CN115301702A

CN115301702A - Liftable in-mine refuse treatment equipment

Info

Publication number: CN115301702A
Application number: CN202211237261.6A
Authority: CN
Inventors: 李闯
Original assignee: Jiangsu Yongda Shearer Cable Manufacturing Co ltd
Current assignee: Jiangsu Yongda Shearer Cable Manufacturing Co ltd
Priority date: 2022-10-11
Filing date: 2022-10-11
Publication date: 2022-11-08

Abstract

The invention belongs to the technical field of separation, and particularly relates to liftable in-mine garbage treatment equipment which comprises a tailing treatment main body, a single-pendulum type feeding lifting mechanism, a rolling type thermal cycle crushing mechanism and a multiple gravitation tailing separation mechanism, wherein the rolling type thermal cycle crushing mechanism is arranged on the upper side inside the tailing treatment main body, the multiple gravitation tailing separation mechanism is arranged on the lower side inside the tailing treatment main body, and the single-pendulum type feeding lifting mechanism is arranged on the outer side of the tailing treatment main body; the invention provides a rolling type thermal cycle crushing mechanism, which realizes the functions of crushing and drying tailings by the mutual matching of a bounce type rolling component, a microwave internal reflection type driving component and a tailing adhesion prevention heating component.

Description

Liftable in-mine refuse treatment equipment

Technical Field

The invention belongs to the technical field of crushing, and particularly relates to a liftable device for treating mine garbage.

Background

A large amount of tailings with low available value are screened in the mineral resource processing treatment process, but the tailings are not completely useless wastes, the tailings contain rich colored, black, rare or nonmetal minerals and the like, the tailings are valuable resources which can be recycled, and the conventional treatment method for the tailings is accumulation all the time, so that a large amount of resource waste is caused.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides liftable equipment for treating the mine garbage, aiming at solving the problems that the tailings contain rich colored, black, rare and precious or nonmetal minerals and the like, the tailings are valuable resources which can be recycled, and the conventional treatment method for the tailings is accumulation, so that a large amount of resources are wasted.

The technical scheme adopted by the invention is as follows: the invention provides liftable in-mine garbage treatment equipment, which comprises a tailing treatment main body, a single-pendulum type feeding lifting mechanism, a rolling type thermal cycle crushing mechanism and a multiple gravitation tailing separation mechanism, wherein the rolling type thermal cycle crushing mechanism is arranged at the upper side in the tailing treatment main body; broken mechanism of roll extrusion formula thermal cycle rolls subassembly, microwave internal reflection-type drive assembly and prevents that the tails glues glutinous heating element including the spring type, the spring type rolls the subassembly and locates inside the tails processing main part, microwave internal reflection-type drive assembly locates the spring type and rolls on the subassembly, prevent that the tails glues glutinous heating element and locates in the spring type rolls the subassembly.

Further, the tailings processing main part includes broken casing, broken chamber, disengagement chamber, feed inlet one, discharge gate, linkage plate and support horizontal pole, broken casing is located in the tailings processing main part, the inside upside of broken casing is located in broken chamber, the inside downside of broken casing is located in the disengagement chamber, one side in broken chamber is located to feed inlet one, the back side of broken casing is located to the discharge gate, the linkage plate is located on the feed inlet one, the support horizontal pole is located on the discharge gate.

Further, the spring type rolls the subassembly and includes that broken circular telegram steel ball, thickened annular roll track, electrical layer, protruding sloping block, two feed inlets and electronic valve, thickened annular rolls the track and locates in the microwave reflection-type drive assembly, broken circular telegram steel ball rolls and locates in the thickened annular rolls the track, the electrical layer is located on the thickened annular rolls orbital inner wall, the protruding sloping block is located on the thickened annular rolls orbital inner wall, two feed inlets are located on the thickened annular rolls the track, electronic valve locates on feed inlet two.

Further, reflection-type drive assembly includes driving motor one, axis of rotation one, connecting pipe and magnetron in the microwave, driving motor one locates the outside in broken chamber, broken intracavity is located in a rotation axis of rotation, driving motor one's output is located to the one end of axis of rotation one, the axis of rotation is located on one to the one end of connecting pipe, the other end of axis of rotation one link up locates the thickening ring shape and rolls orbital inboard, the magnetron is located in the connecting pipe.

Further, prevent that tails glues glutinous heating element and include graphite alkene layer, broken layer, striking chamber, striking iron ball and protruding piece, broken layer locates the skin of broken circular telegram steel ball, the inlayer of broken layer is located to graphite alkene layer, the inside on graphite alkene layer is located to the striking chamber, protruding piece is located on the inner wall on broken layer, the striking iron ball rolls and locates the striking intracavity.

Further, the multi-gravity tailing separation mechanism comprises a vertical component multi-gravity screening assembly and a through type rotary driving assembly, the through type rotary driving assembly is arranged on the outer side of the separation cavity, and the vertical component multi-gravity screening assembly is arranged on the through type rotary driving assembly.

Further, many gravitations of perpendicular component screening subassembly include and rotate cylinder, strong magnet, separation hole, bearing one, bracing piece and mop piece, bearing one is located on supporting the horizontal pole, the one end of rotating the cylinder is located on the bearing one, the other end of rotating the cylinder rotates and locates on the lateral wall of separation chamber, the separation hole is located and is rotated on the cylinder, the one end of rotating the cylinder is located to the bracing piece, the one end of strong magnet is located on the bracing piece, the other end of strong magnet link up and locates the inside one end of rotating the cylinder, the inside lower extreme of separation chamber is located to the mop piece.

Further, through rotary driving subassembly includes motor two, gear one, gear two, bearing two, air pump, gas-supply pipe, annular interface, filter screen and collecting box, motor two is located on the lateral wall of disengagement chamber, the output of motor two is located to gear one, the one end of rotating the cylinder is located to gear cover, gear one and gear two rotate for the meshing and link to each other, bearing two link up the one end of locating the rotation cylinder, the air pump is located on the lateral wall of disengagement chamber, the one end of gas-supply pipe link up the output of locating the air pump, the other end of gas-supply pipe link up and locates on the bearing two, the annular interface link up and cup joint and locate the epaxial of rotation cylinder, the one end of annular interface link up and locates on the rotation cylinder, the collecting box is located on the discharge gate, one side of collecting box is located to the filter screen.

Further, simple pendulum formula material loading elevating system is including transportation frame, motor three, axis of rotation two, transportation area, baffle, hinge one, hinge two, spout, pulley and cylinder, the lower extreme of feed inlet one is located to hinge one, the one end of transportation frame is located on the hinge one, the cylinder is located on broken casing, the output of cylinder is located to hinge two, axis of rotation two rotates to be located in the transportation frame, the outside of transportation frame is located to axis of rotation two, the output of motor three is located to the one end of axis of rotation two, the transportation area cup joints on locating axis of rotation two, the baffle is located on the transportation area, the lower extreme of transportation frame is located to the spout, the one end of pulley slides and locates in the spout, the other end of pulley is located on the hinge two.

Furthermore, a collecting brush is arranged on the rotary roller.

The invention with the structure has the following beneficial effects: the invention provides a liftable in-mine garbage treatment device, which realizes the following beneficial effects:

(1) In order to realize the drying function while crushing the tailings, the invention provides a rolling type thermal cycle crushing mechanism, which dries the tailings with high moisture by utilizing the microwave reflection principle through the mutual matching of a bounce type rolling component, a microwave internal reflection type driving component and a tailing adhesion preventing heating component.

(2) In order to further improve the practicability and the popularization, the invention provides the multi-gravity tailing separation mechanism, and iron minerals in tailings can be separated through the mutual matching of the vertical component force multi-gravity screening assembly and the through type rotary driving assembly.

(3) And the crushing electrified steel ball falls after passing through the raised slope block to crush and roll the mineral tailings.

(4) And the arrangement of the collecting brush throws the mixed tailings which are not separated cleanly up again, and the mixed tailings are separated by using airflow.

(5) Electrifying the electrified layer, impacting the iron ball to roll and impact in the impacting cavity, and in the electrified layer under the electrified state, the carbon molecule clusters rub against each other and collide to generate heat energy, and the heat energy is radiated out uniformly in a plane mode through far infrared rays, so that the broken layer can be well heated, and the tailing is prevented from being stuck on the outer wall of the broken layer.

Drawings

FIG. 1 is a front view of a liftable in-mine waste treatment apparatus according to the present invention;

FIG. 2 is a front sectional view of a liftable in-mine garbage disposal apparatus according to the present invention;

FIG. 3 is a top view of a multiple gravity tailing separation mechanism;

FIG. 4 is a rear view of the rotating drum;

FIG. 5 is a schematic structural view of a broken energized steel ball;

FIG. 6 is a cross-sectional view of the rotating drum;

fig. 7 is a partially enlarged view of a portion a in fig. 2.

Wherein, 1, a tailing processing main body, 2, a rolling type thermal cycle crushing mechanism, 3, a multiple attraction tailing separating mechanism, 4, a single pendulum type feeding lifting mechanism, 5, a crushing shell, 6, a crushing cavity, 7, a separating cavity, 8, a first feeding port, 9, a discharging port, 10, a connecting plate, 11, a supporting cross bar, 12, a bounce type rolling component, 13, a microwave internal reflection type driving component, 14, a tailing adhesion prevention heating component, 15, a crushing electrified steel ball, 16, a thickened annular rolling track, 17, an electrified layer, 18, a raised slope block, 19, a second feeding port, 20, an electronic valve, 21, a first driving motor, 22, a first rotating shaft, 23, a connecting pipe, 24, a magnetron, 25 and a graphene layer, 26, a crushing layer 27, an impact cavity 28, an impact iron ball 29, a bump 30, a vertical component force multi-gravitation screening component 31, a through type rotary driving component 32, a rotary roller 33, a strong magnet 34, a separation hole 35, a first bearing, 37, a support rod 38, a mopping block 39, a second motor 40, a first gear, 41, a second gear, 42, a second bearing, 43, an air pump 44, an air pipe 45, a ring joint, 46, a filter screen 47, a transport frame 48, a third motor, 49, a second rotary shaft 50, a transport belt 51, a baffle plate 52, a first hinge, 53, a second hinge, 54, a chute, 55, a pulley, 56, an air cylinder 57, a collection box, 58 and a collection brush.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings, merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention.

As shown in fig. 1-7, the invention provides a liftable in-mine waste treatment device, which comprises a tailing treatment main body 1 and a single-pendulum type feeding lifting mechanism 4, and is characterized in that: the device also comprises a rolling type thermal cycle crushing mechanism 2 and a multiple gravitation tailing separation mechanism 3, wherein the rolling type thermal cycle crushing mechanism 2 is arranged on the upper side inside the tailing processing main body 1, the multiple gravitation tailing separation mechanism 3 is arranged on the lower side inside the tailing processing main body 1, and a single pendulum type feeding lifting mechanism 4 is arranged on the outer side of the tailing processing main body 1; the rolling type thermal cycle crushing mechanism 2 comprises a bouncing type rolling component 12, a microwave internal reflection type driving component 13 and a tailing adhesion prevention heating component 14, the bouncing type rolling component 12 is arranged inside a tailing processing main body 1, the microwave internal reflection type driving component 13 is arranged on the bouncing type rolling component 12, and the tailing adhesion prevention heating component 14 is arranged in the bouncing type rolling component 12.

The tailings processing main body 1 comprises a crushing shell 5, a crushing cavity 6, a separation cavity 7, a feeding port I8, a discharging port 9, a connecting plate 10 and a supporting cross rod 11, the crushing shell 5 is arranged on the tailings processing main body 1, the crushing cavity 6 is arranged on the inner upside of the crushing shell 5, the separation cavity 7 is arranged on the inner downside of the crushing shell 5, the feeding port I8 is arranged on one side of the crushing cavity 6, the discharging port 9 is arranged on the rear side end of the crushing shell 5, the connecting plate 10 is arranged on the feeding port I8, and the supporting cross rod 11 is arranged on the discharging port 9.

The multi-gravity tailing separating mechanism 3 comprises a vertical component force multi-gravity screening assembly 30 and a through type rotary driving assembly 31, wherein the through type rotary driving assembly 31 is arranged outside the separating cavity 7, and the vertical component force multi-gravity screening assembly 30 is arranged on the through type rotary driving assembly 31.

The vertical component multi-gravity screening assembly 30 comprises a rotating roller 32, a strong magnet 33, a separation hole 34, a first bearing 35, a support rod 37 and a mopping block 38, wherein the first bearing 35 is arranged on the support cross rod 11, one end of the rotating roller 32 is arranged on the first bearing 35, the other end of the rotating roller 32 is rotatably arranged on the side wall of the separation cavity 7, the separation hole 34 is arranged on the rotating roller 32, the support rod 37 is arranged at one end of the rotating roller 32, one end of the strong magnet 33 is arranged on the support rod 37, the other end of the strong magnet 33 penetrates through one end inside the rotating roller 32, and the mopping block 38 is arranged at the lower end inside the separation cavity 7.

The through type rotary driving assembly 31 comprises a second motor 39, a first gear 40, a second gear 41, a second bearing 42, an air pump 43, an air pipe 44, an annular connector 45, a filter screen 46 and a collecting box 57, the second motor 39 is arranged on the outer side wall of the separation cavity 7, the first gear 40 is arranged at the output end of the second motor 39, the second gear 41 is sleeved on one end of the rotary roller 32, the first gear 40 and the second gear 41 are connected in a meshing rotation mode, the second bearing 42 is arranged at one end of the rotary roller 32 in a penetrating mode, the air pump 43 is arranged on the outer side wall of the separation cavity 7, one end of the air pipe 44 is arranged at the output end of the air pump 43 in a penetrating mode, the other end of the air pipe 44 is arranged on the second bearing 42 in a penetrating mode, the annular connector 45 is arranged on the shaft of the rotary roller 32 in a penetrating mode, one end of the annular connector 45 is arranged on the rotary roller 32 in a penetrating mode, the collecting box 57 is arranged on the discharging hole 9, and the filter screen 46 is arranged on one side of the collecting box 57.

The single-pendulum loading lifting mechanism 4 comprises a transportation frame 47, a motor III 48, a rotating shaft II 49, a transportation belt 50, a baffle 51, a hinge I52, a hinge II 53, a sliding groove 54, a pulley 55 and a cylinder 56, wherein the hinge I52 is arranged at the lower end of a feeding hole I8, one end of the transportation frame 47 is arranged on the hinge I52, the cylinder 56 is arranged on the crushing shell 5, the hinge II 53 is arranged at the output end of the cylinder 56, the rotating shaft II 49 is rotatably arranged in the transportation frame 47, the rotating shaft II 49 is arranged at the outer side of the transportation frame 47, one end of the rotating shaft II 49 is arranged at the output end of the motor III 48, the transportation belt 50 is sleeved on the rotating shaft II 49, the baffle 51 is arranged on the transportation belt 50, the sliding groove 54 is arranged at the lower end of the transportation frame 47, one end of the pulley 55 is slidably arranged in the sliding groove 54, and the other end of the pulley 55 is arranged on the hinge II 53.

The rotating drum 32 is provided with a collecting brush 58.

The bounce type rolls subassembly 12 and includes broken circular telegram steel ball 15, thickening annular rolls track 16, circular telegram layer 17, protruding sloping block 18, two 19 feed inlets and electronic valve 20, thickening annular rolls on track 16 locates microwave internal reflection type drive assembly 13, broken circular telegram steel ball 15 rolls and locates in the thickening annular rolls track 16, circular telegram layer 17 is located thickening annular and rolls on track 16's the inner wall, protruding sloping block 18 is located thickening annular and rolls on track 16's the inner wall, two 19 feed inlets are located thickening annular and roll on track 16, electronic valve 20 is located on two 19 feed inlets.

The microwave internal reflection type driving assembly 13 comprises a first driving motor 21, a first rotating shaft 22, a connecting pipe 23 and a magnetron 24, wherein the first driving motor 21 is arranged on the outer side of the crushing cavity 6, the first rotating shaft 22 is rotatably arranged in the crushing cavity 6, one end of the first rotating shaft 22 is arranged at the output end of the first driving motor 21, one end of the connecting pipe 23 is arranged on the first rotating shaft 22, the other end of the first rotating shaft 22 is arranged on the inner side of the thickened annular rolling track 16 in a penetrating mode, and the magnetron 24 is arranged in the connecting pipe 23.

Prevent that tails glues glutinous heating element 14 includes graphite alkene layer 25, broken layer 26, striking chamber 27, striking iron ball 28 and protruding piece 29, and broken layer 26 locates the skin of broken circular telegram steel ball 15, and broken layer 26's inlayer is located to graphite alkene layer 25, and striking chamber 27 locates graphite alkene layer 25's inside, and protruding piece 29 is located on broken layer 26's inner wall, and striking iron ball 28 rolls and locates in the striking chamber 27.

When the device is used, the output end of the motor III 48 rotates to drive the rotating shaft II 49 to rotate, the rotating shaft II 49 rotates to drive the conveying belt 50 to rotate, the conveying belt 50 rotates to drive the baffle plate 51 to rotate, the output end of the air cylinder 56 moves to drive the hinge II 53 to move, the hinge II 53 moves to drive the pulley 55 to move in the sliding groove 54, so that the lifting of one end of the conveying frame 47 is driven, so that the mineral tailings are fed, the electronic valve 20 is opened, the tailings enter the thickened annular rolling track 16, the electronic valve 20 is closed, the output end of the driving motor I21 rotates to drive the rotating shaft I22 to rotate, the rotating shaft I22 rotates to drive the connecting pipe 23 to rotate, the connecting pipe 23 rotates to drive the thickened annular rolling track 16 to rotate, the thickened annular rolling track 16 rotates to drive the raised slope block 18 to rotate, the crushed electrified steel ball 15 falls after passing through the raised slope block 18, the crushed and rolled mineral tailings are started by the magnetron 24, microwave is generated in the thickened annular rolling track 16, on one hand, tailings can be dried, on the other hand, the other end assists in crushing the tailings through vibration, the electrified layer 17 is electrified, the impact iron ball 28 rolls and impacts in the impact cavity 27, carbon molecular groups in the electrified layer 17 in an electrified state rub and collide with each other to generate heat energy, the heat energy is uniformly radiated out in a planar mode through far infrared rays, the crushed layer 26 can be well heated, the tailings are prevented from being adhered to the outer wall of the crushed layer 26, the electronic valve 20 is opened, the crushed tailings enter the separation cavity 7 through the feed inlet two 19, the output end of the motor two 39 rotates to drive the gear one 40 to rotate, the gear one 40 rotates to drive the gear two 41 to rotate, the gear two 41 rotates to drive the rotary roller 32 to rotate, air flow generated by starting the air pump 43 enters the annular connector 45 through the air delivery pipe 44 and then passes through the rotary roller 32, broken tailings enter the rotary drum 32 from the separation hole 34, iron ore materials are adsorbed on the strong magnet 33, other tailings are blown into the discharge hole 9, and next mineral raw material separation is carried out.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings show only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should be able to conceive of the present invention without creative design of the similar structural modes and embodiments without departing from the spirit of the present invention, and all such modifications should fall within the protection scope of the present invention.

Claims

1. The utility model provides a liftable in-mine refuse treatment equipment, includes that tailings are handled main part (1) and simple pendulum formula material loading elevating system (4), its characterized in that: the liftable in-mine garbage treatment equipment further comprises a rolling type thermal cycle crushing mechanism (2) and a multiple attraction tailing separation mechanism (3), wherein the rolling type thermal cycle crushing mechanism (2) is arranged on the upper side inside the tailing treatment main body (1), the multiple attraction tailing separation mechanism (3) is arranged on the lower side inside the tailing treatment main body (1), and the single pendulum type feeding and lifting mechanism (4) is arranged on the outer side of the tailing treatment main body (1); broken mechanism of roll extrusion formula thermal cycle (2) rolls subassembly (12), microwave internal reflection formula drive assembly (13) and prevents that the tails glues glutinous heating element (14) including the bounce type, the bounce type rolls inside tailing processing main part (1) is located in subassembly (12), locate the bounce type in microwave internal reflection formula drive assembly (13) and roll on subassembly (12), prevent that the tails glues glutinous heating element (14) and locate the bounce type and roll in subassembly (12).

2. The liftable equipment for treating the mine waste according to claim 1, wherein: the tailing processing main body (1) comprises a crushing shell (5), a crushing cavity (6), a separation cavity (7), a first feed inlet (8), a discharge outlet (9), a connecting plate (10) and a supporting transverse rod (11), the crushing shell (5) is arranged on the tailing processing main body (1), the inner upside of the crushing shell (5) is arranged in the crushing cavity (6), the inner downside of the crushing shell (5) is arranged in the separation cavity (7), one side of the crushing cavity (6) is arranged in the first feed inlet (8), the rear side end of the crushing shell (5) is arranged in the discharge outlet (9), the connecting plate (10) is arranged on the first feed inlet (8), and the supporting transverse rod (11) is arranged on the discharge outlet (9).

3. The liftable equipment for treating the mine waste according to claim 2, wherein: the utility model discloses a microwave heating roller, including bounce type rolling subassembly (12) including broken circular telegram steel ball (15), thickening ring rolling track (16), circular telegram layer (17), protruding sloping block (18), feed inlet two (19) and electronic valve (20), the thickening ring rolls on track (16) locates microwave internal reflection type drive assembly (13), broken circular telegram steel ball (15) roll locate the thickening ring roll in track (16), circular telegram layer (17) are located the thickening ring and are rolled on the inner wall of track (16), protruding sloping block (18) are located the thickening ring and are rolled on the inner wall of track (16), the thickening ring is located in feed inlet two (19) and are rolled on track (16), electronic valve (20) are located on feed inlet two (19).

4. A liftable in-mine waste disposal apparatus according to claim 3, wherein: reflection-type drive assembly (13) includes driving motor (21), axis of rotation (22), connecting pipe (23) and magnetron (24) in the microwave, the outside in broken chamber (6) is located in driving motor (21), in broken chamber (6) is located in rotation axis (22) rotation, the output of driving motor (21) is located to the one end of axis of rotation (22), the one end of connecting pipe (23) is located on axis of rotation (22), the other end of axis of rotation (22) link up and locate the inboard that the thickening ring rolled track (16), magnetron (24) are located in connecting pipe (23).

5. The liftable equipment for treating the mine waste according to claim 4, wherein: prevent that tails glues glutinous heating element (14) including graphite alkene layer (25), broken layer (26), striking chamber (27), striking iron ball (28) and protruding piece (29), broken layer (26) are located the skin of broken circular telegram steel ball (15), the inlayer of broken layer (26) is located in graphite alkene layer (25), the inside of graphite alkene layer (25) is located in striking chamber (27), on the inner wall of broken layer (26) is located in protruding piece (29), striking iron ball (28) roll is located in striking chamber (27).

6. The liftable equipment for treating the mine waste according to claim 5, wherein: the multi-gravity tailing separation mechanism (3) comprises a vertical component force multi-gravity screening assembly (30) and a through type rotary driving assembly (31), the through type rotary driving assembly (31) is arranged on the outer side of the separation cavity (7), and the vertical component force multi-gravity screening assembly (30) is arranged on the through type rotary driving assembly (31).

7. The liftable equipment for treating mine waste according to claim 6, wherein: vertical component multi-gravitation screening subassembly (30) is including rotating cylinder (32), strong magnet (33), separation hole (34), bearing (35), bracing piece (37) and dragging piece (38), support on horizontal pole (11) is located in bearing (35), the one end of rotating cylinder (32) is located on bearing (35), the other end of rotating cylinder (32) rotates and locates on the lateral wall of disengagement chamber (7), separation hole (34) are located on rotating cylinder (32), the one end of rotating cylinder (32) is located in bracing piece (37), the one end of strong magnet (33) is located on bracing piece (37), the other end of strong magnet (33) link up and locate the inside one end of rotating cylinder (32), drag piece (38) and locate the inside lower extreme of disengagement chamber (7).

8. The liftable equipment for treating mine waste according to claim 7, wherein: through-type rotation driving subassembly (31) includes motor two (39), gear one (40), gear two (41), bearing two (42), air pump (43), gas-supply pipe (44), annular interface (45), filter screen (46) and collecting box (57), motor two (39) are located on the lateral wall of separation chamber (7), the output of motor two (39) is located in gear one (40), gear two (41) cup joint and locate the one end that rotates cylinder (32), gear one (40) and gear two (41) link to each other for meshing rotation, bearing two (42) link up and locate the one end that rotates cylinder (32), air pump (43) are located on the lateral wall of separation chamber (7), the one end of gas-supply pipe (44) link up and locate the output of air pump (43), the other end of gas-supply pipe (44) link up and locate on bearing two (42), annular interface (45) link up and locate on the axle that rotates cylinder (32), the one end that annular interface (45) located rotates gas-supply pipe (32) link up, the collecting box (57) is located on the discharge gate (57), discharge gate (57) one side of discharge gate (46).

9. The liftable equipment for treating mine waste according to claim 8, wherein: simple pendulum formula material loading elevating system (4) is including transportation frame (47), motor three (48), axis of rotation two (49), transportation area (50), baffle (51), hinge (52), hinge two (53), spout (54), pulley (55) and cylinder (56), the lower extreme of feed inlet (8) is located in hinge one (52), the one end of transportation frame (47) is located on hinge one (52), on broken casing (5) is located in cylinder (56), the output of cylinder (56) is located in hinge two (53), axis of rotation two (49) are rotated and are located in transportation frame (47), the outside of transportation frame (47) is located in axis of rotation two (49), the output of motor three (48) is located to the one end of axis of rotation two (49), axis of rotation two (49) are located in the cup joint of belt (50), baffle (51) are located on transportation area (50), the lower extreme of transportation frame (47) is located in spout (54), the one end slip of pulley (55) is located in spout (54), two (53) go up the other end of pulley (55).

10. The liftable equipment for treating mine waste according to claim 9, wherein: the rotating roller (32) is provided with a collecting brush (58).