阅读说明：本技术 一种具有打散功能的环保砖生产用智能供料设备 (Intelligent feeding equipment with scattering function for production of environment-friendly bricks ) 是由 张惠强 于 2021-08-09 设计创作，主要内容包括：本发明公布了一种具有打散功能的环保砖生产用智能供料设备,属于环保砖生产技术领域,它包括堆料平台,堆料平台后侧与仓库侧壁相接,堆料平台上堆积有原料,堆料平台前侧设置有输送带,输送带与堆料平台前侧壁平行设置,堆料平台上设置有多斗挖料装置,多斗挖料装置为倾斜设置且其下端设置有辅助下料机构而上端与仓库顶部的行车上的绞车相连辅助下料机构通过滚轮组件驱动并与所述输送带平行运动；输送带后接上料输送带,上料输送带尾端位于供料筒顶部的进口上方,供料筒的进口下方设置有打散组件,打散组件包括水平对称设置的主动轴和从动轴,主动轴与从动轴上环形阵列设置有第二搅拌件,打散组件下方设置有振动筛,振动筛下方为供料筒的出口。(The invention discloses intelligent feeding equipment with a scattering function for producing environment-friendly bricks, which belongs to the technical field of environment-friendly brick production and comprises a stacking platform, wherein the rear side of the stacking platform is connected with the side wall of a warehouse, raw materials are stacked on the stacking platform, a conveying belt is arranged on the front side of the stacking platform and is arranged in parallel with the front side wall of the stacking platform, a multi-bucket excavating device is arranged on the stacking platform, the multi-bucket excavating device is obliquely arranged, the lower end of the multi-bucket excavating device is provided with an auxiliary blanking mechanism, and the upper end of the multi-bucket excavating device is connected with a winch on a travelling crane at the top of the warehouse and is driven by a roller component and moves in parallel with the conveying belt; connect material loading conveyer belt behind the conveyer belt, material loading conveyer belt tail end is located the import top at feed cylinder top, and the import below of feed cylinder is provided with breaks up the subassembly, breaks up the driving shaft and the driven shaft that the subassembly includes the horizontal symmetry and sets up, and annular array is provided with the second stirring piece on driving shaft and the driven shaft, breaks up the subassembly below and is provided with the shale shaker, and the shale shaker below is the export of feed cylinder.)

1. The intelligent feeding equipment with the scattering function for producing the environment-friendly bricks comprises a stacking platform (3), wherein the rear side of the stacking platform (3) is connected with a warehouse side wall (1), raw materials (2) are stacked on the stacking platform (3), a conveying belt (7) is arranged on the front side of the stacking platform (3), the conveying belt (7) is arranged in parallel with the front side wall of the stacking platform (3), the intelligent feeding equipment is characterized in that a multi-bucket excavating device (4) is arranged on the stacking platform (3), the multi-bucket excavating device (4) is arranged in an inclined mode, an auxiliary blanking mechanism (5) is arranged at the lower end of the multi-bucket excavating device, the upper end of the multi-bucket excavating device is connected with a winch on a travelling crane at the top of the warehouse, a discharge port (21) of the auxiliary blanking mechanism (5) is located above the conveying belt (7), and the auxiliary blanking mechanism (5) is driven by a roller assembly and moves in parallel with the conveying belt (7); connect material loading conveyer belt (30) behind conveyer belt (7), material loading conveyer belt (30) tail end is located import (33) top at feed cylinder (31) top, feed cylinder (31) lower extreme is export (34), and import (33) below of feed cylinder (31) is provided with breaks up the subassembly, break up the subassembly and include driving shaft (37) and driven shaft (38) that the horizontal symmetry set up, annular array is provided with second stirring piece (44) on driving shaft (37), and same annular array is provided with second stirring piece (44) on driven shaft (38), break up the subassembly below and be provided with shale shaker (46), export (34) of feed cylinder (31) are in shale shaker (46) below.

2. The intelligent feeding device with the scattering function for the environment-friendly bricks is characterized in that the multi-bucket digging device (4) comprises a digging machine conveyor belt (13) driven by a driving roller (14) and a driven roller (10), digging buckets (12) are arranged on the digging machine conveyor belt (13) in an array mode, the driven roller (10) is connected with a winch on a travelling crane at the top of a warehouse through a steel cable assembly, the driving roller (14) is driven by a first motor (16), the digging machine conveyor belt (13) is located at one end of the driving roller (14) and located above a feeding hole (15) of an auxiliary blanking mechanism (5) of a box structure, and a discharging hole (21) of the auxiliary blanking mechanism (5) is located above a conveyor belt (7).

3. The intelligent feeding equipment with the scattering function for the production of the environment-friendly bricks is characterized in that an auxiliary blanking mechanism (5) of a box body structure comprises a box body, a feeding hole (15) is formed in the top of the box body, the feeding hole (15) is connected with a first blanking channel (25) in the box body, the first blanking channel (25) is connected with a second blanking channel (26), a scattering mechanism (27) is arranged at the joint of the first blanking channel (25) and the second blanking channel (26), and the second blanking channel (26) is connected with a discharging hole (21); the first motor (16) is arranged on the auxiliary blanking mechanism (5) through a motor bracket; the first blanking channel (25) is obliquely arranged, an acute angle is formed between the first blanking channel (25) and the second blanking channel (26), and the cross sectional area of the first blanking channel (25) is larger than that of the second blanking channel (26); and a discharge valve (20) is arranged at the discharge port (21).

4. The intelligent feeding equipment with the scattering function for the production of the environment-friendly bricks is characterized in that the scattering mechanism (27) comprises a rotary drum, shoveling plates (28) are arranged on the rotary drum in an annular array, and the surfaces of the shoveling plates (28) are of cambered surface structures; the rotary drum is driven by a second motor (17), and the second motor (17) is arranged on the side wall of the auxiliary blanking mechanism (5) through a motor support.

5. The intelligent feeding device with the scattering function for the production of the environment-friendly bricks is characterized in that the roller components of the auxiliary blanking mechanism (5) comprise a driving roller (19) and a driven roller (22), the driving roller (19) and the driven roller (22) are respectively arranged at two sides of the bottom of the auxiliary blanking mechanism (5), the driving roller (19) and the driven roller (22) are limited by a guide rail (6), and the driving roller (19) is driven by a stepping motor in a control chamber (18) at the bottom of the auxiliary blanking mechanism (5); the steel cable assembly comprises a steel cable (8), the upper end of the steel cable (8) is connected with a winch on a travelling crane at the bottom of the warehouse, the lower end of the steel cable (8) is connected onto a rotating shaft (29), two ends of the rotating shaft (29) are connected with bearings of a connecting plate (9), and the connecting plate (9) is connected with bearing seats (11) at two ends of a main shaft of the driven roller (10).

6. The intelligent feeding device with the scattering function for the production of environment-friendly bricks is characterized in that the upper surface of the conveying belt (7) is of an inward concave structure, and two sides of the bottom of the conveying belt (7) are limited and supported by a limiting barrel assembly; spacing section of thick bamboo subassembly includes spacing section of thick bamboo (24), spacing section of thick bamboo (24) are the slope setting, and the main shaft both ends of spacing section of thick bamboo (24) link to each other with mounting bracket (23), mounting bracket (23) include the bottom plate, and the bottom plate both sides are provided with the backup pad, and the backup pad of one side is longer and the backup pad of opposite side is shorter, the main shaft both ends of spacing section of thick bamboo (24) link to each other with the backup pad of mounting bracket (23).

7. The intelligent feeding device with the scattering function for the environment-friendly bricks is characterized in that the feeding cylinder (31) is supported by a support (35), the top of the feeding cylinder (31) is symmetrically provided with first inclined plates (32), an inlet (33) is arranged below the first inclined plates (32) at two sides, and the lower part of the feeding cylinder (31) at two sides of the outlet (34) is provided with second inclined plates (48); shale shaker (46) are the arc structure, and shale shaker (46) both sides are connected with vibrating motor (47), and vibrating motor (47) are installed through the mounting panel on feed cylinder (31) inner wall.

8. The intelligent feeding device for the environmentally-friendly brick production with the scattering function according to claim 1, wherein one end of the driving shaft (37) passes through a sealing bearing on the side wall of the feeding cylinder (31) and is connected with an output shaft of a third motor (40), a driving gear (41) is arranged on the driving shaft (37), the third motor (40) is mounted on the side wall of the feeding cylinder (31) through a motor support, and the other end of the driving shaft (37) passes through a sealing bearing on the other side wall of the feeding cylinder (31) and extends to the outside; two ends of the driven shaft (38) respectively penetrate through sealing bearings on the side wall of the feeding cylinder (31), and a driven gear (42) matched with the driving gear (41) is arranged on the driven shaft (38).

9. The intelligent feeding device with the scattering function for the environmentally-friendly bricks is characterized in that rotating shafts (36) are movably arranged in the driving shaft (37) and the driven shaft (38), first stirring pieces (43) are arranged on the rotating shafts (36) in an annular array, the first stirring pieces (43) are of a plate-shaped structure, the first stirring pieces (43) penetrate through sliding grooves (45) in the side walls of the driving shaft (37) and the driven shaft (38), and the first stirring pieces (43) can be inserted into second stirring pieces (44) for storage.

10. The intelligent feeding device with the scattering function for the production of the environment-friendly bricks is characterized in that the second stirring pieces (44) are two stirring plates with a plate-shaped structure which are symmetrically arranged, a groove is arranged in the middle of the second stirring pieces (44) and is communicated with the chute (45), and the first stirring pieces (43) slide into the groove from the chute (45) and are overlapped with the stirring plates on two sides of the second stirring pieces (44); the top of the rotating shaft (36) is provided with limiting screw holes (39) with different heights, the bottoms of the driving shaft (37) and the driven shaft (38) are also provided with threaded holes corresponding to the limiting screw holes (39), and the rotating shaft (36) is connected with the driving shaft (37) or the driven shaft (38) through the bolt matched limiting screw holes (39) and the threaded holes.

Technical Field

The invention relates to the technical field of production of environment-friendly bricks, in particular to intelligent feeding equipment with a scattering function for production of environment-friendly bricks.

Background

The building bricks play a fundamental and important role in economic development and social construction, and the requirements of old buildings and new buildings on the bricks are only increased but not reduced. With the development of building industry and the progress of the whole society, the living standard of people is continuously improved, more and more people require multifunctional houses with high heat insulation, low density, light weight and the like, and the hollow brick is a product recommended by the national building department firstly because of the advantages of light weight, high strength, good heat insulation, sound insulation and noise reduction performance, less consumption of raw materials, environmental protection, no pollution and the like.

The common environment-friendly hollow brick at present is a novel wall material manufactured by using fly ash, cinder, coal gangue, tailing slag, chemical industry slag or natural sand, tidal marsh mud, industrial waste, garbage incinerator slag and the like (one or more of the above raw materials) as main raw materials, and the environment-friendly hollow brick is a product which accords with the general guideline of developing building materials of protecting farmlands, saving energy, taking local resources according to local conditions in China and also belongs to a building material product which is free from value-added tax. The material has high strength, good durability, standard size, complete appearance, uniform color and luster, has simple and natural appearance, can be used as a dry wall and any external decoration, and is a renewal product which replaces clay bricks and has great development prospect.

During the production of the hollow brick, the accumulated mixed raw materials are continuously dug and transported to a feeding cylinder from a raw material warehouse, and then uniform and stable feeding is carried out. The raw materials in the warehouse are often accumulated like a mountain, the excavator is arranged on an inclined plane on one side for excavating, if the position of the excavator cannot be adjusted, the excavating process is difficult to keep continuous, the discharging is not uniform enough, and the subsequent stable feeding is influenced; and because the raw materials are accumulated in the warehouse, humidification treatment is often needed, and the materials are easy to agglomerate and agglomerate after being dug and enter the material supply cylinder, which affects the continuous and uniform discharge of the materials.

Disclosure of Invention

The invention aims to solve the problems, and provides intelligent feeding equipment with a scattering function for producing environment-friendly bricks, which consists of a multi-bucket excavator and a feeding cylinder, wherein the angle of the excavator can be adjusted in a stepless manner, so that each bucket of the excavator is prevented from being dug in the process of material digging, the feeding cylinder is improved to provide the scattering function, and continuous, uniform and stable feeding is realized.

In order to realize the purpose, the invention adopts the technical scheme that: an intelligent feeding device with a scattering function for producing environment-friendly bricks comprises a stacking platform, wherein the rear side of the stacking platform is connected with the side wall of a warehouse, raw materials are stacked on the stacking platform, a conveying belt is arranged on the front side of the stacking platform, and the conveying belt is arranged in parallel with the front side wall of the stacking platform; connect material loading conveyer belt behind the conveyer belt, material loading conveyer belt tail end is located the import top at feed cylinder top, feed cylinder lower extreme is the export, and the import below of feed cylinder is provided with breaks up the subassembly, break up the subassembly and include driving shaft and the driven shaft that the horizontal symmetry set up, the last annular array of driving shaft is provided with the second stirring piece, and the same annular array is provided with the second stirring piece on the driven shaft, it is provided with the shale shaker to break up the subassembly below, and the shale shaker below is the export of feed cylinder.

Furthermore, the multi-bucket digging device comprises a digging machine conveyor belt driven by a driving roller and a driven roller, digging buckets are arranged on the digging machine conveyor belt in an array mode, the driven roller is connected with a winch on a travelling crane at the top of the warehouse through a steel cable assembly, the driving roller is driven by a first motor, one end of the digging machine conveyor belt is located above a feed inlet of an auxiliary discharging mechanism of the box structure, and a discharge outlet of the auxiliary discharging mechanism is located above the conveyor belt.

Furthermore, the auxiliary blanking mechanism of the box body structure comprises a box body, a feeding hole is formed in the top of the box body, the feeding hole is connected with a first blanking channel inside the box body, the first blanking channel is connected with a second blanking channel, a scattering mechanism is arranged at the joint of the first blanking channel and the second blanking channel, and the second blanking channel is connected with a discharging hole; the first motor is arranged on the auxiliary blanking mechanism through a motor bracket; the first blanking channel is obliquely arranged, an acute angle is formed between the first blanking channel and the second blanking channel, and the cross sectional area of the first blanking channel is larger than that of the second blanking channel; and a discharge valve is arranged at the discharge port.

Furthermore, the scattering mechanism comprises a rotary drum, wherein shoveling plates are arranged on the rotary drum in an annular array mode, and the surfaces of the shoveling plates are of cambered surface structures; the rotary drum is driven by a second motor, and the second motor is arranged on the side wall of the auxiliary blanking mechanism through a motor support.

Furthermore, the roller components of the auxiliary blanking mechanism comprise a driving roller and a driven roller, the driving roller and the driven roller are respectively arranged on two sides of the bottom of the auxiliary blanking mechanism, the driving roller and the driven roller are limited through guide rails, and the driving roller is driven by a stepping motor in a control chamber at the bottom of the auxiliary blanking mechanism; the cable wire assembly comprises a cable wire, the upper end of the cable wire is connected with a winch on a travelling crane at the bottom of the warehouse, the lower end of the cable wire is connected onto the rotating shaft, two ends of the rotating shaft are connected with bearings of the connecting plate, and the connecting plate is connected with bearing seats at two ends of the main shaft of the driven roller.

Furthermore, the upper surface of the conveying belt is of an inward concave structure, and two sides of the bottom of the conveying belt are limited and supported through a limiting cylinder assembly; spacing section of thick bamboo subassembly includes a spacing section of thick bamboo, a spacing section of thick bamboo sets up for the slope, and the main shaft both ends of a spacing section of thick bamboo link to each other with the mounting bracket, the mounting bracket includes the bottom plate, and the bottom plate both sides are provided with the backup pad, and the backup pad of one side is longer and the backup pad of opposite side is shorter, the main shaft both ends of a spacing section of thick bamboo link to each other with the backup pad of mounting bracket.

Furthermore, the feeding cylinder is supported by the support, first inclined plates are symmetrically arranged at the top of the feeding cylinder, an inlet is formed below the first inclined plates on two sides, and second inclined plates are arranged on two sides of the outlet at the lower part of the feeding cylinder; the vibrating screen is of an arc-shaped structure, two sides of the vibrating screen are connected with a vibrating motor, and the vibrating motor is installed through a mounting plate on the inner wall of the feeding cylinder.

Furthermore, one end of the driving shaft penetrates through a sealing bearing on the side wall of the feeding cylinder and is connected with an output shaft of a third motor, a driving gear is arranged on the driving shaft, the third motor is installed on the side wall of the feeding cylinder through a motor support, and the other end of the driving shaft penetrates through the sealing bearing on the other side wall of the feeding cylinder and extends to the outside; two ends of the driven shaft respectively penetrate through the sealing bearings on the side walls of the feeding cylinders, and the driven shaft is provided with a driven gear matched with the driving gear.

Further, equal activity is provided with the pivot in driving shaft and the driven shaft, and annular array is provided with first stirring piece in the pivot, first stirring piece is platelike structure, and first stirring piece passes the spout setting on driving shaft and the driven shaft lateral wall, and first stirring piece can be accomodate in the second stirring piece.

Furthermore, the second stirring piece is two symmetrically arranged stirring plates with plate-shaped structures, a slot is arranged in the middle of the second stirring piece and is communicated with the chute, and the first stirring piece slides into the slot from the chute and is overlapped with the stirring plates on two sides of the second stirring piece; the top of the rotating shaft is provided with limiting screw holes with different heights, the bottoms of the driving shaft and the driven shaft are also provided with threaded holes corresponding to the limiting screw holes, and the rotating shaft is connected with the driving shaft or the driven shaft through the bolt matched limiting screw holes and the threaded holes.

The invention has the beneficial effects that:

when feeding, at first, get the material operation through the multi-bucket excavator device, wherein the winch on the driving at multi-bucket excavator device's one end passes through the cable wire subassembly and links to each other with the warehouse top, drives multi-bucket excavator device one end through receiving and releasing of cable wire and transfers or the lifting to keep with the pile material surface contact who piles up on the platform, and then guarantee that the bucket can dig the material always, realize that accumulational raw materials carry out even feed from the material that digs of surperficial one deck. And the multi-bucket digging device is connected with the auxiliary discharging mechanism, so that the dug materials can be centralized, scattered and discharged at a constant speed into the conveying belt. The auxiliary blanking mechanism is of a box structure, a large first blanking channel is arranged in the box structure and used for receiving raw materials unloaded from the bucket, the first blanking channel is connected with a small second blanking channel, the connecting part is provided with a scattering mechanism for scattering the raw materials, and the blocking of the second blanking channel by the blocking materials is prevented. The second unloading passageway can be full of to the material of breaing up, carries out even ejection of compact entering conveyer belt through the discharge gate afterwards.

The auxiliary blanking mechanism integrally moves through the roller assemblies and the guide rails in a matched mode, and the auxiliary blanking mechanism keeps synchronous movement with a travelling crane at the top of the warehouse, so that the multi-bucket excavating device is translated, the excavating and taking operation can be carried out on raw materials in different areas, the continuous and fine material taking of a large-scale raw material warehouse is realized, and the requirement of uniform material supply of the raw materials is met.

In order to solve the problems that materials are not smoothly and uniformly fed due to the phenomena of caking, agglomeration and the like caused by excessive humidity and the like, the feeding device is provided with the feeding cylinder, the scattering assembly is arranged in the feeding cylinder to fully scatter the materials, and the materials are sieved by the vibrating screen and then discharged from the feeding cylinder. Meanwhile, the production efficiency is considered, and the density of the stirring pieces of the scattering assembly can be adjusted to meet the scattering requirements of different materials, so that fine and efficient operation is realized. Wherein in first stirring piece can be accomodate and the second stirring piece, the density of stirring piece when both overlap obtains adjusting, specifically is through promoting the pivot in driving shaft and the driven shaft, drives epaxial first stirring piece and removes to it is fixed with pivot and driving shaft or driven shaft through the spacing screw of bolt cooperation. When the first stirring piece is stored into the second stirring piece, the coincidence of the third motor can be reduced, the power of the third motor can be reduced, and the energy-saving effect is achieved.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

FIG. 2 is a schematic view of the relative position of the multi-bucket excavator and the stacking platform of the present invention.

FIG. 3 is a schematic view of the position of the multi-bucket excavator and the auxiliary blanking mechanism of the present invention.

Fig. 4 is a schematic view of the internal structure of the auxiliary blanking mechanism of the present invention.

Fig. 5 is a schematic structural diagram of a limiting cylinder assembly of the present invention.

FIG. 6 is a schematic view of the construction of the wire rope assembly of the present invention.

FIG. 7 is a schematic view of the driving and driven shafts of the present invention.

Fig. 8 is a schematic view of the installation of the rotating shaft of the present invention.

Fig. 9 is a schematic view of the mounting of the third motor of the present invention.

Fig. 10 is a schematic view of the internal structure of the supply cylinder of the present invention.

The text labels in the figures are represented as: 1. a warehouse side wall; 2. raw materials; 3. a stockpiling platform; 4. a multi-bucket digging device; 5. an auxiliary blanking mechanism; 6. a guide rail; 7. a conveyor belt; 8. a steel cord; 9. a connecting plate; 10. a driven drum; 11. a bearing seat; 12. excavating a bucket; 13. a shovel conveyor belt; 14. a driving roller; 15. a feed inlet; 16. a first motor; 17. a second motor; 18. a control room; 19. a driving roller; 20. a discharge valve; 21. a discharge port; 22. a driven roller; 23. a mounting frame; 24. a limiting cylinder; 25. a first blanking channel; 26. a second blanking channel; 27. a breaking mechanism; 28. a shoveling plate; 29. a rotating shaft; 30. a feeding conveyer belt; 31. a supply cylinder; 32. a first sloping plate; 33. an inlet; 34. an outlet; 35. a support; 36. a rotating shaft; 37. a drive shaft; 38. a driven shaft; 39. a limiting screw hole; 40. a third motor; 41. a driving gear; 42. a driven gear; 43. a first stirring member; 44. a second stirring member; 45. a chute; 46. vibrating screen; 47. a vibration motor; 48. a second swash plate.

Detailed Description

The invention is further illustrated by the following examples.

An intelligent feeding device with a scattering function for producing environment-friendly bricks comprises a stacking platform 3, wherein the rear side of the stacking platform 3 is connected with a warehouse side wall 1, raw materials 2 are stacked on the stacking platform 3, a conveying belt 7 is arranged on the front side of the stacking platform 3, and the conveying belt 7 is arranged in parallel with the front side wall of the stacking platform 3. the intelligent feeding device is characterized in that a multi-bucket excavating device 4 is arranged on the stacking platform 3, the multi-bucket excavating device 4 is arranged in an inclined manner, an auxiliary blanking mechanism 5 is arranged at the lower end of the multi-bucket excavating device 4, the upper end of the multi-bucket excavating device is connected with a winch on a travelling crane at the top of the warehouse, a discharge port 21 of the auxiliary blanking mechanism 5 is positioned above the conveying belt 7, and the auxiliary blanking mechanism 5 is driven by a roller component and moves in parallel with the conveying belt 7; connect material loading conveyer belt 30 behind conveyer belt 7, material loading conveyer belt 30 tail end is located the import 33 top at a feed section of thick bamboo 31 top, a feed section of thick bamboo 31 lower extreme is export 34, and the import 33 below of a feed section of thick bamboo 31 is provided with breaks up the subassembly, break up the subassembly and include driving shaft 37 and the driven shaft 38 that the horizontal symmetry set up, annular array is provided with second stirring piece 44 on driving shaft 37, and same annular array is provided with second stirring piece 44 on the driven shaft 38, it is provided with shale shaker 46 to break up the subassembly below, and shale shaker 46 below is the export 34 of a feed section of thick bamboo 31.

Preferably, as shown in fig. 3 and 4, the multi-bucket material digging device 4 comprises a digging machine conveyor belt 13 driven by a driving roller 14 and a driven roller 10, wherein digging buckets 12 are arranged on the digging machine conveyor belt 13 in an array, the driven roller 10 is connected with a winch on a travelling crane at the top of the warehouse through a steel cable assembly, the driving roller 14 is driven by a first motor 16, one end of the digging machine conveyor belt 13, which is positioned at the driving roller 14, is positioned above a feeding port 15 of an auxiliary blanking mechanism 5 of a box structure, and a discharging port 21 of the auxiliary blanking mechanism 5 is positioned above a conveyor belt 7.

Preferably, as shown in fig. 2 and 3, the auxiliary blanking mechanism 5 of the box structure includes a box body, a feeding hole 15 is formed at the top of the box body, the feeding hole 15 is connected with a first blanking channel 25 inside the box body, the first blanking channel 25 is connected with a second blanking channel 26, a scattering mechanism 27 is arranged at the connection position of the first blanking channel 25 and the second blanking channel 26, and the second blanking channel 26 is connected with a discharging hole 21; the first motor 16 is arranged on the auxiliary blanking mechanism 5 through a motor bracket; the first blanking channel 25 is obliquely arranged, an acute angle is formed between the first blanking channel 25 and the second blanking channel 26, and the cross-sectional area of the first blanking channel 25 is larger than that of the second blanking channel 26; and a discharge valve 20 is arranged at the discharge port 21.

Raw materials 2 get into the box through feed inlet 15 after at first carry out the unloading through the first unloading passageway 25 of broad, the raw materials 2 accessible of caking is broken up mechanism 27 and is broken up, and raw materials 2 gets into second unloading passageway 26 afterwards, because so raw materials 2 can comparatively enrich second unloading passageway 26 of the narrower second unloading passageway 26 width, reduce inside space, are favorable to the unloading even.

Preferably, as shown in fig. 4, the scattering mechanism 27 includes a rotating cylinder, a shoveling plate 28 is arranged on the rotating cylinder in an annular array, and the surface of the shoveling plate 28 is of an arc-shaped structure; the rotating drum is driven by a second motor 17, and the second motor 17 is arranged on the side wall of the auxiliary blanking mechanism 5 through a motor support. The scattering mechanism 27 not only can scatter the agglomerated raw material 2, but also can accelerate the raw material 2 to enter the second feeding channel 26, so that the second feeding channel 26 is filled more fully.

Preferably, as shown in fig. 3 and 4, the roller assembly of the auxiliary blanking mechanism 5 includes a driving roller 19 and a driven roller 22, the driving roller 19 and the driven roller 22 are respectively disposed at two sides of the bottom of the auxiliary blanking mechanism 5, the driving roller 19 and the driven roller 22 are both limited by the guide rail 6, and the driving roller 19 is driven by a stepping motor in the control chamber 18 at the bottom of the auxiliary blanking mechanism 5; the steel cable assembly comprises a steel cable 8, the upper end of the steel cable 8 is connected with a winch on a travelling crane at the bottom of the warehouse, the lower end of the steel cable 8 is connected to a rotating shaft 29, two ends of the rotating shaft 29 are connected with bearings of a connecting plate 9, and the connecting plate 9 is connected with bearing seats 11 at two ends of a main shaft of the driven roller 10.

Preferably, as shown in fig. 1, 2, 5 and 6, the upper surface of the conveyor belt 7 is an inward concave structure, and both sides of the bottom of the conveyor belt 7 are limited and supported by a limiting cylinder assembly; spacing section of thick bamboo subassembly includes spacing section of thick bamboo 24, spacing section of thick bamboo 24 sets up for the slope, and the main shaft both ends of spacing section of thick bamboo 24 link to each other with mounting bracket 23, mounting bracket 23 includes the bottom plate, and the bottom plate both sides are provided with the backup pad, and the backup pad of one side is longer and the backup pad of opposite side is shorter, the main shaft both ends of spacing section of thick bamboo 24 link to each other with the backup pad of mounting bracket 23.

Because conveyer belt 7 is longer, 7 both ends of conveyer belt pass through the rotary drum and drive when carrying out reciprocating motion, for preventing 7 middle parts of conveyer belt from collapsing, set up spacing section of thick bamboo subassembly and carry out spacingly to conveyer belt 7, spacing section of thick bamboo subassembly's mounting bracket 23 can be supported by the support column.

Preferably, as shown in fig. 1, 9 and 10, the feeding cylinder 31 is supported by a support 35, the top of the feeding cylinder 31 is symmetrically provided with first inclined plates 32, the inlet 33 is arranged below the first inclined plates 32 on both sides, and the lower part of the feeding cylinder 31 is provided with second inclined plates 48 on both sides of the outlet 34; the shale shaker 46 is the arc structure, and the shale shaker 46 both sides are connected with vibrating motor 47, and vibrating motor 47 installs through the mounting panel on the feed cylinder 31 inner wall.

Preferably, as shown in fig. 1, one end of the driving shaft 37 passes through a sealing bearing on a side wall of the supply cylinder 31 and is connected to an output shaft of a third motor 40, a driving gear 41 is disposed on the driving shaft 37, the third motor 40 is mounted on the side wall of the supply cylinder 31 through a motor bracket, and the other end of the driving shaft 37 passes through the sealing bearing on the other side wall of the supply cylinder 31 and extends to the outside; two ends of the driven shaft 38 are respectively arranged through a sealing bearing on the side wall of the feeding cylinder 31, and a driven gear 42 matched with the driving gear 41 is arranged on the driven shaft 38.

Preferably, as shown in fig. 7, 8 and 9, the driving shaft 37 and the driven shaft 38 are both movably provided with a rotating shaft 36, the rotating shaft 36 is provided with a first stirring member 43 in an annular array, the first stirring member 43 is a plate-shaped structure, the first stirring member 43 is disposed through a sliding groove 45 on the side wall of the driving shaft 37 and the driven shaft 38, and the first stirring member 43 can be inserted into and stored in a second stirring member 44. The second stirring piece 44 is two symmetrically arranged stirring plates with plate-shaped structures, a slot is arranged in the middle of the second stirring piece 44 and is communicated with the chute 45, and the first stirring piece 43 slides into the slot from the chute 45 and is overlapped with the stirring plates on two sides of the second stirring piece 44; the top of the rotating shaft 36 is provided with limiting screw holes 39 with different heights, the bottoms of the driving shaft 37 and the driven shaft 38 are also provided with threaded holes corresponding to the limiting screw holes 39, and the rotating shaft 36 is connected with the driving shaft 37 or the driven shaft 38 through the bolt matched limiting screw holes 39 and the threaded holes.

Through the pivot 36 in promoting driving shaft 37 and the driven shaft 38, drive the epaxial 43 pieces of first stirring of pivot 36 and remove to it is fixed with driving shaft 37 or driven shaft 38 with pivot 36 through the spacing screw hole of bolt cooperation 39, realize the regulation of density of stirring, thereby the demand of breaing up under the adaptation different material operating modes, can also make motor power obtain reducing, optimizes energy-conserving effect.

It should be noted that, in this document, 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.

The principles and embodiments of the present invention are explained herein, and the above description of the embodiments is only used to help understand the method and its core idea of the present invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.