CN111483824A

CN111483824A - Automatic bucket elevator of unloading

Info

Publication number: CN111483824A
Application number: CN202010378908.1A
Authority: CN
Inventors: 刘文荩
Original assignee: Yongkang Keka Automation Equipment Co ltd
Current assignee: Yongkang Keka Automation Equipment Co ltd
Priority date: 2020-05-07
Filing date: 2020-05-07
Publication date: 2020-08-04
Anticipated expiration: 2040-05-07
Also published as: CN111483824B

Abstract

The invention discloses an automatic discharging bucket elevator, which comprises an elevator, wherein a feeding frame is fixedly arranged on the left side of the elevator, a feeding cavity with an upward opening is arranged in the feeding frame, a first conveying cavity is arranged on the lower side of the feeding cavity, and a first magnetic sliding block is arranged in a first guide chute in a sliding manner.

Description

Automatic bucket elevator of unloading

Technical Field

The invention relates to the technical field of elevators, in particular to a bucket elevator capable of automatically discharging.

Background

The bucket elevator is a continuous conveying machine which utilizes a series of buckets uniformly and fixedly connected to an endless traction member to vertically and upwards lift materials, but the common elevator cannot realize quantitative automatic discharging, only can realize batch feeding, or can ensure quantitative output of the materials through manual timing discharging, so that the discharging speed is low, and the manpower input is increased, thereby reducing the discharging efficiency.

Disclosure of Invention

The invention aims to provide an automatic discharging bucket elevator which is used for overcoming the defects in the prior art.

The bucket elevator capable of automatically discharging comprises an elevator, wherein a feeding frame is fixedly arranged on the left side of the elevator, a feeding cavity with an upward opening is arranged in the feeding frame, a first conveying cavity is arranged on the lower side of the feeding cavity, the elevator comprises a first rotating shaft and a first roller, the first rotating shaft is rotatably arranged in the first conveying cavity, the first roller is fixedly arranged on the first rotating shaft, the first rotating shaft is vertically and symmetrically arranged, a first guide chute is arranged on the lower side of the first conveying cavity, a first magnetic sliding block is slidably arranged in the first guide chute, a first cavity is arranged on the lower side of the first guide chute, a storage bucket capable of storing materials is arranged in the first cavity, a storage cavity is arranged in the storage bucket, an input cavity with an upward opening and capable of feeding the storage bucket into the elevator body is arranged on the front side of the first cavity, a pushing device capable of feeding the storage bucket into the first cavity is arranged on, the pushing device comprises a first pushing block arranged in the input cavity, a first fixed rod fixedly arranged on the front side of the first pushing block, a second transportation cavity arranged on the lower side of the first cavity, a gravity sensing plate capable of sensing the weight of the upper side and arranged in the second transportation cavity in a sliding manner, a second guiding chute arranged on the right side of the second transportation cavity, a rack fixedly connected with the right side of the gravity sensing plate and arranged in the second guiding chute in a sliding manner, a second cavity arranged on the lower side of the second transportation cavity, a third cavity arranged on the lower side of the second cavity, an output cavity with a backward opening arranged on the rear side of the second transportation cavity, and a transportation device capable of conveying a material stored in the storage barrel into the output cavity and arranged in the third cavity, wherein the transportation device comprises a first threaded rod arranged in the third cavity, a first sliding block connected with the first threaded rod in a threaded manner and a second sliding block fixedly connected with the, The storage barrel comprises a second rotating shaft, a gear sleeve, a fourth bevel gear, a second threaded rod, a second roller, a third roller, a first conveying belt and a second pushing block, wherein the second rotating shaft is rotatably installed in a third cavity, the gear sleeve is in key connection with the second rotating shaft, the second bevel gear is fixedly installed on the gear sleeve and is meshed with the first bevel gear, the third bevel gear is fixedly installed on the gear sleeve, the third rotating shaft is rotatably installed in the third cavity, the fourth bevel gear is fixedly installed on the third rotating shaft, the second threaded rod is rotatably installed in the third cavity, the second roller is fixedly installed on the second threaded rod, the third roller is fixedly installed on the third rotating shaft, the first conveying belt is rotatably installed between the second roller and the third roller, and the second pushing block is in threaded connection with.

On the basis of the technical scheme, the upside is located at the rear side of the rotating shaft in the lifter, the first motor is connected to the inside of the lifter in a power mode, the first rotating shaft is rotatably installed in the second conveying belt, and the conveying boxes which are uniformly distributed on the second conveying belt and can draw, take and convey materials at the bottom of the first conveying cavity are fixedly arranged.

On the basis of the technical scheme, an electromagnet is fixedly arranged on the rear side of the first guide sliding groove, a telescopic rod is arranged between the electromagnet and the first sliding block, and the first sliding block is electrically connected with the gravity sensing plate.

On the basis of the technical scheme, the second pushing block comprises a cavity IV in the first fixing rod, a swing rod shaft I rotatably installed in the cavity IV, a swing rod fixedly installed on the swing rod shaft I, a swing rod shaft II hinged with the swing rod, a cavity V positioned on the front side of the input cavity, a rotating shaft IV rotatably installed in the cavity V, a rotating disc fixedly installed on the rotating shaft IV, a bevel gear V fixedly installed on the rotating shaft IV, a rotating shaft V rotatably installed in the cavity V, a bevel gear VI fixedly installed on the rotating shaft V and meshed with the bevel gear V, a cavity VI positioned on the right side of the cavity I, and a gear fixedly installed on the rotating shaft V and meshed with the rack, the rotating shaft five is rotatably installed in the cavity six, and the swing rod shaft two is fixedly connected with the rotating disc.

On the basis of the technical scheme, the transportation device comprises a cavity seventh located on the lower side of the gravity sensing plate, a guide slide block II slidably mounted in the cavity seventh, a top block I slidably mounted in the guide slide block II, a return spring I arranged between the top block I and the inner wall of the guide slide block II, a return spring II arranged between the guide slide block II and the inner wall of the elevator, a push block III fixedly connected with the rear side of the top block I, a guide slide groove III located on the lower side of the cavity seventh, a guide slide block I slidably mounted in the guide slide groove III, a guide slide groove IV located in the guide slide block I, a slide block III slidably mounted in the guide slide groove IV, a return spring III arranged between the slide block III and the inner wall of the guide slide block I and having elastic strength smaller than that of the return spring I, a cavity eighth located on the front side of the cavity seventh, and a guide slide block III slidably mounted in the cavity eighth, The fixed rod II is fixedly connected with the ejector block II in the guide sliding block III in a sliding mode, the reset spring IV is arranged between the fixed rod II and the inner wall of the guide sliding block III, the ejector block II is arranged in the cavity eight in a sliding mode, the reset spring V is arranged between the ejector block II and the inner wall of the elevator, the rotating shaft six in the cavity eight is rotatably arranged, and the sector gear is fixedly arranged on the rotating shaft six and meshed with the ejector block II.

The invention has the beneficial effects that: the gravity sensing plate senses the weight of the storage barrel positioned on the upper side of the gravity sensing plate so as to control the motor II to start, the quantitative transportation purpose is realized, meanwhile, the storage barrel storing materials is driven by the pushing device to move downwards and push backwards, the material transportation purpose is realized, the pushing block III is driven by the pushing block I to push the gear sleeve to slide up and down through the pushing block I to slide up and down, the meshing and the separation of gears are realized, the pushing device can reset after the transportation is finished, the transportation process is repeated, and the unloading efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of an automatic discharging bucket elevator of the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" in FIG. 2;

fig. 4 is an enlarged structural view of "C" in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 4, the bucket elevator with automatic discharging according to the embodiment of the present invention includes an elevator 11, a feeding frame 12 is fixedly disposed on the left side of the elevator 11, a feeding cavity 13 with an upward opening is disposed in the feeding frame 12, a first transporting cavity 14 is disposed on the lower side of the feeding cavity 13, the elevator 11 includes a first rotating shaft 19 rotatably mounted in the first transporting cavity 14 and a first roller 17 fixedly mounted on the first rotating shaft 19, a first guide chute 36 is disposed on the lower side of the first transporting cavity 14, a first magnetic sliding block 21 is slidably mounted in the first guide chute 36, a first cavity 20 is disposed on the lower side of the first guide chute 36, a storage bucket 22 capable of storing materials is disposed in the first cavity 20, a storage cavity 23 is disposed in the storage bucket 22, an input cavity 39 with an upward opening is disposed on the front side of the first cavity 20 and capable of feeding the storage bucket 22 into the elevator body, the front side of the input cavity 39 is provided with a pushing device 901 capable of feeding the storage barrel 22 into the first cavity 20, the pushing device 901 comprises a first pushing block 40 which is slidably mounted in the input cavity 39 and a first fixing rod 41 which is fixedly arranged on the front side of the first pushing block 40, the lower side of the first cavity 20 is provided with a second transportation cavity 28, the second transportation cavity 28 is slidably mounted with a gravity sensing plate 35 capable of sensing the weight of the upper side, the right side of the second transportation cavity 28 is provided with a second guiding chute 29, the second guiding chute 29 is slidably mounted with a rack 24 which is fixedly connected with the right side of the gravity sensing plate 35, the lower side of the second transportation cavity 28 is provided with a second cavity 31, the lower side of the second cavity 31 is provided with a third cavity 32, the rear side of the second transportation cavity 28 is provided with an output cavity 48 with a backward opening, and the third cavity 32 is internally provided with a transportation device 902 capable of conveying the storage barrel 22 storing materials with specified weight into, the transportation device 902 comprises a first threaded rod 33 which is rotatably arranged in the cavity III 32, a second sliding block 30 which is in threaded connection with the upper side of the first threaded rod 33 and is fixedly connected with the gravity sensing plate 35, a second rotating shaft 63 which is rotatably arranged in the cavity III 32, a gear sleeve 55 which is in key connection with the second rotating shaft 63, a second bevel gear 57 which is fixedly arranged on the gear sleeve 55 and is meshed with the first bevel gear 34, a third bevel gear 54 which is fixedly arranged on the gear sleeve 55, a third rotating shaft 53 which is rotatably arranged in the cavity III 32, a fourth bevel gear 56 which is fixedly arranged on the third rotating shaft 53, a second threaded rod 49 which is rotatably arranged in the cavity III 32, a second roller 50 which is fixedly arranged on the second threaded rod 49, a third roller 52 which is fixedly arranged on the third rotating shaft 53, and a first conveyor belt 51 which is rotatably arranged between the second roller 50 and the third roller 52, And the second push block 84 is in threaded connection with the second threaded rod 49 and is slidably arranged in the third cavity 32, and can be used for transporting the storage barrel 22 storing materials with the specified weight to the right.

In addition, in an embodiment, the upside the 19 rear sides of axis of rotation are located power connection has a motor 18 in the lifting machine 11, both sides about the axis of rotation 19 rotates and installs in conveyer belt two 16, evenly distributed's setting on conveyer belt two 16 can draw and get and transport the transport case 15 of a 14 bottom materials in transportation chamber, if will transport the material of a 14 bottom in chamber upwards transportation, then a starter motor 18 drives a 19 rotations of axis of rotation of upside to drive a 17 rotations of gyro wheel of upside, drive conveyer belt two 16 through belt drive and rotate, thereby make transport case 15 draw the material of getting a 14 bottom in transportation chamber and upwards slide, realize the purpose of material transport.

In addition, in one embodiment, an electromagnet 38 is fixedly arranged on the rear side of the first sliding guide groove 36, an expansion link 37 is arranged between the electromagnet 38 and the first sliding block 21, the first sliding block 21 is electrically connected with the gravity sensing plate 35, and if a material is to be fed into the material storage cavity 23, the electromagnet 38 is energized to generate magnetic force to attract the first sliding block 21 to slide backwards, so that the material transported in the first transport cavity 14 falls into the material storage cavity 23, and the purpose of discharging is achieved.

In addition, in one embodiment, the second pushing block 84 includes a cavity four 47 located in the first fixing rod 41, a swing rod shaft one 42 rotatably installed in the cavity four 47, a swing rod 44 fixedly installed on the swing rod shaft one 42, a swing rod shaft two 46 hinged to the swing rod 44, a cavity five 43 located in front of the input cavity 39, a rotating shaft four 61 rotatably installed in the cavity five 43, a rotating disk 45 fixedly installed on the rotating shaft four 61, a bevel gear five 60 fixedly installed on the rotating shaft four 61, a rotating shaft five 26 rotatably installed in the cavity five 43, a bevel gear six 62 fixedly installed on the rotating shaft five 26 and engaged with the bevel gear five 60, a cavity six 25 located on the right side of the cavity one 20, a gear 27 fixedly installed on the rotating shaft five 26 and engaged with the rack 24, the rotating shaft five 26 is rotatably installed in the cavity six 25, the second rocker shaft 46 is fixedly connected with the rotating disk 45.

In addition, in one embodiment, the transportation device 902 includes a cavity seven 69 located at the lower side of the gravity sensing plate 35, a second guide slider 73 slidably mounted in the cavity seven 69, a first top block 74 slidably mounted in the second guide slider 73, a first return spring 68 disposed between the first top block 74 and the inner wall of the second guide slider 73, a second return spring 70 disposed between the second guide slider 73 and the inner wall of the elevator 11, a third push block 71 fixedly connected to the rear side of the first top block 74, a third guide chute 64 located at the lower side of the cavity seven 69, a first guide slider 85 slidably mounted in the third guide chute 64, a fourth guide chute 65 located in the first guide slider 85, a third slide block 66 slidably mounted in the fourth guide chute 65, and a third return spring 67 disposed between the third slide block 66 and the inner wall of the first guide slider 85 and having a strength smaller than that of the first return spring 68, The lifting device comprises a cavity eight 81 positioned at the front side of the cavity seven 69, a guide slide block three 76 slidably mounted in the cavity eight 81, a fixed rod two 75 slidably mounted in the guide slide block three 76 and fixedly connected with a top block one 74, a return spring four 77 arranged between the fixed rod two 75 and the inner wall of the guide slide block three 76, a top block two 83 slidably mounted in the cavity eight 81, a return spring five 82 arranged between the top block two 83 and the inner wall of the lifter 11, a rotating shaft six 79 rotatably mounted in the cavity eight 81, and a sector gear 80 fixedly mounted on the rotating shaft six 79 and meshed with the top block two 83.

In an initial state, the first sliding block 21 is located at the extreme front end of the first guide sliding groove 36, the rack 24 is located at the extreme upper side of the second guide sliding groove 29, the telescopic rod 37 is in a normal telescopic state, the second fixing rod 75 is far away from the sector gear 80, the second ejector block 83 is meshed with the sector gear 80, the fourth return spring 77 is in a normal compression state, the second return spring 70 is in a normal compression state, the first return spring 68 is in a normal compression state, the first guide sliding block 85 is located at the extreme upper side of the third guide sliding groove 64, the third return spring 67 is in a normal compression state, the third bevel gear 54 is far away from the fourth bevel gear 56, the second bevel gear 57 is meshed with the first bevel gear 34, and the second.

When materials need to be transported and unloaded, the electromagnet 38 is electrified to generate magnetic force to attract the first sliding block 21 to slide backwards, then the materials in the first transporting cavity 14 fall into the material storage cavity 23, the weight of the material storage barrel 22 filled with the materials is sensed through the gravity sensing plate 35, when a specified standard is reached, the second rotating shaft 63 is driven to rotate through the second starting motor 58, the toothed sleeve 55 is driven to rotate, the second bevel gear 57 is driven to rotate, the first threaded rod 33 is driven to rotate through meshing transmission between the second bevel gear 57 and the first bevel gear 34, the second sliding block 30 is driven to slide downwards to the tail end of the lower side of the second cavity 31 through the threaded transmission, the first jacking block 74 is pressed downwards, the third pushing block 71 is driven to slide downwards, the first guiding block 85 is pushed to slide downwards, meanwhile, the second fixing rod 75 slides downwards to be meshed with the sector gear 80, and the gravity sensing plate 35 slides to the lower part of the second cavity 31 through the third return spring 67 with smaller elastic strength than the first return When the gravity sensing plate is at the tail end, the return spring III 67 rebounds to drive the sliding block III 66 to slide downwards, and then the gear sleeve 55 is driven to move downwards, so that the bevel gear II 57 is far away from the bevel gear I34, the bevel gear III 54 is meshed with the bevel gear IV 56, the rotating shaft III 53 is driven to rotate through meshing transmission among the gears, so that the roller III 52 is driven to rotate, the threaded rod II 49 is driven to rotate through belt transmission, the pushing block II 84 is driven to slide backwards through thread transmission, so that the feeding output cavity 48 on the gravity sensing plate 35 is pushed, and meanwhile, the pushing block II 83 is driven to slide upwards to extend into the cavity III 32 through the elastic force compressed by the return spring V82; after the storage barrel 22 is fed into the output cavity 48, the second motor 58 rotates reversely to drive the second pushing block 84 to slide forward until the second pushing block 83 abuts against the second pushing block 84, the second pushing block 84 pushes forward, thereby the second top block 83 slides downwards to drive the sector gear 80 to rotate, the second fixed rod 75 is driven to slide forwards through the meshing transmission between the sector gear 80 and the second fixed rod 75, thereby driving the second guide slide block 73 to slide rightwards and away from the gravity sensing plate 35, driving the first top block 74 to slide upwards through the elastic force compressed by the first return spring 68, thereby driving the third push block 71 to slide upwards and further driving the gear sleeve 55 to slide upwards, so that the third bevel gear 54 is far away from the fourth bevel gear 56, the second bevel gear 57 is meshed with the first bevel gear 34, the first threaded rod 33 is driven to rotate through meshing transmission among the gears, the second sliding block 30 is driven to slide upwards through the threaded transmission, and the second sliding block 73 is driven to slide rightwards through the elastic force compressed by the second return spring 70; meanwhile, the gravity sensing plate 35 drives the rack 24 to slide upwards, the gear 27 is driven to rotate through meshing between the gear 27 and the rack 24, so that the rotating shaft five 26 is driven to rotate, the rotating shaft four 61 is driven to rotate through meshing between the bevel gear six 62 and the bevel gear five 60, so that the rotating disc 45 is driven to rotate, the swing rod 44 is driven to swing backwards through hinged fit, so that the first push block 40 is pushed to slide backwards, and then the storage barrel 22 fed from the input cavity 39 is pushed to slide backwards.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides an automatic bucket elevator of unloading, includes the lifting machine, its characterized in that: the left side of the elevator is fixedly provided with a feeding frame, a feeding cavity with an upward opening is arranged in the feeding frame, a first transportation cavity is arranged on the lower side of the feeding cavity, the elevator comprises a first rotation shaft and a first guide chute which are arranged in the first transportation cavity in a vertically symmetrical mode, a first roller is fixedly arranged on the first rotation shaft, the first roller is rotatably arranged in the first transportation cavity, a first guide chute is arranged on the lower side of the first transportation cavity, a first magnetic sliding block is arranged in the first guide chute in a sliding mode, a first cavity is arranged on the lower side of the first guide chute, a storage barrel capable of storing materials is arranged in the first cavity, a storage cavity is arranged in the storage barrel, an input cavity with an upward opening and capable of feeding the storage barrel into the elevator body is arranged on the front side of the first cavity, a pushing device capable of feeding the storage barrel into the first cavity is arranged on the front side of the, Set firmly in the dead lever one of ejector pad front side, a cavity downside is equipped with transportation chamber two, slidable mounting has the gravity induction board that can respond to the side weight in the transportation chamber two, two right sides in transportation chamber are equipped with lead spout two, lead spout two slidable mounting have with gravity induction board right side fixed connection's rack, two downside in transportation chamber are equipped with cavity two, two downside in cavity are equipped with cavity three, two rear sides in transportation chamber are equipped with the output chamber that the opening is backward, be equipped with in the cavity three and store the material that appointed weight the storage vat sends into the conveyer in the output chamber, conveyer is including rotating to install threaded rod one in cavity three, with threaded rod one upside threaded connection and with gravity induction board fixed connection's sliding block two, rotate and install axis of rotation two in the cavity three, The storage barrel comprises a gear sleeve connected with the rotating shaft in a key-on mode, a bevel gear II fixedly installed on the gear sleeve and meshed with the bevel gear I, a bevel gear III fixedly installed on the gear sleeve, a rotating shaft III rotatably installed in the cavity III, a bevel gear IV fixedly installed on the rotating shaft III, a threaded rod II rotatably installed in the cavity III, a roller II fixedly installed on the threaded rod II, a roller III fixedly installed on the rotating shaft III, a conveyor belt I rotatably installed between the roller II and the roller III, and a pushing block II which is in threaded connection with the threaded rod II and slidably installed in the cavity III and can transport the storage barrel storing materials with specified weight to the right.

2. The bucket elevator of claim 1, wherein the bucket elevator is characterized in that: the upside a axis of rotation rear side is located power connection has motor one in the lifting machine, both sides about axis of rotation one rotates and installs in conveyer belt two, evenly distributed's setting firmly on the conveyer belt two can draw and get and transport the transport case of a transportation chamber bottom material.

3. The bucket elevator of claim 1, wherein the bucket elevator is characterized in that: the rear side of the first guide sliding groove is fixedly provided with an electromagnet, a telescopic rod is arranged between the electromagnet and the first sliding block, and the first sliding block is electrically connected with the gravity sensing plate.

4. The bucket elevator of claim 1, wherein the bucket elevator is characterized in that: the second pushing block comprises a cavity IV in the first fixing rod, a swing rod shaft I rotatably installed in the cavity IV, a swing rod fixedly installed on the swing rod shaft I, a swing rod shaft II hinged to the swing rod, a cavity V positioned on the front side of the input cavity, a rotating shaft IV rotatably installed in the cavity V, a rotating disc fixedly installed on the rotating shaft IV, a bevel gear V fixedly installed on the rotating shaft IV, a rotating shaft V rotatably installed in the cavity V, a bevel gear VI fixedly installed on the rotating shaft V and meshed with the bevel gear V, a cavity VI positioned on the right side of the cavity I, and a gear fixedly installed on the rotating shaft V and meshed with the rack, wherein the rotating shaft V is rotatably installed in the cavity VI, and the swing rod shaft II is fixedly connected with the rotating disc.

5. The bucket elevator of claim 1, wherein the bucket elevator is characterized in that: the transportation device comprises a cavity seventh positioned at the lower side of the gravity sensing plate, a guide slide block II slidably mounted in the cavity seventh, a top block I slidably mounted in the guide slide block II, a return spring I arranged between the top block I and the inner wall of the guide slide block II, a return spring II arranged between the guide slide block II and the inner wall of the elevator, a push block III fixedly connected with the rear side of the top block I, a guide slide groove III positioned at the lower side of the cavity seventh, a guide slide block I slidably mounted in the guide slide groove III, a guide slide groove IV arranged in the guide slide block I, a slide block III slidably mounted in the guide slide groove IV, a return spring III arranged between the slide block III and the inner wall of the guide slide block I and having elastic strength smaller than that of the return spring I, a cavity eighth positioned at the front side of the cavity seventh, a guide slide block III slidably mounted in the cavity eighth, a guide slide block III, The fixed rod II is fixedly connected with the ejector block II in the guide sliding block III in a sliding mode, the reset spring IV is arranged between the fixed rod II and the inner wall of the guide sliding block III, the ejector block II is arranged in the cavity eight in a sliding mode, the reset spring V is arranged between the ejector block II and the inner wall of the elevator, the rotating shaft six in the cavity eight is rotatably arranged, and the sector gear is fixedly arranged on the rotating shaft six and meshed with the ejector block II.