame, 7, overturning top frame, 8, stirring assembly, 81, sixth support frame, 82, pushing frame, 821, homing spring, 83, T-shaped support frame, 84, rack frame, 85, second spring, 86, stirring frame, 87, overrunning clutch, 88, third spur gear, 9, outflow control assembly, 91, baffle frame, 92, sliding rail frame, 93, slotting buoyancy frame, 94, blocking frame, 95, screen.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

The utility model provides a high-efficient shaking table of ore dressing with being convenient for handle tailing, as shown in fig. 1-8, including supporting base 1, reciprocal subassembly 2, outflow subassembly 3 and collection subassembly 4, be equipped with on the supporting base 1 and be used for shaking the reciprocal subassembly 2 of ore grain, be equipped with on the reciprocal subassembly 2 and be used for making the outflow subassembly 3 of water outflow, be equipped with on the supporting base 1 and be used for collecting the collection subassembly 4 of ore grain.

The reciprocating assembly 2 comprises a first supporting frame 21, a swinging plate 22, a limiting block 23, a multi-groove sliding plate 24, a pushing clamping frame 25, a supporting baffle frame 26, a motor 27, a rotating wedge frame 28, a first straight gear 29, a second straight gear 210, a second supporting frame 211 and a limiting frame 212, wherein the supporting base 1 is fixedly connected with the first supporting frame 21 through bolts, the swinging plate 22 is rotatably connected to the first supporting frame 21, the supporting base 1 is fixedly connected with the limiting block 23 far away from one side of the first supporting frame 21, the limiting block 23 is contacted with the swinging plate 22, the top of the swinging plate 22 is slidably connected with the multi-groove sliding plate 24, the top of the multi-groove sliding plate 24 is provided with a plurality of sliding grooves in a transverse linear distribution mode, the bottom side of the multi-groove sliding plate 24 is fixedly connected with the pushing clamping frame 25, the multi-groove sliding plate 24 is fixedly connected with the supporting baffle frame 26, the supporting baffle frame 26 is used for blocking ore particles and water flow, the motor 27 is fixedly arranged on the supporting base 1, one end of the output shaft of the motor 27 is fixedly connected with the rotating wedge frame 28, one side of the rotating wedge frame 28 is close to one side of the first supporting frame 21, the top of the rotating wedge frame 28 is in a triangular structure, the top of the rotating frame 28 is in a position-shaped structure close to one side of the first supporting frame 21, the rotating frame 28 is in a position-limited frame 29 is fixedly connected with the first straight gear frame 29, the supporting frame 2 is fixedly connected with the supporting frame 2, the first straight gear 2 is fixedly connected with the supporting frame 210, the supporting frame 2 is fixedly connected with the limiting frame 210 on the first side of the supporting frame 2, and the supporting frame 2 is fixedly connected with the limiting frame 2, the limiting frame 2 is connected with the first side 2, the limiting frame 2 is fixedly connected with the limiting frame 2 on the first side 2, the supporting frame 2, and the supporting frame 2.

The outflow subassembly 3 is including fluting frame 31, inlet tube 3101, gag lever post 32, backup pad 33 and spacing loop bar 34, is connected with the fluting frame 31 that is used for storing water in the pivoted on the swinging plate 22, and the intercommunication has the inlet tube 3101 that is used for pouring into fluting frame 31 inside on the fluting frame 31, and fluting frame 31 outer wall one side fixedly connected with gag lever post 32, stopper 23 upper portion one side has backup pad 33 through bolted connection, and the last sliding connection of backup pad 33 has spacing loop bar 34, and spacing loop bar 34 is connected with gag lever post 32 slidingly.

The collecting assembly 4 comprises a first guide frame 41, a third support frame 42, a second guide frame 43 and a third guide frame 44, wherein the first guide frame 41 for collecting tailings is connected to the first support frame 21 through bolts, the third support frame 42 is fixedly welded to the support base 1, the second guide frame 43 for collecting middlings is fixedly connected to the third support frame 42, and the third guide frame 44 for collecting concentrate is fixedly connected to the third support frame 42.

The water inlet pipe 3101 is communicated with an external water supply pipe, the external water supply pipe is opened to enable water to flow into the slotted frame 31 through the water inlet pipe 3101, water can flow onto the multi-slot sliding plate 24 through the opening at the bottom of the slotted frame 31, ore particles to be sorted can be poured into the frame of one side of the slotted frame 31 far away from the third supporting frame 42 through manual operation, the ore particles to be sorted flow onto the multi-slot sliding plate 24 along with water flow, the motor 27 is manually controlled to be started before the operation, the motor 27 drives the rotary wedge-shaped frame 28 and an upper device thereof to rotate forward through an output shaft, the first straight gear 29 drives the second straight gear 210 and an upper device thereof to rotate reversely, the limiting frame 212 drives the pushing clamping frame 25 and the upper device thereof to reciprocate, and ore particle groups move in different directions under the effects of longitudinal water flow flushing and transverse shaking of the multi-slot sliding plate 24, so that ore particles with different properties can flow onto the third guide frame 44, the second guide frame 43 and the first guide frame 41 respectively, and the purpose of automatically sorting ore concentrate, middling and tailing is achieved.

Example 2

On the basis of embodiment 1, as shown in fig. 9-10, the device further comprises a blocking component 5, the blocking component 5 for blocking water flow on the multi-groove sliding plate 24 is arranged on the supporting baffle frame 26, the blocking component 5 comprises a fourth supporting frame 51, a blocking frame 52, a first spring 53, an L-shaped supporting rod 54 and a C-shaped transmission frame 55, the fourth supporting frame 51 is connected to the supporting baffle frame 26 through bolts, the blocking frame 52 is connected to the fourth supporting frame 51 in a sliding mode, the first spring 53 for driving the blocking frame 52 to reset is symmetrically connected between the blocking frame 52 and the fourth supporting frame 51, the L-shaped supporting rod 54 is fixedly welded on one side, far away from the second supporting frame 211, of the third supporting frame 42, the C-shaped transmission frame 55 is fixedly connected to the L-shaped supporting rod 54 in a sliding mode, and the C-shaped transmission frame 55 is fixedly connected to the blocking frame 52.

The novel sliding type lifting device is characterized by further comprising a stirring assembly 6, wherein the stirring assembly 6 is arranged on the supporting base 1, the stirring assembly 6 comprises a fifth supporting frame 61, a sliding stirring frame 62 and a slotted swinging frame 63, the fifth supporting frame 61 is fixedly connected onto the supporting base 1, the sliding stirring frame 62 is connected onto the fifth supporting frame 61 in a sliding manner, the slotted swinging frame 63 is rotatably connected onto the fifth supporting frame 61, sliding grooves are formed in two sides of the slotted swinging frame 63, and the slotted swinging frame 63 is in limit fit with the C-shaped transmission frame 55 and the sliding stirring frame 62.

The wedge 28 is rotated to push the sliding frame 62 upwards, the C-shaped transmission frame 55 and the upper device thereof are moved downwards under the action of the slotting swing frame 63, the first spring 53 is compressed, the blocking frame 52 blocks the multi-slot sliding plate 24 into two parts, so that water flow to the third guide frame 44 and the second guide frame 43 can be increased, the separation efficiency of concentrate and middling is improved, the wedge 28 is separated from the sliding frame 62, the first spring 53 is reset and drives the blocking frame 52 and the upper device thereof to reset, and the sliding frame 62 is reset under the action of the slotting swing frame 63, so that the effect of efficiently separating ore particles is achieved.

Example 3

On the basis of the embodiment 2, as shown in fig. 11, the device further comprises a turning top frame 7, and the bottom of the swinging plate 22 is fixedly connected with the turning top frame 7 for pouring out the tailings remained on the multi-groove sliding plate 24.

Then the turning wedge frame 28 can push the turning top frame 7 and the upper device thereof to move upwards, the swinging plate 22 and the upper device thereof can swing, so that the tailings remained on the multi-groove sliding plate 24 fall onto the first guide frame 41, in the process, the grooved frame 31 and the upper device thereof are always in a vertical state through the cooperation of the limit sleeve rod 34 and the limit rod 32 and the upper device thereof, so that a large amount of water in the grooved frame 31 is prevented from being poured out, the sorting of mineral particles is not influenced, then the turning wedge frame 28 can be separated from the turning top frame 7, the turning top frame 7 and the upper device thereof can be reset under the action of gravity, and the purpose of efficiently treating the tailings is realized through the above operations.

Example 4

Based on embodiment 3, as shown in fig. 12-14, stirring assembly 8 is further included, stirring assembly 8 is disposed on supporting base 1, stirring assembly 8 includes sixth supporting frame 81, pushing frame 82, homing spring 821, T-shaped supporting frame 83, rack 84, second spring 85, stirring frame 86, overrun clutch 87 and third spur gear 88, sixth supporting frame 81 is fixedly connected on supporting base 1, pushing frame 82 is slidingly connected with pushing frame 82, pushing frame 82 contacts with rotary wedge 28, pushing frame 82 is connected with sixth supporting frame 81, homing spring 821 for driving pushing frame 82 to reset is connected with outer wall of slotted frame 31 through bolts, T-shaped supporting frame 83 is T-shaped, T-shaped supporting frame 83 is slidingly connected with rack 84, second spring 85 for driving rack 84 to reset is connected between rack 84 and slotted frame 31, stirring frame 86 for fully stirring mineral grains is rotatably connected with inside slotted frame 31, stirring frame 87 is fixedly connected with stirring frame 87, overrun clutch 88 is fixedly connected with third spur gear 84, and third overrun clutch 88 is fixedly connected with slotted frame 84.

Then the rotating wedge frame 28 pushes the pushing frame 82 to move, the homing spring 821 is stretched, the pushing frame 82 pushes the rack frame 84 to move upwards and drive the third spur gear 88 and the upper device thereof to rotate, the second spring 85 is stretched, so that the stirring frame 86 stirs the ore particles in the frame of the side of the slotted frame 31, which is close to the T-shaped supporting frame 83, fully, the ore particles are sorted, the rotating wedge frame 28 is separated from the pushing frame 82, the pushing frame 82 is reset under the reset action of the homing spring 821, the second spring 85 is reset and drives the pushing rack frame 84 to reset, the pushing rack frame 84 drives the third spur gear 88 and the upper device thereof to rotate reversely, and the stirring frame 86 is not rotated under the action of the overrunning clutch 87, so that stirring is not needed, and the effect of effectively improving the sorting efficiency is achieved through the operation.

Example 5

On the basis of embodiment 4, as shown in fig. 15-16, the device further comprises an outflow control component 9, wherein the outflow control component 9 for controlling water flow is arranged on the slotted frame 31, the outflow control component 9 comprises a baffle frame 91, a sliding rail frame 92, a slotted buoyancy frame 93, a blocking frame 94 and a screen 95, the outer bottom of the slotted frame 31 is slidably connected with the baffle frame 91, the sliding rail frames 92 are symmetrically and fixedly connected with the inner wall of the slotted frame 31, the sliding rail frames 92 are in an I shape, the slotted buoyancy frames 93 are slidably connected between the two sliding rail frames 92 together, the slotted buoyancy frame 93 has the characteristic of small mass, the slotted buoyancy frame 93 is in limit fit with the baffle frame 91, the blocking frame 94 is fixedly connected with the blocking frame 94 and used for blocking a water inlet pipe 3101, the blocking frame 94 is in contact with the slotted frame 31, and the screen 95 for blocking mineral grains is fixedly connected with the slotted frame 31.

Along with the rising of the water level in the slotted frame 31, the slotted buoyancy frame 93 moves upwards under the action of buoyancy, the slotted buoyancy frame 93 drives the baffle frame 91 to move away from the fourth supporting frame 51, so that the baffle frame 91 is opened, water in the slotted frame 31 can flow onto the multi-slotted sliding plate 24 through the opening at the bottom of the baffle frame, when the water level in the slotted frame 31 drops, the slotted buoyancy frame 93 resets and drives the baffle frame 91 to reset, when the water level in the slotted frame 31 rises to a certain height, the blocking frame 94 can block the water inlet pipe 3101 so as to prevent excessive water in the slotted frame 31 from overflowing, when the water level in the slotted frame 31 drops, the blocking frame 94 can be opened, through the screen mesh 95, part of ore particles can be prevented from entering the other side of the slotted frame 31 when the stirring frame 86 stirs ore particles in the frame near one side of the T-shaped supporting frame 83, the aim of blocking the ore particles can be fulfilled, finally, the manual control motor 27 stops running when the operation is repeated, and the ore particles can be sorted again and efficiently.

Although embodiments of the present invention 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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a high-efficient shaking table of tailing is handled with being convenient for to ore dressing which characterized in that includes support base (1), reciprocal subassembly (2), outflow subassembly (3) and collection subassembly (4):

the reciprocating assembly (2) is arranged on the supporting base (1), and the reciprocating assembly (2) is used for reciprocating shaking ore particles;

the outflow assembly (3) is arranged on the reciprocating assembly (2), the outflow assembly (3) is used for enabling water to flow onto the reciprocating assembly (2) and has the effect of flushing ore particles on the reciprocating assembly (2);

the collecting assembly (4) is arranged on the supporting base (1), and the collecting assembly (4) is used for collecting the separated ore particles;

the reciprocating assembly (2) comprises a first supporting frame (21), a swinging plate (22), a limiting block (23), a multi-groove sliding plate (24), a pushing clamping frame (25), a supporting baffle frame (26), a motor (27), a rotating wedge frame (28), a first straight gear (29), a second straight gear (210), a second supporting frame (211) and a limiting frame (212), wherein the first supporting frame (21) is connected to a supporting base (1) through bolts, the swinging plate (22) is rotatably connected to the first supporting frame (21), the limiting block (23) is fixedly connected to the supporting base (1), the limiting block (23) is contacted with the swinging plate (22), the top of the swinging plate (22) is slidably connected with the multi-groove sliding plate (24), one side of the bottom of the multi-groove sliding plate (24) is fixedly connected with the pushing clamping frame (25), the supporting baffle frame (26) is fixedly connected to the multi-groove sliding plate (24), the motor (27) is fixedly arranged on the supporting base (1), one end of an output shaft of the motor (27) is fixedly connected with the rotating wedge frame (28), the rotating wedge frame (28) is rotatably connected to the supporting base (1), the rotating wedge frame (29) is fixedly connected to the first straight gear (210), the second spur gear (210) is meshed with the first spur gear (29), a second supporting frame (211) is fixedly connected to the supporting base (1), a limiting frame (212) is connected to the second supporting frame (211) in a sliding mode, the limiting frame (212) is in limiting fit with the second spur gear (210), and the limiting frame (212) is in contact with the pushing clamping frame (25);

the outflow assembly (3) comprises a slotted frame (31), a water inlet pipe (3101), a limiting rod (32), a supporting plate (33) and a limiting sleeve rod (34), wherein the slotted frame (31) is rotatably connected to the swinging plate (22), the water inlet pipe (3101) is communicated to the slotted frame (31), the limiting rod (32) is fixedly connected to one side of the outer wall of the slotted frame (31), the supporting plate (33) is connected to one side of the upper part of the limiting block (23) through a bolt, the limiting sleeve rod (34) is connected to the supporting plate (33) in a sliding mode, and the limiting sleeve rod (34) is connected with the limiting rod (32) in a sliding mode;

the collecting assembly (4) comprises a first guide frame (41), a third support frame (42), a second guide frame (43) and a third guide frame (44), wherein the first support frame (21) is connected with the first guide frame (41) through bolts, the third support frame (42) is fixedly welded on the support base (1), the second guide frame (43) is fixedly connected on the third support frame (42), and the third guide frame (44) is fixedly connected on the third support frame (42);

the novel plastic composite material blocking device is characterized by further comprising a blocking component (5), wherein the blocking component (5) is arranged on the supporting and blocking frame (26), the blocking component (5) comprises a fourth supporting frame (51), a blocking frame (52), a first spring (53), an L-shaped supporting rod (54) and a C-shaped transmission frame (55), the fourth supporting frame (51) is connected to the supporting and blocking frame (26) through bolts, the blocking frame (52) is connected to the fourth supporting frame (51) in a sliding mode, the first spring (53) is symmetrically connected between the blocking frame (52) and the fourth supporting frame (51), the L-shaped supporting rod (54) is fixedly welded to the third supporting frame (42), the C-shaped transmission frame (55) is connected to the L-shaped supporting rod (54) in a sliding mode, and the C-shaped transmission frame (55) is fixedly connected to the blocking frame (52).

2. The efficient shaking table convenient for tailings treatment for mineral separation according to claim 1 is characterized by further comprising a stirring assembly (6), wherein the stirring assembly (6) is arranged on the supporting base (1), the stirring assembly (6) comprises a fifth supporting frame (61), a sliding stirring frame (62) and a slotting swinging frame (63), the fifth supporting frame (61) is fixedly connected to the supporting base (1), the sliding stirring frame (62) is connected to the fifth supporting frame (61) in a sliding mode, the slotting swinging frame (63) is connected to the fifth supporting frame (61) in a rotating mode, and the slotting swinging frame (63) is in limit fit with the C-shaped transmission frame (55) and the sliding stirring frame (62).

3. A high efficiency shaker for concentrating tailings according to claim 2,

the device is characterized by further comprising a turning top frame (7), and the bottom of the swinging plate (22) is fixedly connected with the turning top frame (7).

4. A high efficiency shaker for beneficiation processes of tailings according to claim 3,

it is characterized in that the stirring device also comprises a stirring component (8), the stirring component (8) is arranged on the supporting base (1), the stirring component (8) comprises a sixth supporting frame (81), a pushing frame (82), a homing spring (821), a T-shaped supporting frame (83), a rack (84), a second spring (85), a stirring frame (86), an overrunning clutch (87) and a third spur gear (88), the sixth supporting frame (81) is fixedly connected on the supporting base (1), the pushing frame (82) is connected on the sixth supporting frame (81) in a sliding way, the pushing frame (82) is contacted with the rotating wedge-shaped frame (28),

a homing spring (821) is connected between the pushing frame (82) and the sixth supporting frame (81),

t-shaped supporting frames (83) are fixedly connected to the outer wall of the grooved frame (31), and the T-shaped supporting frames (83)

The upper sliding type is connected with a rack (84), a second spring (85) is connected between the rack (84) and the slotted frame (31), an agitating frame (86) is rotatably connected in the slotted frame (31), and an overrunning clutch (87) is fixedly connected on the agitating frame (86), and the overrunning clutch (87) is fixedly connected on the upper sliding type

And a third straight gear (88) is fixedly connected to the upper part, and the third straight gear (88) is meshed with the rack (84).

5. The efficient shaking table convenient for tailings disposal for mineral separation according to claim 4, further comprising an outflow control assembly (9), wherein the outflow control assembly (9) is arranged on the slotted frame (31), the outflow control assembly (9) comprises a baffle frame (91), a sliding rail frame (92), a slotted buoyancy frame (93), a blocking frame (94) and a screen (95), the baffle frame (91) is slidably connected to the outer bottom of the slotted frame (31), the sliding rail frames (92) are symmetrically and fixedly connected to the inner wall of the slotted frame (31), the slotted buoyancy frame (93) is slidably connected between the two sliding rail frames (92), the slotted buoyancy frame (93) is in limit fit with the baffle frame (91), the blocking frame (94) is fixedly connected to the slotted buoyancy frame (93), the blocking frame (94) is in contact with the slotted frame (31), and the screen (95) is fixedly connected to the slotted frame (31).