CN214266267U - Plastic recycling particle screening device - Google Patents

Abstract

The utility model discloses a plastics are retrieved granule screening plant, include vibration adjusting device one, vibration adjusting device two, screening plate, direction stabilising arrangement, conveyer belt, pan feeding mouth, large granule discharge gate, tiny particle discharge gate, hold shell and device outer frame. The utility model belongs to the technical field of plastics screening equipment, specifically a plastics recycling particle screening plant, the work efficiency of plastics recycling particle screening plant has been improved, the cost of manufacture of plastics recycling particle screening plant has been reduced through only setting up a vibration driving motor, the consumption of plastics recycling particle screening plant has been reduced through setting up the conveyer belt, through setting up vibration adjusting device one, vibration adjusting device two, the screening board has reduced plastics recycling particle screening plant's use cost, the noise that produces in the plastics recycling particle screening plant operation has been reduced, the use that has improved plastics recycling particle screening plant is experienced, the cost that plastics recycling particle screening plant maintained has been reduced.

Description

Plastic recycling particle screening device

Technical Field

The utility model belongs to the technical field of plastics screening equipment, specifically indicate a plastics recovery granule screening plant.

Background

The existing waste plastics need to be cut into granules after being recycled, plastic particles need to be screened after being cut into granules, the plastic particle screening is to utilize the relative motion of bulk materials and a screen surface to enable partial particles to penetrate through screen holes, the plastic particle materials are divided into different grades according to the particle sizes, the plastic particles are generally continuous, and after screening raw materials are fed to a screening machine, the materials smaller than the size of the screen holes penetrate through the screen holes and are called as undersize products; the material that is greater than sieve mesh size is constantly discharged from the sifter, be called the product on the sieve, present common plastic granules screening plant inefficiency, can not satisfy the operation that the production water line is incessant in succession, be unfavorable for people's use, simultaneously present plastic granules screening plant need operate for a long time and vibration frequency is big, the cost is higher, also lead to spare part to damage easily, and present plastics are retrieved granule screening plant and need be used more motor, the energy consumption is great and can produce a large amount of noises, bring a great deal of inconvenience during the use.

SUMMERY OF THE UTILITY MODEL

To the above situation, for overcoming the defect of prior art, the utility model provides a plastics recycling granule screening plant, the work efficiency of plastics recycling granule screening plant has been improved, the cost of manufacture of plastics recycling granule screening plant has been reduced, the consumption of plastics recycling granule screening plant has been reduced, the use cost of plastics recycling granule screening plant has been reduced, the noise that produces in the plastics recycling granule screening plant operation has been reduced, the use experience of plastics recycling granule screening plant has been improved, the cost of plastics recycling granule screening plant maintenance has been reduced, the life of plastics recycling granule screening plant has been prolonged, it is low effectively to have solved plastics recycling granule screening plant inefficiency on the existing market, and self structure is complicated, maintain comparatively inconvenient problem.

The utility model adopts the following technical scheme: the utility model relates to a plastic recovery particle screening device, which comprises a vibration adjusting device I, a vibration adjusting device II, a screening plate, a guiding stabilizing device, a conveyor belt, a feeding port, a large particle discharging port, a small particle discharging port, a containing shell and an outer device frame, wherein the outer device frame is a hollow shell with only one side wall open, the vibration adjusting device I is arranged on the lower bottom wall in the outer device frame, the vibration adjusting device II is arranged on the lower bottom wall in the outer device frame, the screening plate is arranged between the vibration adjusting device I and the vibration adjusting device II, the guiding stabilizing device is arranged on the vibration adjusting device I and the vibration adjusting device II, the conveyor belt is arranged between the vibration adjusting device I and the vibration adjusting device II, the containing shell is fixedly connected on the inner side wall of the outer device frame, the feeding port is communicated with the upper bottom wall of the containing shell, the large granule discharge gate link up to be located on the right side wall that holds the shell, the tiny particle discharge gate link up to be located on the lower diapire that holds the shell.

Furthermore, the vibration adjusting device comprises a first cam, a first driving gear, a first driven gear, a first gear driving shaft, a first gear driven shaft, a vibration driving motor, a first contact guide plate, a first spring, a first guide post and a first guide plate, wherein the first gear driving shaft is rotatably arranged on the inner side wall of the outer frame of the device, the first gear driven shaft is rotatably arranged on the inner side wall of the outer frame of the device, the first driving gear is fixedly connected to the first gear driving shaft in a penetrating manner, the first driven gear is fixedly connected to the first gear driven shaft in a penetrating manner, the vibration driving motor is arranged on the first gear driving shaft, the first cam is fixedly connected to the first gear driven shaft in a penetrating manner, the first guide plate is fixedly connected to the inner side wall of the outer frame of the device, the first guide post is slidably arranged on the first guide plate in a penetrating manner, and the first contact guide plate is fixedly connected to the lower bottom wall of the first guide post, the first cam is in sliding friction connection with the lower bottom wall of the first contact guide plate, one end of the first spring is fixedly connected to the upper bottom wall of the first contact guide plate, the other end of the first spring is fixedly connected to the lower bottom wall of the first guide plate, and the first spring is arranged on the outer side of the first guide column in a surrounding mode.

Further, the second vibration adjusting device comprises a second cam, a second driving gear, a second driven gear, a second gear driving shaft, a second gear driven shaft, a second contact guiding flat plate, a second spring, a second guide post and a second guide plate, wherein the second gear driving shaft is rotatably arranged on the inner side wall of the outer device frame, the second gear driven shaft is rotatably arranged on the inner side wall of the outer device frame, the second driving gear is fixedly connected to the second gear driving shaft in a penetrating manner, the second driven gear is fixedly connected to the second gear driven shaft in a penetrating manner, the second cam is fixedly connected to the second gear driven shaft in a penetrating manner, the second guide plate is fixedly connected to the inner side wall of the outer device frame in a penetrating manner, the second guide post is slidably arranged on the second guide plate in a penetrating manner, the second contact guiding flat plate is fixedly connected to the lower bottom wall of the second guide post, and the second cam is in sliding friction connection with the lower bottom wall of the second contact guiding flat plate, one end of the second spring is fixedly connected to the upper bottom wall of the second contact guide plate, the other end of the second spring is fixedly connected to the lower bottom wall of the second guide plate, and the two springs are wound on the outer side of the second guide column.

Further, the direction stabilising arrangement includes direction slide bar one, direction slide bar two and two backup pads of slide bar, direction slide bar one rigid coupling is on the lower diapire in the outer frame of device, two backup pads of slide bar rigid couplings are on the inside wall of outer frame of device, two rigid couplings of direction slide bar are on the last diapire of two backup pads of slide bar.

Further, the screening board includes sliding platform one, sliding platform two, aperture sieve, macropore sieve and sieve body, sliding platform one runs through to slide and locates on the direction slide bar one, sliding platform two runs through to slide and locates on the direction slide bar two, sieve body rigid coupling is between sliding platform one and sliding platform two, sieve body runs through to locate and holds in the shell, the aperture sieve link up locates on the sieve body, macropore sieve link up locates on the sieve body.

Further, the conveyor belt is arranged between the first gear driving shaft and the second gear driving shaft.

Further, the first driving gear and the first driven gear are in meshed connection.

Furthermore, the first guide column is fixedly connected to the lower bottom wall of the first sliding platform, and the second guide column is fixedly connected to the lower bottom wall of the second sliding platform.

Adopt above-mentioned structure the utility model discloses the beneficial effect who gains as follows: the utility model provides a plastics recycling particle screening plant, the work efficiency of plastics recycling particle screening plant is improved, the cost of manufacture through only setting up a vibration driving motor has reduced plastics recycling particle screening plant, the consumption of plastics recycling particle screening plant has been reduced through setting up the conveyer belt, through setting up vibration adjusting device one, vibration adjusting device two, the use cost of plastics recycling particle screening plant has been reduced to the screening board, the noise that produces in the plastics recycling particle screening plant operation has been reduced, the use experience of plastics recycling particle screening plant has been improved, the cost that plastics recycling particle screening plant maintained has been reduced, the life of plastics recycling particle screening plant has been prolonged, it is low effectively to have solved plastics recycling particle screening plant in the existing market, and self structure is complicated, maintain comparatively inconvenient problem.

Drawings

FIG. 1 is a front view of the plastic recycled particle screening device of the present invention;

fig. 2 is a partially enlarged view of a portion a of fig. 1.

Wherein, 1, a first vibration adjusting device, 2, a second vibration adjusting device, 3, a screening plate, 4, a guide stabilizing device, 5, a conveyor belt, 6, a feeding port, 7, a large particle discharging port, 8, a small particle discharging port, 9, a containing shell, 10, an outer device frame, 11, a first cam, 12, a first driving gear, 13, a first driven gear, 14, a first gear driving shaft, 15, a first gear driven shaft, 16, a vibration driving motor, 17, a first contact guide flat plate, 18, a first spring, 19, a first guide column, 20, a first guide plate, 21, a second cam, 22, a second driving gear, 23, a second driven gear, 24, a second gear driving shaft, 25, a second gear driven shaft, 26, a second contact guide flat plate, 27, a second spring, 28, a second guide column, 29, a second guide plate, 30, a first guide slide rod, 31, a second guide slide rod, 32, a second slide rod supporting plate, 33. the screen plate comprises first sliding platforms 34, second sliding platforms 35, small-hole screen plates 36, large-hole screen plates 37 and screen plate bodies.

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.

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, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments; based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in the figures 1-2, the plastic recycling particle screening device of the present invention comprises a vibration adjusting device 1, a vibration adjusting device 2, a screening plate 3, a guiding and stabilizing device 4, a conveyor belt 5, a feeding port 6, a large particle discharging port 7, a small particle discharging port 8, a containing shell 9 and an outer device frame 10, wherein the outer device frame 10 is a hollow shell with only one side wall open, the vibration adjusting device 1 is disposed on the lower bottom wall inside the outer device frame 10, the vibration adjusting device 2 is disposed on the lower bottom wall inside the outer device frame 10, the screening plate 3 is disposed between the vibration adjusting device 1 and the vibration adjusting device 2, the guiding and stabilizing device 4 is disposed on the vibration adjusting device 1 and the vibration adjusting device 2, the conveyor belt 5 is disposed between the vibration adjusting device 1 and the vibration adjusting device 2, the containing shell 9 is fixedly connected to the inner side wall of the outer device frame 10, pan feeding mouth 6 link up and locate on the last diapire that holds shell 9, large granule discharge gate 7 link up and locate on the right side wall that holds shell 9, small granule discharge gate 8 link up and locate on the lower diapire that holds shell 9.

The first vibration adjusting device 1 comprises a first cam 11, a first driving gear 12, a first driven gear 13, a first gear driving shaft 14, a first gear driven shaft 15, a vibration driving motor 16, a first contact guide flat plate 17, a first spring 18, a first guide column 19 and a first guide plate 20, wherein the first gear driving shaft 14 is rotatably arranged on the inner side wall of the outer device frame 10, the first gear driven shaft 15 is rotatably arranged on the inner side wall of the outer device frame 10, the first driving gear 12 is fixedly connected onto the first gear driving shaft 14 in a penetrating manner, the first driven gear 13 is fixedly connected onto the first gear driven shaft 15 in a penetrating manner, the vibration driving motor 16 is arranged on the first gear driving shaft 14, the first cam 11 is fixedly connected onto the first gear driven shaft 15 in a penetrating manner, the first guide plate 20 is fixedly connected onto the inner side wall of the outer device frame 10, and the first guide column 19 is slidably arranged on the first guide plate 20 in a penetrating manner, the contact guide flat plate I17 is fixedly connected to the lower bottom wall of the guide column I19, the cam I11 is in sliding friction connection with the lower bottom wall of the contact guide flat plate I17, one end of the spring I18 is fixedly connected to the upper bottom wall of the contact guide flat plate I17, the other end of the spring I18 is fixedly connected to the lower bottom wall of the guide plate I20, and the spring I18 is arranged on the outer side of the guide column I19 in a surrounding mode.

The second vibration adjusting device 2 comprises a second cam 21, a second driving gear 22, a second driven gear 23, a second gear driving shaft 24, a second gear driven shaft 25, a second contact guiding plate 26, a second spring 27, a second guide post 28 and a second guide plate 29, the second gear driving shaft 24 is rotatably arranged on the inner side wall of the outer device frame 10, the second gear driven shaft 25 is rotatably arranged on the inner side wall of the outer device frame 10, the second driving gear 22 is fixedly connected to the second gear driving shaft 24 in a penetrating manner, the second driven gear 23 is fixedly connected to the second gear driven shaft 25 in a penetrating manner, the second cam 21 is fixedly connected to the second gear driven shaft 25 in a penetrating manner, the second guide plate 29 is fixedly connected to the inner side wall of the outer device frame 10 in a penetrating manner, the second guide post 28 is slidably arranged on the second guide plate 29, the second contact guiding plate 26 is fixedly connected to the lower bottom wall of the second guide post 28, and the second cam 21 is in sliding friction connection with the lower bottom wall of the second contact guiding plate 26, one end of the second spring 27 is fixedly connected to the upper bottom wall of the second contact guide plate 26, the other end of the second spring 27 is fixedly connected to the lower bottom wall of the second guide plate 29, and the second spring 27 is arranged on the outer side of the second guide column 28 in a surrounding mode.

The guide stabilizing device 4 comprises a first guide slide bar 30, a second guide slide bar 31 and a second slide bar supporting plate 32, wherein the first guide slide bar 30 is fixedly connected to the lower bottom wall in the outer device frame 10, the second slide bar supporting plate 32 is fixedly connected to the inner side wall of the outer device frame 10, and the second guide slide bar 31 is fixedly connected to the upper bottom wall of the second slide bar supporting plate 32.

Screening board 3 includes sliding platform 33, two 34 of sliding platform, aperture sieve 35, macropore sieve 36 and sieve body 37, sliding platform 33 runs through the slip and locates on guide slide bar 30, two 34 of sliding platform run through the slip and locate on guide slide bar two 31, sieve body 37 rigid coupling is between sliding platform 33 and two 34 of sliding platform, sieve body 37 runs through and locates in holding shell 9, micropore sieve 35 link up locates on sieve body 37, macropore sieve 36 link up and locates on sieve body 37.

The conveyor belt 5 is arranged between the first gear drive shaft 14 and the second gear drive shaft 24.

The first driving gear 12 and the first driven gear 13 are in meshed connection.

The first guide column 19 is fixedly connected to the lower bottom wall of the first sliding platform 33, and the second guide column 28 is fixedly connected to the lower bottom wall of the second sliding platform 34.

When the plastic particle feeding device is used, a user firstly puts recycled and processed plastic particles into the feeding port 6, then the vibration driving motor 16 is started, the first gear driving shaft 14 rotates to drive the first driving gear 12 to rotate, the first driven gear 13 rotates to drive the first gear driven shaft 15 to rotate along with the first gear driving shaft, then the first cam 11 synchronously rotates along with the first gear driving shaft, at the moment, the conveyor belt 5 starts to act along with the first gear driving shaft 14, the second gear driving shaft 24 rotates along with the first gear driving shaft, the second driving gear 22 rotates to drive the second driven gear 23 to rotate along with the second gear driving shaft 25, then the second cam 21 synchronously rotates along with the second gear driving shaft, then the first rotating cam 11 and the second rotating cam 21 respectively drive the first contact guide flat plate 17 and the second contact guide flat plate 26 to reciprocate up and down, and then the first guide column 19 and the second guide column 28 are respectively driven to slide back and forth along the first guide plate 20 and the second guide plate 29, make sliding platform 33 and sliding platform 34 along the slide bar 30 of leading thereupon and two 31 reciprocating sliding of slide bar of leading thereupon, drive sieve body 37 synchronous reciprocating vibration thereupon, less plastic granules falls into in the tiny particle discharge gate 8 through aperture sieve 35 this moment, great plastic granules falls into in large granule discharge gate 7 through macropore sieve 36, can hold the plastic granules of equidimension not with the container of difference put under large granule discharge gate 7 and tiny particle discharge gate 8 respectively this moment, realized the screening processing to plastic granules, it is above that just to the utility model discloses holistic work flow, repeat this step can when using next time.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, 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.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and the embodiments thereof have been described above, but the description is not limited thereto, and the embodiment shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should understand that they should not be limited to the embodiments described above, and that they can design the similar structure and embodiments without departing from the spirit of the invention.

Claims (8)

1. The utility model provides a plastics recycling granule screening plant which characterized in that: the device comprises a first vibration adjusting device, a second vibration adjusting device, a screening plate, a guiding stabilizing device, a conveying belt, a feeding port, a large particle discharging port, a small particle discharging port, a containing shell and an outer device frame, wherein the outer device frame is a hollow shell with only one side wall being opened, the first vibration adjusting device is arranged on the lower bottom wall in the outer device frame, the second vibration adjusting device is arranged on the lower bottom wall in the outer device frame, the screening plate is arranged between the first vibration adjusting device and the second vibration adjusting device, the guiding stabilizing device is arranged on the first vibration adjusting device and the second vibration adjusting device, the conveying belt is arranged between the first vibration adjusting device and the second vibration adjusting device, the containing shell is fixedly connected on the inner side wall of the outer device frame, the feeding port is communicated with the upper bottom wall of the containing shell, and the large particle discharging port is communicated with the right side wall of the containing shell, the small particle discharge hole is arranged on the lower bottom wall of the containing shell in a penetrating way.

2. A plastic recycled particle screening apparatus as recited in claim 1, wherein: the vibration adjusting device comprises a first cam, a first driving gear, a first driven gear, a first gear driving shaft, a first gear driven shaft, a vibration driving motor, a first contact guiding flat plate, a first spring, a first guide post and a first guide plate, wherein the first gear driving shaft is rotatably arranged on the inner side wall of the outer device frame, the first gear driven shaft is rotatably arranged on the inner side wall of the outer device frame, the first driving gear is fixedly connected to the first gear driving shaft in a penetrating manner, the first driven gear is fixedly connected to the first gear driven shaft in a penetrating manner, the vibration driving motor is arranged on the first gear driving shaft, the first cam is fixedly connected to the first gear driven shaft in a penetrating manner, the first guide plate is fixedly connected to the inner side wall of the outer device frame, the first guide post is slidably arranged on the first guide plate in a penetrating manner, the first contact guiding flat plate is fixedly connected to the lower bottom wall of the first guide post in a sliding friction connection with the lower bottom wall of the first contact guiding flat plate, one end of the first spring is fixedly connected to the upper bottom wall of the first contact guide plate, the other end of the first spring is fixedly connected to the lower bottom wall of the first guide plate, and the first spring is arranged on the outer side of the first guide column in a surrounding mode.

3. A plastic recycled particle screening apparatus as recited in claim 2, wherein: the second vibration adjusting device comprises a second cam, a second driving gear, a second driven gear, a second gear driving shaft, a second gear driven shaft, a second contact guide flat plate, a second spring, a second guide post and a second guide plate, the second gear driving shaft is rotatably arranged on the inner side wall of the outer device frame, the second gear driven shaft is rotatably arranged on the inner side wall of the outer device frame, the second driving gear is fixedly connected to the second gear driving shaft in a penetrating manner, the second driven gear is fixedly connected to the second gear driven shaft in a penetrating manner, the second cam is fixedly connected to the second gear driven shaft in a penetrating manner, the second guide plate is fixedly connected to the inner side wall of the outer device frame in a penetrating manner, the second guide post is slidably arranged on the second guide plate in a penetrating manner, the second contact guide flat plate is fixedly connected to the lower bottom wall of the second guide post, the second cam is connected with the lower bottom wall of the second contact guide flat plate in a sliding friction manner, and one end of the second spring is fixedly connected to the upper bottom wall of the second contact guide flat plate, the other end of the second spring is fixedly connected to the lower bottom wall of the second guide plate, and the two springs are wound on the outer side of the second guide column.

4. A plastic recycled particle screening apparatus as recited in claim 3, wherein: the guide stabilizing device comprises a first guide slide bar, a second guide slide bar and a second slide bar supporting plate, wherein the first guide slide bar is fixedly connected to the lower bottom wall in the outer device frame, the second slide bar supporting plate is fixedly connected to the inner side wall of the outer device frame, and the second guide slide bar is fixedly connected to the upper bottom wall of the second slide bar supporting plate.

5. A plastic recycled particle screening apparatus as recited in claim 4, wherein: the screening board includes sliding platform one, sliding platform two, aperture sieve, macropore sieve and sieve body, sliding platform one runs through the slip and locates on the direction slide bar one, sliding platform two runs through the slip and locates on the direction slide bar two, sieve body rigid coupling is between sliding platform one and sliding platform two, sieve body runs through and locates in holding the shell, the aperture sieve link up on locating the sieve body, macropore sieve link up locates on the sieve body.

6. A plastic recycled particle screening apparatus as recited in claim 5, wherein: the conveyor belt is arranged between the first gear driving shaft and the second gear driving shaft.

7. A plastic recycled particle screening apparatus as recited in claim 6, wherein: and the first driving gear and the first driven gear are in meshed connection.

8. A plastic recycled particle screening apparatus as recited in claim 7, wherein: the first guide column is fixedly connected to the lower bottom wall of the first sliding platform, and the second guide column is fixedly connected to the lower bottom wall of the second sliding platform.

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