CN216460064U - Feeding structure for ore dressing - Google Patents

Abstract

The utility model provides a feed arrangement for ore dressing relates to mineral processing equipment technical field, including the feeding storehouse, one side external surface fixation in feeding storehouse has the support frame, the top of support frame is fixed with vibrating motor. The utility model discloses, in the material gets into the feeding storehouse, vibrating motor can drive the screening otter board and shake, because the surface of screening otter board has little gap, so less material can be screened the cambered plate at the in-process of vibrations, again by the output of tiny particle output pipeline, the great material that is not screened can get into large granule output pipeline and export, the device functionality has been strengthened, so can be with the material of good size of preliminary classification at the in-process of output because large granule output pipeline all is fixed with a plurality of division boards with tiny particle output pipeline's inside, separately export, there is certain buffer function, can prevent that the material from once only gushing out too much, improve the device practicality.

Description

Feeding structure for ore dressing

Technical Field

The utility model relates to a mineral processing equipment technical field especially relates to a feeding structure for ore dressing.

Background

Mineral separation is a process of crushing and grinding ores according to the physical and chemical properties of different minerals in the ores, separating useful minerals from gangue minerals by methods such as gravity separation, flotation, magnetic separation, electric separation and the like, separating various symbiotic useful minerals from each other as much as possible, and removing or reducing harmful impurities to obtain raw materials required by smelting or other industries.

However, in the prior art, in the current mineral separation process, all processes are buckled with each other in a ring manner, however, the first step of the mineral separation process is to pour materials into a feeding pipeline, so that all processes are communicated, because the current feeding pipeline is only to simply put in mineral materials, no practical functionality exists, most of the traditional feeding modules are manually fed, the practicability of the device is low, a large amount of labor force can be consumed, the mineral separation cost is increased, and the feeding process is complicated.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcoming that exists among the prior art, vibrating motor can drive the screening otter board and shake, because the surface of screening otter board has little gap, so can be screened the cambered plate at the less material of in-process of vibrations, has strengthened the device functionality.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a feeding structure for ore dressing, includes the feeding storehouse, one side external fixed surface in feeding storehouse has the support frame, the top of support frame is fixed with vibrating motor, vibrating motor's output shaft is fixed with the screening otter board, and the interior table wall swing joint in screening otter board and feeding storehouse, the inside bottom surface in feeding storehouse is fixed with the cambered plate, one side exterior wall intercommunication in feeding storehouse has large granule output pipeline, large granule output pipeline's inside bottom surface equidistance is fixed with a plurality of division boards, large granule output pipeline's one end is fixed with the linking ring, one side exterior wall in feeding storehouse is close to bottom edge intercommunication and has tiny particle output pipeline, and tiny particle output pipeline's inside bottom surface equidistance is fixed with a plurality of division boards to tiny particle output pipeline's one end is fixed with the linking ring.

Preferably, the base is fixed on the outer surface of the other side of the feeding bin close to the edge of the bottom, and a first motor is fixed on the bottom surface of the inner part of the base.

Preferably, a material bin is fixed at the bottom of the base, and a rotating rod is fixed on an output shaft of the first motor.

Preferably, the surface cover of bull stick is equipped with the material loading auger, the inside intercommunication of material storehouse has the transportation pipeline, and the surface of material loading auger is located to transportation pipeline slip cap to the one end of transportation pipeline extends in the inside in feeding storehouse.

Preferably, two square grooves are formed in the rear surface wall inside the feeding bin, and a second motor is fixed inside each square groove.

Preferably, the output shafts of the two second motors are fixed with rotating shafts, and the outer surfaces of the rotating shafts are sleeved with speed reduction blades.

Compared with the prior art, the utility model has the advantages and positive effects that,

1. the utility model discloses in, in the material gets into the feeding storehouse, vibrating motor can drive the screening otter board and shake, because the surface of screening otter board has little gap, so less material can be screened the cambered plate at the in-process of vibrations, again by the output of tiny particle delivery pipeline, the great material that is not screened can get into large granule delivery pipeline and export, the device functionality has been strengthened, so can be with the material of good size of preliminary classification at the in-process of output because large granule delivery pipeline all is fixed with a plurality of division boards with tiny particle delivery pipeline's inside, separately export, there is certain buffer function, can prevent that the material from once only gushing out too much, improve the device practicality.

2. The utility model discloses in, drive the rotation of bull stick by first motor, make the material of placing inside the material storehouse begin to be transported to the material of material loading auger, make material loading auger material loading to the feeding storehouse in, when the material enters into the feeding storehouse, it drives the pivot rotation to start the second motor, buffering blade begins to rotate this moment, the material is under buffering blade's drive, can slowly and have the spaced bottom that drops to the feeding storehouse, make the device have buffering effect, make the device can not highly drop and cause the damage by the material for a long time, and avoid the material to cause blocking phenomenon at the feeding in-process feeding too much to the feeding storehouse, improve the device practicality.

Drawings

Fig. 1 is a front sectional view of a feeding structure for mineral separation according to the present invention;

fig. 2 is a partial side sectional view of a transportation pipeline of the feeding structure for mineral separation according to the present invention;

fig. 3 is a side sectional view of a rotating shaft part of a feeding structure for mineral separation according to the present invention;

fig. 4 is the utility model provides a feed structure's joining ring partially side view is used in ore dressing.

Illustration of the drawings:

1. a base; 101. a first motor; 2. a material bin; 3. a rotating rod; 4. a feeding auger; 5. a transport pipeline; 6. a feeding bin; 7. a square groove; 8. a second motor; 9. a rotating shaft; 10. a decelerating blade; 11. a vibration motor; 12. a support frame; 13. screening a screen plate; 14. an arcuate panel; 15. a large particle output pipeline; 16. a small particle output pipe; 17. a partition plate; 18. an adaptor ring.

Detailed Description

In order to make the above objects, features and advantages of the present invention more clearly understood, the present invention will be further described with reference to the accompanying drawings and examples. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the present invention is not limited to the limitations of the specific embodiments of the present disclosure.

Embodiment 1, as shown in fig. 1-4, the utility model provides a feeding structure for mineral separation, which comprises a feeding bin 6, a supporting frame 12 fixed on the outer surface of one side of the feeding bin 6, a vibrating motor 11 fixed on the top of the supporting frame 12, a screening mesh plate 13 fixed on the output shaft of the vibrating motor 11, the screening net plate 13 is movably connected with the inner surface wall of the feeding bin 6, an arc-shaped panel 14 is fixed on the inner bottom surface of the feeding bin 6, a large particle output pipeline 15 is communicated with the outer surface wall on one side of the feeding bin 6, a plurality of partition plates 17 are fixed on the inner bottom surface of the large particle output pipeline 15 at equal intervals, a connecting ring 18 is fixed on one end of the large particle output pipeline 15, a small particle output pipeline 16 is communicated with the edge, close to the bottom, of the outer surface wall on one side of the feeding bin 6, and a plurality of partition plates 17 are fixed to the inner bottom surface of the small particle output duct 16 at equal intervals, and a coupling ring 18 is fixed to one end of the small particle output duct 16.

The whole embodiment 1 achieves the effect that when the material enters the feeding bin 6, the vibrating motor 11 drives the screening net plate 13 to vibrate, and because the surface of the screening net plate 13 is provided with small gaps, so that during the shaking process, the smaller materials are screened onto the curved panel 14 and then discharged through the small particle discharge duct 16, and the larger materials that are not screened enter the large particle discharge duct 15 for discharge, because the large particle output pipeline 15 and the small particle output pipeline 16 are both internally fixed with a plurality of partition plates 17, materials with preliminarily classified sizes can be separately output in the output process, and the large particle output pipeline and the small particle output pipeline have certain buffer function, the material can be prevented from overflowing too much at one time, the connecting rings 18 are fixed at one ends of the large particle output pipeline 15 and the small particle output pipeline 16, so that the feeding structure can be conveniently connected with a next process device, and the model of the vibration motor 11 is YZU-1-2.

Embodiment 2, as shown in fig. 1-3, the opposite side surface of feeding storehouse 6 is close to bottom edge and is fixed with base 1, the inside bottom surface of base 1 is fixed with first motor 101, the bottom of base 1 is fixed with material storehouse 2, the output shaft of first motor 101 is fixed with bull stick 3, the surface cover of bull stick 3 is equipped with material loading auger 4, the inside intercommunication of material storehouse 2 has transport pipeline 5, and transport pipeline 5 sliding sleeve locates the surface of material loading auger 4, and the one end of transport pipeline 5 extends in the inside of feeding storehouse 6, two square grooves 7 have been seted up to the inside back table wall of feeding storehouse 6, the inside of two square grooves 7 all is fixed with second motor 8, the output shaft of two second motors 8 all is fixed with pivot 9, the surface cover of pivot 9 is equipped with speed reduction blade 10.

The whole embodiment 2 achieves the effect that the first motor 101 drives the rotation of the rotating rod 3, so that the feeding auger 4 starts to transport the materials placed in the material bin 2, the feeding auger 4 feeds the materials into the feeding bin 6, when the materials enter the feeding bin 6, the second motor 8 is started to drive the rotating shaft 9 to rotate, the speed reduction blade 10 starts to rotate at the moment, the materials can slowly and intermittently fall to the bottom of the feeding bin 6 under the driving of the speed reduction blade 10, the device has a buffering effect, the device cannot be damaged due to long-term high falling of the materials, the phenomenon that the materials are excessively fed in the feeding process to block the feeding bin 6 is avoided, the practicability of the device is improved, the model of the first motor 101 is YCT112-4B, and the model of the second motor 8 is 0.09 KW-56-4P.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in other forms, and any person skilled in the art may use the above-mentioned technical contents to change or modify the equivalent embodiment into equivalent changes and apply to other fields, but any simple modification, equivalent change and modification made to the above embodiments according to the technical matters of the present invention will still fall within the protection scope of the technical solution of the present invention.

Claims (6)

1. The utility model provides a feeding structure for ore dressing, includes feeding storehouse (6), its characterized in that: the outer fixed surface of one side of feeding storehouse (6) has support frame (12), the top of support frame (12) is fixed with vibrating motor (11), the output shaft of vibrating motor (11) is fixed with screening otter board (13), and screens otter board (13) and the interior table wall swing joint in feeding storehouse (6), the inside bottom surface in feeding storehouse (6) is fixed with arc panel (14), one side outward appearance wall intercommunication in feeding storehouse (6) has large granule output pipeline (15), the inside bottom surface equidistance of large granule output pipeline (15) is fixed with a plurality of division boards (17), the one end of large granule output pipeline (15) is fixed with links up ring (18), one side outward appearance wall in feeding storehouse (6) is close to bottom edge intercommunication has small granule output pipeline (16), and the inside bottom surface equidistance of small granule output pipeline (16) is fixed with a plurality of division boards (17), and one end of the small particle output pipeline (16) is fixed with an adapter ring (18).

2. A feeding structure for mineral processing according to claim 1, characterized in that: the outer surface of the other side of the feeding bin (6) is fixed with a base (1) close to the edge of the bottom, and a first motor (101) is fixed on the bottom surface of the inner portion of the base (1).

3. A feeding structure for mineral processing according to claim 2, characterized in that: the bottom of base (1) is fixed with material storehouse (2), the output shaft of first motor (101) is fixed with bull stick (3).

4. A feeding structure for mineral processing according to claim 3, characterized in that: the surface cover of bull stick (3) is equipped with material loading auger (4), the inside intercommunication of material storehouse (2) has transportation pipeline (5), and transportation pipeline (5) slip cap locates the surface of material loading auger (4) to the one end of transportation pipeline (5) extends in the inside in feed storehouse (6).

5. A feeding structure for mineral processing according to claim 1, characterized in that: two square grooves (7) are formed in the back surface wall of the interior of the feeding bin (6), and a second motor (8) is fixed inside each square groove (7).

6. A feeding structure for mineral processing according to claim 5, characterized in that: and the output shafts of the two second motors (8) are respectively fixed with a rotating shaft (9), and the outer surface of the rotating shaft (9) is sleeved with a speed reduction blade (10).

Images