CN218967964U

CN218967964U - Mining motor vibration feeder

Info

Publication number: CN218967964U
Application number: CN202223323056.XU
Authority: CN
Inventors: 滕雷
Original assignee: Xuzhou Zhongshun Electromechanical Technology Co ltd
Current assignee: Xuzhou Zhongshun Electromechanical Technology Co ltd
Priority date: 2022-12-12
Filing date: 2022-12-12
Publication date: 2023-05-05
Anticipated expiration: 2032-12-12

Abstract

The utility model discloses a mining motor vibration feeder, which comprises a feeder body, wherein a discharging bin is arranged at one side of the top of the feeder body, and a discharging hopper is arranged at the upper part of the discharging bin; the vibratory feeding mechanism is arranged at the upper part in the feeder body and comprises a feeding slope, slag leakage holes are arrayed on the feeding slope, and a collecting bin is arranged at one end, far away from the discharging hopper, of the feeder body; the slag feeding mechanism is arranged below the vibration feeding mechanism and comprises an inclined slag slideway, and a slag recovery guide slope is arranged below the collecting bin; the main driving mechanism is arranged at one end, close to the discharging hopper, inside the feeder body and is used for driving and controlling the vibration feeding mechanism and the slag feeding mechanism. The utility model aims to solve the technical problems of overcoming the defects of the prior art and providing the mining motor vibration feeder which is reasonable in structure, high in efficiency, stable and reliable, and has the screening function while providing the vibration feeding function.

Description

Mining motor vibration feeder

Technical Field

The utility model relates to the technical field of vibration feeders, in particular to a mining motor vibration feeder.

Background

The vibrating feeder is also called as a vibrating feeder, can continuously and uniformly feed for crushing machines in a sand production line, is widely applied to crushing and screening combined equipment in industries such as mines, metallurgy, coal and the like, and is generally formed by combining a vibrating frame, a vibrating body, a vibrating motor, a vibration exciter, a spring and the like.

The existing vibrating feeder only has the vibrating feeding function, and when mineral raw materials are conveyed in a working mode according to the size and the volume screening function, the mineral raw materials are relatively miscellaneous in volume, the later period is required to be screened again, and the mineral raw material particle dust to be crushed is fed into the later period treatment work, so that dust pollution is easily caused, and the problem of the existing technology is solved urgently.

Disclosure of Invention

The utility model aims to solve the technical problems of overcoming the defects of the prior art and providing the mining motor vibration feeder which is reasonable in structure, high in efficiency, stable and reliable, and has the screening function while providing the vibration feeding function.

In order to solve the technical problems, the technical scheme provided by the utility model is as follows: a mining motor vibratory feeder comprising:

the feeding machine comprises a feeder body, wherein a discharging bin is arranged on one side of the top of the feeder body, and a discharging hopper is arranged on the upper part of the discharging bin;

the vibrating feeding mechanism is arranged at the upper part in the feeder body and comprises a feeding slope, slag leakage holes are arrayed on the feeding slope, a collecting bin is arranged at one end, far away from the blanking hopper, of the feeder body, the outlet end of the feeding slope is communicated with the inlet end of the collecting bin, and a charging slideway is arranged at one side of the collecting bin;

the slag feeding mechanism is arranged below the vibration feeding mechanism and comprises an inclined slag slideway, a slag recycling guide slope is arranged below the collecting bin, and two ends of the slag recycling guide slope are respectively fixed on two side inner walls of the feeder body;

the total driving mechanism is arranged at one end, close to the discharging hopper, inside the feeder body and is used for driving and controlling the vibration feeding mechanism and the slag feeding mechanism.

Further, the vibration feeding mechanism is fixedly provided with an L-shaped support plate close to one end of the total driving mechanism, two ends of the L-shaped support plate are respectively provided with a side vibrating plate, the upper ends of the side vibrating plates are connected with a vibration center shaft, two ends of the vibration center shaft are respectively and rotatably connected with two side inner walls of the feeder body, and a cam plate is arranged at the position of the side vibrating plates in a rotating mode.

Further, a center shaft belt wheel is arranged on the vibration center shaft, a driving belt wheel is arranged below the center shaft belt wheel, the driving belt wheel is connected with the center shaft belt wheel through a first belt, a belt groove for the first belt to pass through is formed in the L-shaped support plate, a driving center shaft is arranged at the center of the driving belt wheel, two ends of the driving center shaft are respectively and rotatably connected with a center shaft support, the center shaft support is fixed inside the feeder body, a first speed reduction belt wheel is further arranged on the driving center shaft, a speed reduction motor is arranged below the first speed reduction belt wheel, the output shaft end of the speed reduction motor is connected with a second speed reduction belt wheel, and the first speed reduction belt wheel is connected with the second speed reduction belt wheel through a second belt.

Further, the both sides of sending the stock slope are provided with the pay-off striker plate, the outside of pay-off striker plate is provided with the slip spout, sliding connection has the slip clamp plate in the slip spout, the slip clamp plate inboard rotates through T shape and connects in the slip spout, the slip clamp plate middle part runs through and is provided with flexible slide bar, flexible slide bar lower extreme is provided with down the baffle, flexible slide bar upper end is rotated through the vibration pivot and is connected the inner wall of batcher organism, between vibration pivot and the slip clamp plate vibration spring cup joints respectively on the flexible slide bar between baffle down and the slip clamp plate.

Further, a driving turntable is arranged at one extending end of the driving central shaft, a power transmission rod is rotatably connected to the driving turntable near the edge of the driving turntable, and the other end of the power transmission rod is rotatably connected with the end part of the inclined slag slideway.

Further, the middle part of the power transmission rod is provided with a bidirectional adjusting screw rod, and the bidirectional adjusting screw rod is used for adjusting the length of the power transmission rod.

Further, the below of slope slay slide is provided with the angle steel guide rail of opening downwardly, the both ends of angle steel guide rail are fixed inside the batcher organism, the bottom of slope slay slide is provided with the slip gyro wheel, the slip gyro wheel cooperation is connected on the slope slay slide.

Further, the bottom of the feeder body is provided with supporting legs, and the lower ends of the supporting legs are provided with fixing plates.

Further, the top connection of collecting the feed bin is provided with the dust removal pipe.

Compared with the prior art, the utility model has the advantages that: according to the utility model, the traditional vibrating feeder is improved, the efficient vibrating feeding of the vibrating feeding mechanism is realized through the cooperation of the rotating rod and the spring, meanwhile, the operation of the vibrating feeding mechanism and the slag feeding mechanism is simultaneously controlled by one gear motor, and slag waste powder slag and the like can be rapidly collected and intensively cleaned while mineral materials are conveyed, so that the procedures of later cleaning and further screening are reduced, the synchronous screening efficiency in the feeding process is improved, the problems of environmental pollution and slag jam of equipment are reduced, the service life of the equipment is prolonged, and the device is efficient and stable and is suitable for popularization and use.

Drawings

Fig. 1 is a schematic view of an external perspective structure of the present utility model.

Fig. 2 is a schematic view of the structure of the inside of the present utility model.

Fig. 3 is a schematic diagram of the overall driving mechanism in the present utility model.

FIG. 4 is an enlarged schematic view of the structure at the vibrating center axis in the present utility model.

Fig. 5 is an enlarged schematic view of the structure at the sliding platen in the present utility model.

As shown in the figure: 1. a feeder body; 1-1, supporting legs; 1-2, discharging the material from a material bin; 1-3, discharging hoppers; 1-4, collecting bin; 1-5, a loading slideway; 1-6, slag recycling and guiding slope; 1-7, a dust removing pipe;

2. a vibratory feeding mechanism; 2-1, feeding slopes; 2-2, slag leakage holes; 2-3, feeding baffle plates; 2-4, sliding chute; 2-5, sliding pressing plate; 2-6, T-shaped rotating piece; 2-7, a telescopic slide bar; 2-8, lower baffle; 2-9, vibrating the rotating shaft; 2-10, vibrating springs;

3. slag feeding mechanism; 3-1, tilting the slag runner; 3-2, angle steel guide rails; 3-3, sliding rollers;

4. a total driving mechanism; 4-1, L-shaped support plates; 4-2, side vibrating plates; 4-3, vibrating the middle shaft; 4-4, a cam plate; 4-5, a middle shaft belt wheel; 4-6, driving belt wheels; 4-7, a belt groove; 4-8, a central shaft support; 4-9, a first reduction belt wheel; 4-10, a speed reducing motor; 4-11, driving a turntable; 4-12, a power transmission rod.

Detailed Description

In the description of the present utility model, it should be understood that the terms "center," "lateral," "upper," "lower," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more. In addition, the term "include" and any variations thereof are intended to cover a non-exclusive inclusion.

The present utility model will be described in further detail with reference to the accompanying drawings.

When the utility model is embodied, the mining motor vibration feeder, which is shown in combination with figures 1-5, comprises:

the feeding machine comprises a feeder body 1, wherein a discharging bin 1-2 is arranged on one side of the top of the feeder body 1, and a discharging hopper 1-3 is arranged on the upper part of the discharging bin 1-2; and the total driving mechanism 4 is arranged at one end, close to the discharging hopper 1-3, inside the feeder body 1, and the total driving mechanism 4 is used for driving and controlling the vibration feeding mechanism 2 and the slag feeding mechanism 3.

The bottom of the feeder body 1 is provided with a supporting leg 1-1, the lower end of the supporting leg 1-1 is provided with a fixed plate, and the top of the collecting bin 1-4 is connected with a dust removing pipe 1-7.

The vibratory feeding mechanism 2 is arranged at the upper part in the feeder body 1, the vibratory feeding mechanism 2 comprises a feeding slope 2-1, slag leakage holes 2-2 are arrayed on the feeding slope 2-1, a collecting bin 1-4 is arranged at one end, far away from the discharging bin 1-3, of the feeder body 1, the outlet end of the feeding slope 2-1 is communicated with the inlet end of the collecting bin 1-4, and a charging slideway 1-5 is arranged at one side of the collecting bin 1-4; an L-shaped supporting plate 4-1 is fixedly arranged at one end, close to the total driving mechanism 4, of the vibration feeding mechanism 2, side vibrating plates 4-2 are respectively arranged at two ends of the L-shaped supporting plate 4-1, the upper ends of the side vibrating plates 4-2 are connected with a vibration center shaft 4-3, two ends of the vibration center shaft 4-3 are respectively and rotatably connected to the inner walls of two sides of the feeder body 1, a cam plate 4-4 is arranged at the position, rotationally connected with the side vibrating plates 4-2, of the vibration center shaft 4-3, a center shaft belt pulley 4-5 is arranged, a driving belt pulley 4-6 is arranged below the center shaft belt pulley 4-5, the driving belt pulley 4-6 is connected with the center shaft belt pulley 4-5 through a first belt, a belt groove 4-7 for the first belt to pass through is arranged on the L-shaped supporting plate 4-1, the center of the driving belt wheel 4-6 is provided with a driving central shaft, two ends of the driving central shaft are respectively and rotatably connected with a central shaft support 4-8, the central shaft support 4-8 is fixed inside the feeder body 1, a first reduction belt wheel 4-9 is further arranged on the driving central shaft, a reduction motor 4-10 is arranged below the first reduction belt wheel 4-9, an output shaft end of the reduction motor 4-10 is connected with a second reduction belt wheel, the first reduction belt wheel 4-9 is connected with the second reduction belt wheel through a second belt, the reduction motor 4-10 is started to drive the first reduction belt wheel 4-9 to rotate and drive the coaxial driving belt wheel 4-6 to rotate, and the central shaft belt wheel 4-5 is synchronously driven to continuously rotate, so that the vibration central shaft 4-3 continuously rotates.

As a vibration structure, as shown in FIG. 5, two sides of a feeding slope 2-1 are provided with feeding baffle plates 2-3, the outer sides of the feeding baffle plates 2-3 are provided with sliding grooves 2-4, the sliding grooves 2-4 are in sliding connection with sliding pressing plates 2-5, the inner sides of the sliding pressing plates 2-5 are rotationally connected with the sliding grooves 2-4 through T-shaped rotating pieces 2-6, the middle parts of the sliding pressing plates 2-5 are penetrated and provided with telescopic sliding rods 2-7, the lower ends of the telescopic sliding rods 2-7 are provided with lower baffle plates 2-8, the upper ends of the telescopic sliding rods 2-7 are rotationally connected with the inner wall of a feeder body 1 through a vibrating rotating shaft 2-9, vibrating springs 2-10 are respectively sleeved on the telescopic sliding rods 2-7 between the vibrating rotating shaft 2-9 and the sliding pressing plates 2-5, and the whole vibrating feeding mechanism 2-vibrates, and the sliding pressing plates 2-5 on the two sides of the sliding pressing plates are matched to reciprocate on the telescopic sliding rods 2-7, and the upper and lower vibrating springs 2-10 provide a vibration buffering effect, so that ore materials are conveyed to the storage bin 1-4 downwards more efficiently.

The slag feeding mechanism 3 is arranged below the vibration feeding mechanism 2, the slag feeding mechanism 3 comprises an inclined slag slideway 3-1, a slag recovery guide slope 1-6 is arranged below the collecting bin 1-4, and two ends of the slag recovery guide slope 1-6 are respectively fixed on two side inner walls of the feeder body 1; one side extension end of the driving center shaft is provided with a driving turntable 4-11, the driving turntable 4-11 is close to the edge of the driving turntable and is rotationally connected with a power transmission rod 4-12, the other end of the power transmission rod 4-12 is rotationally connected with the end part of the inclined slag slideway 3-1, the middle part of the power transmission rod 4-12 is provided with a bidirectional adjusting screw rod, and the bidirectional adjusting screw rod is used for adjusting the length of the power transmission rod 4-12, so that the length of the power transmission rod 4-12 is conveniently adjusted to control the shaking amplitude. The lower part of the inclined slag slide way 3-1 is provided with an angle steel guide rail 3-2 with a downward opening, two ends of the angle steel guide rail 3-2 are fixed inside the feeder body 1, the bottom of the inclined slag slide way 3-1 is provided with a sliding roller 3-3, and the sliding roller 3-3 is connected to the inclined slag slide way 3-1 in a matched manner.

In the actual use process of the device, mineral aggregate enters the device through the blanking hopper 1-3, falls onto the vibration feeding mechanism 2 and is conveyed through the feeding slope 2-1, in the process, the gear motor 4-10 is started to drive the first reduction belt pulley 4-9 to rotate and drive the coaxial driving belt pulley 4-6 to rotate, and synchronously drives the middle shaft belt pulley 4-5 to continuously rotate, so that the vibration middle shaft 4-3 continuously rotates;

while the vibration center shaft 4-3 continuously rotates, the cam plate 4-4 rotates along with the rotation to drive the side vibration plate 4-2 to rotate in a non-concentric rotation mode, so that the whole vibration feeding mechanism 2 vibrates, the sliding pressing plates 2-5 on two sides of the vibration center shaft reciprocate on the telescopic sliding rod 2-7, and the upper vibration spring 2-10 and the lower vibration spring provide vibration buffering effects, so that mineral aggregate is more efficiently conveyed downwards to the collecting bin 1-4 and falls from the charging slideway 1-5 to be collected or loaded in the next step;

in step, the driving turntable 4-11 continuously rotates, the inclined slag slideway 3-1 is driven to continuously shake by the power transmission rod 4-12, and the sliding roller 3-3 at the bottom of the driving turntable is connected to the inclined slag slideway 3-1 in a matched manner, so that the shaking stability is maintained, and slag and other impurities slide down from the slag recycling guide slope 1-6 and are uniformly collected.

The utility model and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims

1. A mining motor vibratory feeder, comprising:

the feeding machine comprises a feeder body (1), wherein a discharging bin (1-2) is arranged on one side of the top of the feeder body (1), and a discharging hopper (1-3) is arranged on the upper part of the discharging bin (1-2);

the feeding device comprises a vibrating feeding mechanism (2), wherein the vibrating feeding mechanism (2) is arranged at the upper part in a feeder body (1), the vibrating feeding mechanism (2) comprises a feeding slope (2-1), slag leakage holes (2-2) are arranged on the feeding slope (2-1) in an array mode, a collecting bin (1-4) is arranged at one end, away from a discharging hopper (1-3), of the feeder body (1), an outlet end of the feeding slope (2-1) is communicated with an inlet end of the collecting bin (1-4), and a charging slideway (1-5) is arranged at one side of the collecting bin (1-4);

the slag feeding mechanism (3), the slag feeding mechanism (3) is arranged below the vibration feeding mechanism (2), the slag feeding mechanism (3) comprises an inclined slag slideway (3-1), a slag recycling guide slope (1-6) is arranged below the collecting bin (1-4), and two ends of the slag recycling guide slope (1-6) are respectively fixed on two side inner walls of the feeder body (1);

the feeding machine comprises a main driving mechanism (4), wherein the main driving mechanism (4) is arranged at one end, close to a discharging hopper (1-3), inside a feeder body (1), and the main driving mechanism (4) is used for driving and controlling the vibration feeding mechanism (2) and the slag feeding mechanism (3).

2. The mining motor vibratory feeder of claim 1, wherein: the vibrating feeder is characterized in that an L-shaped supporting plate (4-1) is fixedly arranged on the vibrating feeding mechanism (2) and close to one end of the total driving mechanism (4), side vibrating plates (4-2) are respectively arranged at two ends of the L-shaped supporting plate (4-1), a vibrating center shaft (4-3) is connected to the upper end of each side vibrating plate (4-2), two ends of each vibrating center shaft (4-3) are respectively and rotatably connected to two side inner walls of the feeder body (1), and cam plates (4-4) are arranged at the positions of the vibrating center shafts (4-3) and the side vibrating plates (4-2).

3. The mining motor vibratory feeder of claim 2, wherein: the novel vibrating feeding machine is characterized in that a center shaft belt wheel (4-5) is arranged on the vibrating center shaft (4-3), a driving belt wheel (4-6) is arranged below the center shaft belt wheel (4-5), the driving belt wheel (4-6) is connected with the center shaft belt wheel (4-5) through a first belt, a belt groove (4-7) for a first belt to pass through is formed in the L-shaped support plate (4-1), a driving center shaft is arranged at the center of the driving belt wheel (4-6), center shaft supports (4-8) are respectively connected at two ends of the driving center shaft in a rotating mode, the center shaft supports (4-8) are fixed inside the feeding machine body (1), a first speed reducing belt wheel (4-9) is further arranged on the driving center shaft, a speed reducing motor (4-10) is arranged below the first speed reducing belt wheel (4-9), the output end of the speed reducing motor (4-10) is connected with a second speed reducing belt wheel, and the first speed reducing belt wheel (4-9) is connected with the second speed reducing belt wheel through a second belt.

4. A mining electric motor vibratory feeder as set forth in claim 3 wherein: the feeding machine is characterized in that feeding baffle plates (2-3) are arranged on two sides of a feeding slope (2-1), sliding grooves (2-4) are formed in the outer sides of the feeding baffle plates (2-3), sliding pressing plates (2-5) are connected in a sliding mode in the sliding grooves (2-4) in a sliding mode, inner sides of the sliding pressing plates (2-5) are connected in a rotating mode through T-shaped rotating pieces (2-6), telescopic sliding rods (2-7) are arranged in the middle of the sliding pressing plates (2-5) in a penetrating mode, lower baffle plates (2-8) are arranged at the lower ends of the telescopic sliding rods (2-7), the upper ends of the telescopic sliding rods (2-7) are connected with the inner wall of the feeding machine body (1) in a rotating mode through vibrating rotating shafts (2-9), and vibrating springs (2-10) are sleeved on the telescopic sliding rods (2-7) between the vibrating rotating shafts (2-9) and the sliding pressing plates (2-5).

5. The mining motor vibratory feeder of claim 4, wherein: one side extension end of the driving central shaft is provided with a driving turntable (4-11), the driving turntable (4-11) is close to the edge of the driving turntable and is rotationally connected with a power transmission rod (4-12), and the other end of the power transmission rod (4-12) is rotationally connected with the end part of the inclined slag slideway (3-1).

6. The mining motor vibratory feeder of claim 5, wherein: the middle part of the power transmission rod (4-12) is provided with a bidirectional adjusting screw rod, and the bidirectional adjusting screw rod is used for adjusting the length of the power transmission rod (4-12).

7. The mining motor vibratory feeder of claim 6, wherein: the automatic feeding machine is characterized in that an angle steel guide rail (3-2) with a downward opening is arranged below the inclined slag slide rail (3-1), two ends of the angle steel guide rail (3-2) are fixed inside the feeder body (1), a sliding roller (3-3) is arranged at the bottom of the inclined slag slide rail (3-1), and the sliding roller (3-3) is connected to the inclined slag slide rail (3-1) in a matched mode.

8. The mining motor vibratory feeder of claim 1, wherein: the bottom of the feeder body (1) is provided with supporting legs (1-1), and the lower ends of the supporting legs (1-1) are provided with fixing plates.

9. The mining motor vibratory feeder of claim 1, wherein: the top of the collecting bin (1-4) is connected with a dust removing pipe (1-7).