CN210884359U - Quantitative feeding device with adjustable even cloth of auger and volume - Google Patents

Abstract

The utility model provides a quantitative feeding device with auger uniform material distribution and adjustable volume, which comprises a hopper; a first flashboard and a second flashboard are arranged in the hopper; the first gate plate and the second gate plate divide the interior of the hopper into a first bin, a second bin and a third bin from top to bottom in sequence; the first gate plate can horizontally move into and out of the hopper so as to realize communication or separation between the first bin and the second bin; the second gate plate can also horizontally move the feeding hopper and the discharging hopper so as to realize the communication or the separation between the second bin and the third bin; a feed inlet is formed in the top of the first storage bin, and a packing auger is arranged below the feed inlet; the volume of the second storage bin is adjustable and not larger than that of the first storage bin; a plurality of material distributing grooves which are mutually independent and are arranged at intervals are formed in the third storage bin, and a discharge hole is formed in the bottom of each material distributing groove. The utility model has the advantages of automatic control feeding, constant volume material volume, multiple spot quantitative unloading at the uniform velocity, simple structure, low in manufacturing cost moreover.

Description

Quantitative feeding device with adjustable even cloth of auger and volume

Technical Field

The utility model belongs to the field of machinery, a feeder is related to, especially relate to a quantitative feeder with adjustable even cloth of auger and volume.

Background

The granular materials are usually required to be distributed or fed according to the specification of the charging barrel in the production or subpackage process, and the traditional manual quantitative feeding/subpackage mode is low in efficiency, long in consumed time and not beneficial to industrial production. To the condition that needs multiple spot ration cloth, if a plurality of hoppers that connect or the condition that single longer hopper has a plurality of cloth mouths side by side, need to carry out simple evenly distributed to the material, the purpose makes the efficiency of multiple spot cloth keep unanimous, and the control of being convenient for prevents that the material from piling up or overflowing the storage bucket in one side.

The intelligent feeding device can realize multi-point quantitative feeding, but the intelligent device has high technical requirements and very high manufacturing cost and use cost. For the conditions of low material distribution accuracy requirement and high cost control requirement, equipment with low cost and high cost performance is required.

Therefore, a feeding device capable of realizing multipoint simultaneous quantitative distribution needs to be designed, and the feeding device is simple in structure and low in production cost.

Disclosure of Invention

The utility model discloses study to above-mentioned problem, provide a dosing device with adjustable even cloth of auger and volume to the homogeneity and the dosing problem of unloading simultaneously of granular material single-point material loading, multiple spot in solving industrial production.

In order to achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides a quantitative feeding device with adjustable even cloth of auger and volume which characterized in that: comprises a hopper; a first flashboard and a second flashboard which are both horizontally arranged are arranged in the hopper, and the second flashboard is positioned below the first flashboard; the first gate plate and the second gate plate divide the interior of the hopper into a first bin, a second bin and a third bin from top to bottom in sequence; the first gate plate can horizontally move into and out of the hopper so as to realize communication or separation between the first bin and the second bin; the second gate plate can also horizontally move the charging and discharging hopper so as to realize the communication or separation between the second bin and the third bin; a feed inlet is formed in the top of the first storage bin, and a horizontally arranged auger is arranged below the feed inlet; the volume of the second storage bin is adjustable and is not larger than that of the first storage bin; a plurality of material distributing grooves which are mutually independent and are arranged at intervals are formed in the third storage bin, and a discharge hole is formed in the bottom of each material distributing groove.

The utility model discloses a theory of operation is: the first bin is used for feeding and uniformly distributing materials; the second storage bin is used for fixing the volume of the materials; the third feed bin is used for distributing the materials to the distributing troughs. When in use: 1) feeding: closing the first flashboard, enabling the granular materials to enter a first storage bin from the feeding hole, and uniformly distributing the materials through forward and reverse rotation of a packing auger with spiral blades; 2) metering: when enough materials are distributed in the first storage bin, closing the second gate plate, opening the first gate plate, and enabling the materials to enter the second storage bin from the first storage bin; the volume of the first bin is far larger than that of the second bin, so that the second bin is filled with materials; the volume of the second storage bin is adjustable, and the capacity of the second storage bin can be adjusted according to requirements; 3) blanking: and closing the first flashboard, opening the second flashboard, dropping the material from the second storage bin, shunting the material to each distributing groove, and discharging through a discharging port to realize multipoint quantitative distribution.

Preferably, in order to control the automatic feeding and the feeding amount in the first bin, a first sensor and a second sensor are further arranged in the first bin. The first sensor and the second sensor may be infrared detection sensors or the like. The first sensor is used for detecting materials and giving a feeding stopping signal, and the second sensor is used for detecting materials and giving a feeding starting signal. The first sensor is close to the below setting of auger, and the second sensor is close to the top setting of first flashboard, and the level of second sensor is less than the level of first sensor. During feeding, when the material height reaches the level of the first sensor, the first sensor sends a signal for stopping feeding, the feeding is blocked, and meanwhile, the auger also stops rotating. During blanking, when the material height is lower than the horizontal height of the second sensor, the second sensor sends a signal for starting feeding, and a new round of feeding is started.

Further, the horizontal height of the first sensor and the second sensor can be adjusted according to the total amount of each blanking. And in order to ensure that the second storage bin is filled with the materials in the first storage bin when the materials enter the second storage bin, the volume between the horizontal plane of the second sensor and the first gate plate in the first storage bin is preferably not less than the volume of the second storage bin, and is preferably 1-2 times of the volume of the second storage bin.

In order to meet different requirements of the blanking amount, the volume of the second storage bin is adjustable, and the hopper is preferably formed by sleeving an upper hopper and a lower hopper. Wherein, first flashboard setting is in the well lower part of last hopper, and the second flashboard setting is in the well upper portion of hopper down, and the distance of cup jointing between the hopper and the lower hopper is adjustable at certain extent to make the interval of first flashboard and second flashboard adjustable, the volume of second feed bin is adjustable promptly. The realization goes up the hopper and down the adjustable structural style of cup joint distance between the hopper can adopt prior art's multiple implementation, the utility model discloses the structure of preferred adoption is: be equipped with first connecting block in the outside of going up the hopper, be equipped with the second connecting block in the outside of hopper down, connect through bolt and nut between first connecting block and the second connecting block, thereby realize going up the hopper and the distance of cup jointing between the hopper down adjustable through the connection distance between adjusting bolt and the nut.

Furthermore, in order to enable the materials to be smoothly separated from the second bin into the plurality of material separating grooves without accumulation, a plurality of first flow dividing blocks in a similar triangular shape are further arranged in the second bin, and the plurality of first flow dividing blocks are all positioned above the second flashboard. Each first shunting block is arranged above the space between two adjacent distributing grooves; every first reposition of redundant personnel piece be its apex angle up, two adjacent inclined planes incline respectively towards its both sides below the branch silo and set up, when opening the unloading of second flashboard, the material can follow two inclined planes landing of first reposition of redundant personnel piece in each branch silo for the material is shunted at the uniform velocity, and can avoid the material to form between adjacent branch silo top and pile up.

Furthermore, a plurality of second flow distribution blocks similar to triangular bodies are arranged in the first storage bin, and the second flow distribution blocks are all positioned above the first flashboard and are arranged at intervals; each second shunting block is arranged with an upward vertex angle; and the plurality of second shunting blocks are arranged above the plurality of first shunting blocks in a one-to-one correspondence manner. The second shunting block has the functions of: firstly, the material is divided, so that the material cannot be accumulated at a certain position in the first storage bin in the intermittent feeding process, the material entering the first storage bin is ensured to be discharged first, and the freshness of the material is ensured to be consistent; and secondly, the upper end of a first diversion block for preventing the particle materials from falling into a second storage bin is prevented, so that the first flashboard is blocked by the materials in the opening and closing process and cannot be completely closed.

In order to better realize the opening and closing action of the first gate plate, preferably, each second flow dividing block is provided with an inward concave guide groove on the bottom surface facing the first gate plate; the first flashboard is also provided with a plurality of guide rails which are embedded into the guide grooves in a matching manner and slide; the guide groove and the guide rail are mutually matched and installed.

Preferably, the first shutter and the second shutter are pushed by air cylinders, and a first air cylinder for pushing the first shutter to move and a second air cylinder for pushing the second shutter to move are arranged on the outer side of the hopper. The side wall of the hopper is respectively provided with a first through hole and a second through hole; one end of the first flashboard penetrates through the first through hole to extend into the hopper, and the other end of the first flashboard is positioned outside the first through hole and connected with the output end of the first air cylinder; one end of the second flashboard penetrates through the second through hole and extends into the hopper, and the other end of the second flashboard is located on the outer side of the second through hole and connected with the output end of the second air cylinder.

Furthermore, in order to keep the stability of the first gate plate and the second gate plate in the horizontal moving process and prevent the first gate plate and the second gate plate from discharging materials in the hopper in the moving process, a first pressing plate mechanism and a second pressing plate mechanism are arranged outside the hopper. The first pressing plate mechanism comprises a first guide block, a first pressing block and a first spring; the first guide block is fixed on the outer side of the hopper and is provided with a first guide hole which is communicated up and down; the first pressing block is inserted in the first guide hole and can move up and down along the first guide hole; one end of the first spring is fixedly connected to the hopper, the other end of the first spring is connected with one end of the first pressing block, and the other end of the first pressing block is tightly pressed on the surface of the first flashboard; the first spring maintains an elastically deformed state. The second pressing plate mechanism comprises a second guide block, a second pressing block and a second spring; the second guide block is fixed on the outer side of the hopper and is provided with a second guide hole which is communicated up and down; the second pressing block is inserted in the second guide hole and can move up and down along the second guide hole; one end of the second spring is fixedly connected to the hopper, the other end of the second spring is connected with one end of the second pressing block, and the other end of the second pressing block is tightly pressed on the surface of the second flashboard; the second spring maintains an elastically deformed state.

The utility model has the advantages of automatic control feeding and unloading process, multipoint constant speed quantitative unloading, simple structure and low manufacturing cost.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

FIG. 2 is a side structural perspective view of the embodiment;

FIG. 3 is a schematic top view of the embodiment;

FIG. 4 is an enlarged view of a portion A of FIG. 1;

FIG. 5 is a partial enlarged view of portion B of FIG. 1;

FIG. 6 is an enlarged view of a portion C of FIG. 2;

reference numerals: 1-a hopper; 11-a feeding hopper; 111-a first via; 112-a first connection block; 12-a discharge hopper; 121-a second via; 122-a second connection block; 13-a first silo; 14-a second silo; 15-a third silo; 151-distributing groove; 16-a feed inlet; 17-a discharge hole; 18-a first inductor; 19-a second inductor; 2-a packing auger; 3-a first shutter; 31-a guide rail; 4-a second gate; 30-a first cylinder; 40-a second cylinder; 5-a first shunting block; 6-a second shunting block; 61-a guide groove; 7-a first platen mechanism; 71-a first guide block; 711-a first via; 72-a first briquette; 73-a first spring; 8-a second platen mechanism; 81-a second guide block; 811-a second via; 82-second briquetting; 83-a second spring; 91-bolt; 92-nut.

Detailed Description

The present invention is described in detail below with reference to the following embodiments and accompanying drawings, but the scope of the present invention is not limited to the description of the embodiments, and other equivalent technical means or equivalent technical features have the same or similar functions or structures, and shall also fall within the scope of the present invention.

As shown in figure 1, the quantitative feeding device with the auger uniform distribution and the adjustable volume comprises a hopper 1. The hopper 1 is formed by sleeving an upper hopper 11 and a lower hopper 12. A first shutter plate 3 is horizontally arranged in the upper hopper 11, and a second shutter plate 4 is horizontally arranged in the lower hopper 12. The first shutter 3 and the second shutter 4 divide the interior of the hopper 1 into a first bin 13, a second bin 14 and a third bin 15 in sequence from top to bottom. The first shutter 3 is horizontally movable into and out of the hopper 1 to achieve communication or separation between the first silo 13 and the second silo 14. The second shutter 4 is also horizontally movable into and out of the hopper 1, thereby achieving communication or separation between the second bin 14 and the third bin 15.

As shown in fig. 1 to 3, a feed inlet 16 is arranged at the top of the first bin 13; an auger 2 is arranged below the feeding port 16, the auger 2 is horizontally arranged along the length direction of the first storage bin 13, spiral blades for uniformly stirring materials are formed on the surface of the auger 2, and the auger 2 can rotate in a positive pulse mode and a reverse pulse mode.

A first sensor 18 and a second sensor 19 are also provided in the first magazine 13. The first sensor 18 and the second sensor 19 are both infrared detection sensors. The first sensor 18 is arranged below the packing auger 2, the second sensor 19 is arranged above the first shutter 3, and the level of the second sensor 19 is lower than the level of the first sensor 18. The first sensor 18 is used for detecting whether the materials are accumulated to the level height or above in the feeding process, and if so, signals for stopping feeding and stopping the rotation of the packing auger are given. The second sensor 19 is used for detecting whether the material falls below the expiration level, and if so, signals for starting feeding and starting the rotation of the packing auger are given. The volume between the level of the second sensor 19 and the first shutter 3 is not less than the volume of the second silo 14.

As shown in fig. 1 and 6, the volume of the second silo 14 is adjustable according to the adjustment of the coupling distance between the upper hopper 11 and the lower hopper 12. Wherein, the first gate plate 3 is arranged at the middle lower part of the upper hopper 11, and the second gate plate 4 is arranged at the middle upper part of the lower hopper 12; the first connecting block 112 is arranged on the outer side of the upper hopper 11, the second connecting block 122 is arranged on the outer side of the lower hopper 12, and the first connecting block 112 and the second connecting block 122 are connected through the bolt 91 and the nut 92. The coupling distance between the upper hopper 11 and the lower hopper 12 can be adjusted by adjusting the coupling distance between the bolt 91 and the nut 92, that is, the distance between the first gate plate 3 and the second gate plate 4 can be adjusted, that is, the volume of the second storage bin 14 can be adjusted.

As shown in fig. 1 and 2, a plurality of distributing troughs 151 which are independent from each other and arranged at intervals are formed in the third storage bin 15, and a discharge hole 17 is formed at the bottom of each distributing trough 151.

As shown in fig. 1 and 2, a plurality of first diverter blocks 5 shaped like a triangle are arranged above the second gate plate 4 in the blanking hopper 12, namely in the second storage bin 14. Each first shunting block 5 is arranged above the two adjacent distributing grooves 151, and one vertex angle of each first shunting block faces upwards, and the two adjacent inclined planes incline towards the distributing grooves below the two sides of the first shunting block respectively. The first shunting block 5 has the functions of: when the second gate plate 4 is opened for blanking, the materials slide into the distributing grooves 151 from the second bin 14 through the two inclined surface distributing blocks of the first distributing block 5, so that the materials are distributed at a constant speed, and the materials can be prevented from being stacked on the bottom surface between the adjacent distributing grooves 151.

Furthermore, a plurality of second flow dividing blocks 6 with a triangular shape are arranged above the first gate plate 3 in the upper hopper 11, namely the first storage bin 13. The plurality of second shunting blocks 6 correspond to the plurality of first shunting blocks 5 one by one, and one second shunting block 6 is arranged above each first shunting block 5. Each second flow distribution block 6 is also arranged with one top angle upward and one bottom surface parallel to the first gate plate 3. And each second flow dividing block 6 is provided with an inward concave guide groove 61 on the bottom surface facing the first flashboard 3; the first shutter 3 is also provided with a plurality of guide rails 31 matched with the guide grooves 61, and when the first shutter 3 moves horizontally, the guide rails 31 are embedded in the guide grooves 61 to slide. The second shunting block 6 has the functions of: firstly, the material is divided, so that the material cannot be accumulated at a certain position in the first storage bin in the intermittent feeding process, the material entering the first storage bin is ensured to be discharged first, and the freshness of the material is ensured to be consistent; secondly, the particle materials are prevented from falling into the upper end of the first flow dividing block 5 in the second storage bin 14, so that the first gate plate 3 is blocked by the materials in the opening and closing processes and cannot be completely closed; thirdly, the opening and closing of the first flashboard 3 are better guided.

As shown in fig. 1 and 4, the outside of the hopper 1 is provided with a first cylinder 30 for pushing the first shutter 3 to move. The side wall of the hopper 1 is provided with a first through hole 111, one end of the first gate plate 3 penetrates through the first through hole 111 and extends into the hopper 1, and the other end of the first gate plate is positioned outside the first through hole 111 and connected with the output end of the first cylinder 30. Further, the hopper 1 is provided with a first pressing plate mechanism 7 for keeping the stability of the movement of the first shutter 3 and preventing the material from being brought out in the movement process. The first pressing plate mechanism 7 includes a first guide block 71, a first pressing block 72, and a first spring 73; the first guide block 71 is fixed on the outer side of the upper hopper 11 and is provided with a first guide hole 711 which penetrates up and down; the first pressing block 72 is inserted into the first guide hole 711 and can move up and down along the first guide hole 711; one end of the first spring 73 is fixedly connected to the feeding hopper 11, the other end of the first spring is connected with one end of the first pressing block 72, and the other end of the first pressing block 72 is pressed on the surface of the first gate plate 3; the first spring 73 maintains an elastically deformed state.

As shown in fig. 1 and 5, the outside of the hopper 1 is provided with a second cylinder 40 for pushing the second shutter 4 to move. A second through hole 121 is arranged on the side wall of the hopper 1; one end of the second shutter 4 passes through the second through hole 121 and extends into the hopper 1, and the other end is located outside the second through hole 121 and connected with the output end of the second cylinder 40. Further, a second pressing plate mechanism 8 for keeping the stability of the movement of the second pressing plate 4 and preventing the material from being brought out in the movement process is arranged outside the hopper 1. The second pressing plate mechanism 8 includes a second guide block 81, a second pressing block 82, and a second spring 83; the second guide block 81 is fixed on the outer side of the lower hopper 12 and is provided with a second guide hole 811 which is vertically penetrated; the second pressing block 82 is inserted into the second guide hole 811 and can move up and down along the second guide hole 811; one end of the second spring 83 is fixedly connected to the blanking hopper 12, the other end of the second spring is connected with one end of the second pressing block 82, and the other end of the second pressing block 82 is tightly pressed on the surface of the second gate plate 4; the second spring 83 maintains an elastically deformed state.

Claims (10)

1. The utility model provides a quantitative feeding device with adjustable even cloth of auger and volume which characterized in that: comprises a hopper; a first gate plate and a second gate plate which are both horizontally arranged are arranged in the hopper, and the second gate plate is positioned below the first gate plate; the first gate plate and the second gate plate divide the interior of the hopper into a first bin, a second bin and a third bin from top to bottom in sequence; the first gate plate can horizontally move into and out of the hopper so as to realize communication or separation between the first bin and the second bin; the second gate plate can also horizontally move the feeding and discharging hopper so as to realize the communication or separation between the second bin and the third bin; a feed inlet is formed in the top of the first storage bin, and a horizontally arranged auger is arranged below the feed inlet; the volume of the second storage bin is adjustable and is not larger than that of the first storage bin; a plurality of material distributing grooves which are mutually independent and are arranged at intervals are formed in the third storage bin, and a discharge hole is formed in the bottom of each material distributing groove.

2. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: the hopper is formed by sleeving an upper hopper and a lower hopper; the first gate plate is arranged in the upper hopper, and the second gate plate is arranged in the lower hopper; the outside of going up the hopper is equipped with first connecting block, the outside of hopper is equipped with the second connecting block down, connect through bolt and nut between first connecting block and the second connecting block and make go up the hopper and cup joint between the hopper down apart from adjustable, thereby realize the volume of second feed bin is adjustable.

3. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: the first bin is also internally provided with a first sensor for detecting materials and giving a feeding stopping signal and a second sensor for detecting materials and giving a feeding starting signal; the first sensor is arranged close to the lower part of the packing auger, the second sensor is arranged close to the upper part of the first flashboard, and the horizontal height of the second sensor is lower than that of the first sensor; the volume in the first bin between the horizontal direction of the second sensor and the first gate plate is not less than the volume of the second bin.

4. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: a plurality of first flow dividing blocks in a similar triangular shape are also arranged in the second storage bin; the first shunting blocks are all positioned above the second flashboard, and each first shunting block is arranged above the space between two adjacent distributing grooves; each first shunting block is arranged in a material distributing groove with an upward vertex angle and two adjacent inclined planes which incline towards the lower parts of the two sides of the first shunting block respectively.

5. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: a plurality of second flow dividing blocks similar to triangular bodies are further arranged in the first storage bin; the plurality of second shunting blocks are all positioned above the first flashboard and are arranged at intervals; each second shunting block is arranged with the vertex angle upward.

6. The quantitative feeding device with the auger uniform distribution and the adjustable volume as claimed in claim 4, is characterized in that: a plurality of second flow distribution blocks similar to triangular bodies are further arranged in the first storage bin, and the second flow distribution blocks are all positioned above the first flashboard and are arranged at intervals; the plurality of second shunting blocks are correspondingly arranged above the plurality of first shunting blocks one by one; each second shunting block is provided with an upward vertex angle.

7. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 5 or 6, characterized in that: each second flow dividing block is provided with an inward concave guide groove on the bottom surface facing the first flashboard; the first flashboard is also provided with a plurality of guide rails which are embedded into the guide grooves in a matched manner and slide; the guide groove and the guide rail are mutually matched and installed.

8. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: a first air cylinder for pushing the first gate plate to move and a second air cylinder for pushing the second gate plate to move are further arranged on the outer side of the hopper; a first through hole and a second through hole are formed in the side wall of the hopper; one end of the first gate plate penetrates through the first through hole and extends into the hopper, and the other end of the first gate plate is positioned outside the first through hole and connected with the output end of the first cylinder; one end of the second flashboard penetrates through the second through hole and extends into the hopper, and the other end of the second flashboard is located on the outer side of the second through hole and connected with the output end of the second air cylinder.

9. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: a first pressing plate mechanism is arranged outside the hopper; the first pressing plate mechanism comprises a first guide block, a first pressing block and a first spring; the first guide block is fixed on the outer side of the hopper and is provided with a first guide hole which penetrates through the hopper up and down; the first pressing block is inserted in the first guide hole and can move up and down along the first guide hole; one end of the first spring is fixedly connected to the hopper, the other end of the first spring is connected with one end of the first pressing block, and the other end of the first pressing block is tightly pressed on the surface of the first flashboard; the first spring maintains an elastically deformed state.

10. The quantitative feeding device with the auger uniform distribution and the adjustable volume as set forth in claim 1, characterized in that: a second pressing plate mechanism is arranged outside the hopper; the second pressing plate mechanism comprises a second guide block, a second pressing block and a second spring; the second guide block is fixed on the outer side of the hopper and is provided with a second guide hole which penetrates through the hopper up and down; the second pressing block is inserted into the second guide hole and can move up and down along the second guide hole; one end of the second spring is fixedly connected to the hopper, the other end of the second spring is connected with one end of a second pressing block, and the other end of the second pressing block is tightly pressed on the surface of the second flashboard; the second spring maintains an elastically deformed state.

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