CN114750389A

CN114750389A - PBT raw material distributing device

Info

Publication number: CN114750389A
Application number: CN202210481015.9A
Authority: CN
Inventors: 毛建华
Original assignee: Suzhou Fulihua Plastic Technology Co ltd
Current assignee: Suzhou Fulihua Plastic Technology Co ltd
Priority date: 2022-05-05
Filing date: 2022-05-05
Publication date: 2022-07-15

Abstract

The invention relates to the technical field of PBT raw material processing, in particular to a PBT raw material distribution device, which comprises a material box, a plurality of peripheral rotary drums and material conveying machine barrels, wherein the peripheral rotary drums are butted with the material box; the material box is connected with the peripheral rotating cylinders through corresponding material conveying pipelines, the peripheral rotating cylinders are internally provided with turnover auger frames, the peripheral rotating cylinders are externally connected with a linkage case, and the linkage case is used for driving the turnover auger frames; the linkage machine box is internally provided with a main driving shaft, a plurality of medium driving shafts arranged on the side edges of the main driving shaft and feeding driving shafts in one-to-one correspondence with the medium driving shafts, the main driving shaft is connected with the medium driving shafts through proportioning transmission pieces, the feeding driving shafts are connected with the medium driving shafts through synchronous transmission pieces, and the main driving shaft and the feeding driving shafts are used for driving the movement of the turnover auger frame.

Description

PBT raw material distributing device

Technical Field

The invention relates to the technical field of PBT raw material processing, in particular to a PBT raw material distribution device.

Background

The PBT raw material is fed into a raw material bin after being mixed, and then needs to be distributed into different double-screw extruders for subsequent treatment. However, in the past, raw materials are manually fed into different feeding bins of the extruder, but the manual feeding mode not only wastes labor force, but also has low efficiency.

Chinese patent (publication number: CN107471589A) discloses a PBT raw material distribution device, wherein a plurality of conveying pipes are connected to the bottom of a raw material bin, the tail ends of the conveying pipes are communicated with feeding bins of all extruders, so that PBT raw materials can be fed into all the extruders, and each conveying pipe is also provided with a manual valve for controlling feeding of each extruder; however, the prior art patents have certain defects, the PBT raw materials are often distributed according to the proportion of the related processing technology, and the prior art can only adopt independent distribution devices to distribute the materials respectively, but cannot synchronously distribute the corresponding PBT raw materials according to the proportion.

Disclosure of Invention

The invention aims to provide a PBT raw material distribution device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

a PBT raw material distribution device comprises a material box, a plurality of peripheral drums butted with the material box, and material conveying machine barrels butted with the peripheral drums one by one;

the material box is connected with the peripheral rotating cylinders through corresponding material conveying pipelines, the peripheral rotating cylinders are internally provided with a turnover auger frame, the peripheral rotating cylinders are externally connected with a linkage case, and the linkage case is used for driving the turnover auger frame;

The linkage machine box is internally provided with a main driving shaft, a plurality of medium driving shafts arranged on the side edges of the main driving shaft and feeding driving shafts in one-to-one correspondence with the medium driving shafts, the main driving shaft is connected with the medium driving shafts through proportioning transmission pieces, the feeding driving shafts are connected with the medium driving shafts through synchronous transmission pieces, and the main driving shaft and the feeding driving shafts are used for driving the movement of the turnover auger frame.

As a further scheme of the invention: the proportioning transmission part comprises a plurality of driving parts arranged on the main driving shaft and driven parts arranged on the medium driving shaft.

As a further scheme of the invention: the driving machine part comprises a driven disc installed on a medium driving shaft, a transmission outer edge is arranged on the periphery of the driven disc, a plurality of transmission fork supports are arranged on the transmission outer edge at equal angles, transmission notches are formed in the transmission fork supports, the driven machine part comprises a power disc installed on a main driving shaft, linkage protrusions are arranged on the edge of the disc face of the power disc, and the linkage protrusions are in butt joint with the transmission notches.

As a further scheme of the invention: the synchronous transmission part comprises linkage wheels which are respectively arranged on the medium driving shaft and the feeding driving shaft, and the linkage wheels are connected through a synchronous belt.

As a further scheme of the invention: the medium drive shaft includes fixed axostylus axostyle and flexible axostylus axostyle, fixed axostylus axostyle is fixed mounting with the driven plate, the linkage wheel is installed on flexible axostylus axostyle, the rod end and the driven plate butt joint of flexible axostylus axostyle.

As a further scheme of the invention: the improved telescopic shaft is characterized in that a butt joint notch is formed in the disc surface of the driven disc, a butt joint boss is arranged at the axis position of the butt joint notch, inner-connection insections are arranged on the edge of an inner opening of the butt joint notch, a butt joint is arranged at the rod end of the telescopic shaft, an embedded round table is arranged on the butt joint, a butt joint notch matched with the butt joint boss is formed in the axis of the embedded round table, and outer-connection insections matched with the inner-connection insections are arranged on the periphery of the embedded round table.

As a further scheme of the invention: the shaft wall of the telescopic shaft lever is provided with a linear notch, and the corresponding linkage wheel is butted with the linear notch through the embedded inner strip so as to be loaded on the telescopic shaft lever.

As a still further scheme of the invention: defeated material barrel embeds there is defeated material drive shaft, install defeated material drive auger in the defeated material drive shaft, defeated material barrel is built internally and externally to have the carriage, installs driving motor on the carriage, and driving wheel is installed to driving motor's drive end, install from the driving wheel in the defeated material drive shaft, the driving wheel is connected through the drive belt between with the follow driving wheel.

Compared with the prior art, the invention has the beneficial effects that:

the PBT raw material is output from a material box and conveyed into a corresponding operation machine bin through a plurality of material conveying machine barrels, and a peripheral rotating cylinder is arranged between the material box and each material conveying machine barrel; controlling the material conveying proportioning condition of the material conveying machine barrel through the peripheral drum; a turnover auger frame is arranged in the peripheral rotary drum and used for distributing materials in the material conveying machine barrel, and the linkage case controls the movement rate of the turnover auger frame so as to control the material conveying speed of the material conveying machine barrel, namely control the material conveying amount in the same time; the linkage machine box is internally provided with a main driving shaft as a power output shaft part, a medium driving shaft is driven to move according to a certain transmission ratio by a proportioning driving part, and then the medium driving shaft drives a feeding driving shaft to move through synchronous motion, so that the motion speed of a turnover auger frame in each turnover cylinder is controlled according to a certain proportion, namely, the material of each material conveying cylinder is distributed according to a certain proportion, and the PBT raw material is synchronously distributed according to the proportion.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present application and together with the description, serve to explain the principles of the application. Also, the drawings and the description are not intended to limit the scope of the present concepts in any way, but rather to illustrate the concepts of the present disclosure to those skilled in the art by reference to specific embodiments.

Fig. 1 is a schematic overall structure diagram of a PBT raw material distribution device provided in an embodiment of the present invention.

Fig. 2 is a schematic view illustrating an installation of the linkage case and the revolving drum according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a linkage chassis according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a proportioning driver according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a feeding cylinder according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a docking slot according to an embodiment of the present invention.

Fig. 7 is a schematic structural view of a telescopic shaft according to an embodiment of the present invention.

Fig. 8 is a schematic structural view of a linkage wheel coupled to a telescopic shaft according to an embodiment of the present invention.

In the figure: 11-a material tank; 12-a delivery pipe; 13-week of the drum; 14-a conveying cylinder; 15-turnover auger frame; 16-a linkage chassis; 21-a main drive shaft; 22-a media drive shaft; 23-a feed drive shaft; 24-proportioning a transmission piece; 25-a synchronous drive; 31-an equipment frame; 32-a support bearing; 33-a drive mechanism; 34-a driven member; 35-a linkage wheel; 36-a synchronous belt; 41-a power disc; 42-a linkage projection; 43-a driven disc; 44-a drive outer edge; 45-a transmission fork; 46-a drive notch; 51-a fixed shaft; 52-a telescopic shaft; 61-docking notches; 62-inscribe insection; 63-butting bosses; 72-butt joint; 73-embedding the circular truncated cone; 74-circumscribed insection; 75-a docking notch; 76-linear notches; 77-chimeric inner strip; 81-material conveying driving shaft; 82-conveying the conveying driving auger; 83-a drive frame; 84-a drive motor; 85-driving wheels; 86-a transmission belt; 87-driven wheel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, examples of which are shown in the drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements, unless otherwise indicated.

It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

In one embodiment;

referring to fig. 1, a PBT raw material distribution device is provided, which includes a material tank 11, a plurality of peripheral drums 13 in butt joint with the material tank 11, and material delivery machine barrels 14 in one-to-one butt joint with the peripheral drums 13;

the material box 11 is connected with the peripheral rotating cylinder 13 through a corresponding material conveying pipeline 12, a peripheral auger frame 15 is arranged in each peripheral rotating cylinder 13, a linkage case 16 is externally connected to each peripheral rotating cylinder 13, and the linkage case 16 is used for driving the peripheral auger frame 15;

referring to fig. 2, a main driving shaft 21, a plurality of medium driving shafts 22 disposed at the side edges of the main driving shaft 21, and feeding driving shafts 23 corresponding to the medium driving shafts 22 one by one are disposed in the linkage case 16, the main driving shaft 21 and the medium driving shafts 22 are connected by a proportioning transmission member 24, the feeding driving shafts 23 and the medium driving shafts 22 are connected by a synchronous transmission member 25, and both the main driving shaft 21 and the feeding driving shafts 23 are used for driving the motion of the epicyclic auger frame 15.

In the embodiment, the PBT raw material is output from the material box 11 and is conveyed into the corresponding operating machine bin through the plurality of material conveying machine barrels 14, and a revolving drum 13 is arranged between the material box 11 and each material conveying machine barrel 14; the material conveying proportioning condition of a material conveying cylinder 14 is controlled through a peripheral drum 13;

During operation, materials are output from the material box 11 and are guided into the peripheral rotating cylinder 13 through the material conveying pipeline 12, the peripheral rotating cylinder 13 is internally provided with the turnover auger frame 15 for distributing the materials into the material conveying cylinder 14, and the linkage case 16 controls the movement rate of the turnover auger frame 15, so that the material conveying speed of the material conveying cylinder 14 is controlled, namely the material conveying amount in the same time is controlled; the linkage case 16 takes a main driving shaft 21 as a power output shaft member, a medium driving shaft 22 is driven to move through a proportioning transmission member 24 according to a certain transmission ratio, the medium driving shaft 22 drives a feeding driving shaft 23 to move through synchronous movement, and therefore the movement speed of the revolving auger frame 15 in each revolving drum 13 is controlled according to a certain proportion, namely, materials of each material conveying cylinder 14 are distributed according to a certain proportion, and PBT raw materials are synchronously distributed according to the proportion.

In one embodiment;

for the specific implementation structure of the linkage case 16, the present embodiment is designed as follows:

referring to fig. 3, an equipment frame 31 is disposed in the linkage case 16, a plurality of support bearings 32 are disposed on the equipment frame 31, the main driving shaft 21, the medium driving shaft 22 and the feeding driving shaft 23 are mounted in the equipment frame 31 through the support bearings 32, and the proportioning driver 24 includes a plurality of driving members 33 mounted on the main driving shaft 21 and driven members 34 mounted on the medium driving shaft 22.

Referring to fig. 4, the driving mechanism 33 includes a driven disc 43 mounted on the medium driving shaft 22, a transmission outer edge 44 is disposed on the periphery of the driven disc 43, a plurality of transmission fork arms 45 are disposed on the transmission outer edge 44 at equal angles, transmission notches 46 are disposed on the transmission fork arms 45, the driven mechanism 34 includes a power disc 41 mounted on the main driving shaft 21, a linking protrusion 42 is disposed on the disc surface edge of the power disc 41, and the linking protrusion 42 is abutted to the transmission notches 46.

The main driving shaft 21 and the medium driving shaft 22 are driven by the driving mechanism 33 and the driven mechanism 34, the main driving shaft 21 moves to drive the power disc 41 to move, and the power disc 41 drives the transmission fork 45 to move through the linkage protrusion 42 when moving, so as to drive the driven disc 43 to move and further drive the medium driving shaft 22 to move; each time the power disc 41 rotates one circle, the linkage protrusion 42 on the power disc 41 is butted with the next transmission notch 46 of the driven disc 43, namely, the driven disc 43 is driven to rotate by the angle of the angular distance between two adjacent transmission notches 46, so that the transmission ratio between the main driving shaft 21 and the medium driving shaft 22 is controlled, the main driving shaft 21 is butted with the corresponding medium driving shaft 22 through the independent driving mechanism 33, and each medium driving shaft 22 is driven to transmit at the corresponding transmission ratio.

As an example, the present embodiment shows a mechanism arrangement of the proportioning driver 24, and the present embodiment is designed to control the rotation rate ratio between the main driving shaft 21 and the medium driving shaft 22 to be 4:1 by the 4:1 ratio transmission between the driving gear 33 and the driven gear 34, and the driven disc 43 rotates 1/4 radians for every rotation of the power disc 41; the proportioning data can be set according to actual requirements.

Referring to fig. 3, the synchronous transmission member 25 includes linkage wheels 35 respectively mounted on the medium driving shaft 22 and the material supplying driving shaft 23, and the linkage wheels 35 are connected through a synchronous belt 36. The synchronous transmission member 25 adopts a synchronous belt transmission mode to drive the medium driving shaft 22 and the corresponding feeding driving shaft 23 to perform synchronous transmission.

In one embodiment;

for the conveying structure of the conveying cylinder 14, the present embodiment is designed as follows:

referring to fig. 5, a material conveying driving shaft 81 is arranged in the material conveying cylinder 14, a material conveying driving auger 82 is mounted on the material conveying driving shaft 81, a driving frame 83 is arranged in the material conveying cylinder 14, a driving motor 84 is mounted on the driving frame 83, a driving wheel 85 is mounted at a driving end of the driving motor 84, a driven wheel 87 is mounted on the material conveying driving shaft 81, and the driving wheel 85 is connected with the driven wheel 87 through a driving belt 86.

The conveying machine barrel 14 is communicated with the peripheral rotating barrel 13, materials enter the conveying machine barrel 14, the driving motor 84 serves as a power source mechanism, the conveying driving shaft 81 is driven to move through the driving belt 86, and the conveying driving auger 82 drives the materials to be input into the corresponding operating machine bin.

In one embodiment;

in view of the fact that there is a certain difference in the feeding time of different working machine cabins, and the related raw materials sometimes need to be put in or stopped at different time ends, the present embodiment is further configured as follows:

referring to fig. 3, 4, 6 and 7, the medium driving shaft 22 includes a fixed shaft 51 and a telescopic shaft 52, the fixed shaft 51 is fixedly mounted to the driven disc 43, the linkage wheel 35 is mounted on the telescopic shaft 52, and a rod end of the telescopic shaft 52 is abutted to the driven disc 43.

The disc surface of the driven disc 43 is provided with a butt joint notch 61, the axial line position of the butt joint notch 61 is provided with a butt joint boss 63, the edge of the inner opening of the butt joint notch 61 is provided with an inner-connection insection 62, the rod end of the telescopic shaft rod 52 is provided with a butt joint 72, the butt joint 72 is provided with an embedding round platform 73, the axial line position of the embedding round platform 73 is provided with a butt joint notch 75 matched with the butt joint boss 63, and the periphery of the embedding round platform 73 is provided with an outer-connection insection 74 matched with the inner-connection insection 62.

In the present embodiment, the medium driving shaft 22 includes a fixed shaft 51 and a telescopic shaft 52, the fixed shaft 51 forms a fixed support for mounting the driven disc 43, the telescopic shaft 52 is telescopically mounted on the equipment frame 31, an electrically controlled telescopic end is externally connected to drive the telescopic shaft 52 to move in a telescopic manner, one side of the driven disc 43 is fixedly mounted with the fixed shaft 51, and the other side of the driven disc is provided with a docking notch 61, a docking joint 72 is provided at a rod end of the telescopic shaft 52 for docking with the docking notch 61, the docking notch 75 is engaged with the docking boss 63, the external insection 74 is engaged with the internal insection 62, so as to drive the telescopic shaft 52 to perform synchronous transmission, and the telescopic shaft 52 drives the material supply driving shaft 23 to perform synchronous motion through the synchronous transmission member 25;

when a certain material conveying cylinder 14 does not need to be fed again, the operation can be suspended, the electric control telescopic end is used for driving the telescopic shaft rod 52 to stretch and displace, so that the butt joint 72 at the rod end of the telescopic shaft rod 52 is separated from the butt joint notch 61, the transmission relation between the telescopic shaft rod 52 and the driven disc 43 is not generated, the motion of the driven disc 43 cannot drive the corresponding telescopic shaft rod 52 to move, and the feeding of the corresponding material conveying cylinder 14 is stopped; when the material supply needs to be recovered, the butt joint 72 at the rod end of the telescopic shaft rod 52 is butted with the butt joint notch 61, so that the original transmission ratio relation can be maintained, and the material supply can be rapidly recovered.

Preferably, referring to fig. 7 and 8, a linear notch 76 is formed on the shaft wall of the telescopic shaft 52, and the corresponding linkage wheel 35 is butted with the linear notch 76 through a tabling inner strip 77 so as to be loaded on the telescopic shaft 52. In the process of extending and retracting the telescopic shaft 52, the combination status with the linkage wheel 35 is always kept, and the position of the linkage wheel 35 is not influenced.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present specification describes embodiments, not every embodiment includes only a single embodiment, and such description is for clarity purposes only, and it is to be understood that all embodiments may be combined as appropriate by one of ordinary skill in the art to form other embodiments as will be apparent to those of skill in the art from the description herein.

Claims

1. A PBT raw material distribution device comprises a material box, a plurality of peripheral drums butted with the material box, and material conveying machine barrels butted with the peripheral drums one by one; it is characterized in that the preparation method is characterized in that,

the material box is connected with the peripheral rotating cylinders through corresponding material conveying pipelines, the peripheral rotating cylinders are internally provided with turnover auger frames, the peripheral rotating cylinders are externally connected with a linkage case, and the linkage case is used for driving the turnover auger frames;

2. The PBT feedstock dispensing device of claim 1, wherein the linkage box is provided with an equipment frame, the equipment frame is provided with a plurality of support bearings, the main drive shaft, the medium drive shaft and the supply drive shaft are mounted in the equipment frame through the support bearings, and the proportioning transmission member comprises a plurality of driving members mounted on the main drive shaft and driven members mounted on the medium drive shaft.

3. The PBT raw material dispensing device of claim 2, wherein the driving mechanism comprises a driven disc mounted on the medium driving shaft, the driven disc is provided with a driving outer edge on the periphery thereof, a plurality of driving fork supports are arranged on the driving outer edge at equal angles, the driving fork supports are provided with driving notches, the driven mechanism comprises a power disc mounted on the main driving shaft, and the disc surface edge of the power disc is provided with a linkage protrusion which is butted with the driving notches.

4. The PBT raw material distribution device of claim 3, wherein the synchronous transmission member comprises linkage wheels respectively arranged on the medium driving shaft and the feeding driving shaft, and the linkage wheels are connected with each other through a synchronous belt.

5. The PBT feedstock dispensing device of claim 4, wherein the media drive shaft comprises a fixed shaft and a telescopic shaft, the fixed shaft is fixedly mounted to the driven disk, the linkage wheel is mounted to the telescopic shaft, and a rod end of the telescopic shaft is abutted to the driven disk.

6. The PBT raw material distribution device according to claim 5, wherein a butt joint notch is arranged on a disc surface of the driven disc, a butt joint boss is arranged on an axial position of the butt joint notch, an inner joint insection is arranged on an inner opening edge of the butt joint notch, a butt joint is arranged on a rod end of the telescopic shaft, an embedded circular table is arranged on the butt joint, a butt joint notch matched with the butt joint boss is arranged on an axial position of the embedded circular table, and an outer connection insection matched with the inner joint insection is arranged on the periphery of the embedded circular table.

7. The PBT raw material dispensing device according to claim 6, wherein a linear notch is provided on the shaft wall of the telescopic shaft, and the corresponding linkage wheel is loaded on the telescopic shaft by butting the embedded inner strip with the linear notch.

8. The PBT raw material dispensing device of any one of claims 1-7, wherein a conveying driving shaft is arranged in the conveying cylinder, a conveying driving auger is arranged on the conveying driving shaft, a driving frame is arranged in the conveying cylinder, a driving motor is arranged on the driving frame, a driving wheel is arranged at the driving end of the driving motor, a driven wheel is arranged on the conveying driving shaft, and the driving wheel is connected with the driven wheel through a driving belt.