CN107214161B - Bottle embryo overturning and cleaning system - Google Patents

Abstract

The invention discloses a bottle embryo overturning cleaning system, which comprises a bottle embryo input guide rail, a rotating wheel type bottle embryo overturning mechanism and a bottle embryo output guide rail which are arranged obliquely from left to right in sequence; the rotating wheel type bottle embryo overturning mechanism comprises a shell, a driving mechanism and a rotating wheel mechanism; the rotating wheel mechanism comprises a rotating wheel and a plurality of buffer clapboards, and a containing channel for containing bottle blanks is formed between every two adjacent buffer clapboards; the shell is also internally provided with a guardrail component; the shell is provided with a bottle embryo guide piece; the bottle embryo output port of the bottle embryo input guide rail is connected with the input port of the arc embryo inlet channel, and the output port of the arc embryo outlet channel is connected with the bottle embryo input port of the bottle embryo output guide rail. The rotary wheel type bottle embryo overturning mechanism can realize continuous splitting of bottle embryos, has the characteristics of stable operation, convenient disassembly and assembly and low maintenance cost, and meanwhile, the rotary wheel type bottle embryo overturning mechanism realizes bottle embryo overturning by driving the rotary wheel to rotate through the driving mechanism, is not limited by the appearance and the gravity center position of the bottle embryo, and is suitable for bottle embryos of various specifications.

Description

Bottle embryo overturning and cleaning system

Technical Field

The invention relates to a cleaning system, in particular to a bottle embryo overturning cleaning system.

Background

The plastic packaging bottle is mainly applied to liquid type product packaging, has the characteristics of low packaging cost price and convenient transportation, has wide application range, is widely applied to liquid food packaging, and needs hot filling packaging in order to meet the requirements of fresh keeping and quality guarantee, and has higher clean and quality requirements. In the process of processing the plastic packaging bottles, the plastic packaging bottles are firstly molded into bottle blanks by an injection molding machine and then blow molded by a bottle blowing machine. Some charged dust or small scraps are attached to the surfaces of bottle blanks produced in the existing flow production line and fall off, and the quality of packaging bottles is directly affected. Meanwhile, during the filling production process, a very small amount of impurities such as packing box scraps, tiny packing plastic bag residues and the like can be found in the bottle blanks. The volume of the impurities is extremely small, and the plastic bag is transparent, so that the manual empty bottle lamp inspection is difficult to find.

In order to solve the cleaning problem of plastic packaging bottles, a bottle embryo overturning cleaning mechanism of a rotary bottle blowing machine appears in the prior art, and the bottle embryo overturning cleaning mechanism adopts an unpowered spiral guide rail which is fixedly arranged in an upper section of linear conveying guide rail and a lower section of linear conveying guide rail. When a certain number of bottle blanks are arranged and enter the spiral guide rail, under the self weight and the extrusion action of the bottle blanks, the bottle blanks pass through the guide rail along the spiral track, so that the bottle blanks can be turned up and down. The cleaning function is realized by the same nozzle and the negative pressure discharge system. The specific structure of the unpowered spiral guide rail 200 can be seen in fig. 1, and the arrangement of bottle blanks 100 in the guide rail can be seen in fig. 2. The working principle of the spiral guide rail turnover mechanism is as follows: the supporting ring of the bottle embryo is used as a working supporting point, and the kinetic energy required by the gravity center deflection of the bottle embryo is provided by the self weight of the bottle embryo and the extrusion of the embryo row. Although this kind of upset clean mechanism has solved plastics packaging bottle's clean problem to a certain extent, it still has following shortcoming:

1. when the bottle blank is relatively long and relatively large, the gravity center of the bottle blank is far away from the supporting ring, so that the bottle blank can generate relatively large deflection force, and the overturning function cannot be realized;

2. the extrusion force is provided by the following embryo rows to realize the function, and when the number of embryo rows is insufficient, the embryo cannot normally operate;

3. when local damage occurs in the guide rail, the whole guide rail needs to be replaced, and the cost is high.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention aims to provide a bottle embryo overturning cleaning system which can realize continuous separation of bottle embryos, and a rotating wheel type bottle embryo overturning mechanism has the characteristics of stable operation, convenient disassembly and assembly and low maintenance cost, and meanwhile, the bottle embryo overturning cleaning system realizes bottle embryo overturning by driving a rotating wheel to rotate through a driving mechanism, is not limited by the appearance and the gravity center position of the bottle embryo, and is suitable for bottle embryos with various specifications.

The invention adopts the following technical scheme:

a bottle embryo overturning cleaning system, which is characterized in that: comprises a bottle embryo input guide rail, a rotating wheel type bottle embryo overturning mechanism and a bottle embryo output guide rail which are arranged obliquely from left to right in sequence;

the rotating wheel type bottle embryo overturning mechanism comprises a shell, a driving mechanism fixedly arranged on the shell and a rotating wheel mechanism arranged in the shell; an output shaft of the driving mechanism extends into the shell, and the driving mechanism drives the rotating wheel mechanism to rotate; the top of the shell is provided with a notch for inputting and outputting bottle blanks; the rotating wheel mechanism comprises a rotating wheel arranged on the output shaft; the rotating wheel comprises a hub and a plurality of buffer baffle plates which are arranged along the radial direction of the hub in an outward extending way, wherein the buffer baffle plates are uniformly distributed along the circumferential direction of the hub, and a containing channel for containing bottle blanks is formed between every two adjacent buffer baffle plates; the inside of the shell is also provided with a guardrail component for preventing the bottle embryo from falling off from the accommodating channel in the overturning process; a bottle embryo guide piece is arranged at the position of the notch on the shell, and an arc embryo inlet channel and an arc embryo outlet channel which are not communicated with each other are arranged on the bottle embryo guide piece;

the bottle embryo output port of the bottle embryo input guide rail is connected with the input port of the arc-shaped embryo inlet channel, and the output port of the arc-shaped embryo outlet channel is connected with the bottle embryo input port of the bottle embryo output guide rail.

Further, the bottle embryo feeding device also comprises a closed bottle embryo input channel and a bottle embryo output channel; the bottle embryo input guide rail is fixedly arranged in the bottle embryo input channel, the bottle embryo output guide rail is fixedly arranged in the bottle embryo output channel, and the rotating wheel type bottle embryo turnover mechanism is arranged between the bottle embryo input channel and the bottle embryo output channel.

Further, at least one nozzle is arranged in the shell at a position corresponding to the bottle mouth of the bottle embryo downwards, and the nozzle is connected with a cleaning gas circuit containing negative ions.

Further, a drain outlet is arranged at the lower part of the shell and is connected with the dust collector through an air pipe.

Further, the receiving channel has a top opening, a first side opening, and a second side opening;

the guardrail assembly comprises a top split retaining ring, a first side split retaining ring and a second side split retaining ring which are respectively fixed on the inner wall of the shell; the first side split retaining ring and the second side split retaining ring are respectively arranged at the positions of two opposite sides of the buffer baffle; the top split retaining ring is positioned at the outer side of the circumference of the buffer baffle; the top split retaining ring, the first side split retaining ring and the second side split retaining ring are provided with a fracture for the bottle embryo to pass through at positions corresponding to the notch of the shell.

The top opening retainer ring is used for preventing the bottle embryo from falling from the top opening of the accommodating channel in the overturning process, the first side opening retainer ring is used for preventing the bottle embryo from falling from the first side opening of the accommodating channel in the overturning process, and the second side opening retainer ring is used for preventing the bottle embryo from falling from the second side opening of the accommodating channel in the overturning process.

Further, the top split retaining ring, the first side split retaining ring and the second side split retaining ring are all bead ring structures.

Further, the top split retaining ring, the first side split retaining ring and the second side split retaining ring are fixedly connected with the inner wall of the shell through a plurality of guardrail adjusting seats; the position of the top split ring corresponding to each containing channel is provided with at least one guardrail adjusting seat, the position of the first side split ring corresponding to each containing channel is provided with at least one guardrail adjusting seat, and the position of the second side split ring corresponding to each containing channel is provided with at least one guardrail adjusting seat.

Further, the guardrail adjusting seat comprises a fixed sleeve, a clamping piece and a bolt;

the fixed sleeve is provided with a large-radius connecting hole and a small-radius connecting hole, and the large-radius connecting hole and the small-radius connecting hole are communicated with each other; the fixed sleeve is embedded on the inner wall of the shell, and the large-radius end of the fixed sleeve is positioned in the shell;

the clamping piece comprises a plugging part plugged in the large-radius connecting hole of the fixed sleeve and a clamping part positioned outside the large-radius connecting hole, and the radius of the clamping part is larger than that of the plugging part; the clamping part is axially provided with a clamping hole for clamping the top split retaining ring, the first side split retaining ring or the second side split retaining ring, and the inserting part is axially provided with an internal threaded hole;

the bolt is provided with an external thread connecting part, and the external thread connecting part penetrates through the small-radius connecting hole of the fixed sleeve and is in threaded connection with the internal thread hole of the clamping piece.

Further, the driving mechanism comprises a motor, a first belt pulley, a belt and a second belt pulley, wherein the motor is fixed on the shell and is in transmission connection with the first belt pulley, the belt is sleeved on the first belt pulley and the second belt pulley, and the second belt pulley is in transmission connection with the output shaft. Further, the motor is a variable frequency motor or a servo motor.

Further, the buffer baffle is a nylon plate; the number of the accommodating channels is more than three.

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

1. the bottle embryo overturning cleaning system comprises a bottle embryo input guide rail, a rotating wheel type bottle embryo overturning mechanism and a bottle embryo output guide rail which are sequentially arranged obliquely from left to right, wherein the rotating wheel type bottle embryo overturning mechanism is driven by a driving mechanism to rotate, a containing channel for containing bottle embryos is formed between every two adjacent buffer baffle plates on a rotating wheel, the tightness of the bottle embryos is proper, and a guardrail component for preventing the bottle embryos from falling off from the containing channel in the overturning process is further arranged in a shell. The design of the independent buffer baffle plates is realized, and the damaged plate blocks are replaced during maintenance, so that the spiral guide rail mechanism is more economical. Therefore, the bottle blanks sequentially pass through the bottle blank input guide rail, the rotating wheel type bottle blank overturning mechanism and the bottle blank output guide rail under the action of self gravity, so that the continuous separation and the taking of the bottle blanks are realized; the rotating wheel type bottle embryo overturning mechanism has the characteristics of stable operation, convenient disassembly and assembly and low maintenance cost, and meanwhile, the rotating wheel type bottle embryo overturning mechanism realizes bottle embryo overturning by driving the rotating wheel to rotate through the driving mechanism, is not limited by the appearance and the gravity center position of the bottle embryo, and is suitable for bottle embryos of various specifications.

2. The top split retaining ring, the first side split retaining ring and the second side split retaining ring of the rotating wheel type bottle embryo overturning mechanism are fixedly connected with the inner wall of the shell through a plurality of guardrail adjusting seats; when the bolt is rotated clockwise, the clamping piece is enabled to move in a direction away from the accommodating channel, so that the bead ring structure is loosened; when the bolt is rotated anticlockwise, the clamping piece is moved towards the direction approaching the accommodating channel, and the bead ring structure is tightened. The mechanism has stronger adjustability, and can normally operate by adjusting the guardrail adjusting seat when parts are slightly worn or bottle blanks are slightly changed.

3. The rotating wheel type bottle embryo overturning mechanism is provided with the nozzle and the negative pressure discharging system, so that the cleaning function of dust, fiber and other adhesive pollutants and larger particle pollutants in the bottle embryo is realized.

Drawings

FIG. 1 is a schematic view of a prior art unpowered spiral guide rail;

FIG. 2 is a schematic diagram of the arrangement of bottle blanks inside an unpowered spiral guide rail in the prior art;

FIG. 3 is a schematic view of the overall structure of the bottle embryo overturning cleaning system of the present invention;

FIG. 4 is a schematic diagram of the overall structure of the wheel type bottle embryo overturning mechanism of the invention;

FIG. 5 is a schematic view of the structure of the wheel type bottle embryo overturning mechanism of the invention with part of the outer shell removed;

FIG. 6 is a schematic view of the structure of the wheel mechanism of the present invention when rotated to a certain position;

FIG. 7 is a cross-sectional view taken in the direction A-A of FIG. 6;

FIG. 8 is a schematic view of the wheel mechanism of the present invention rotated to another station;

FIG. 9 is a B-B sectional view of FIG. 8;

fig. 10 is a schematic structural view of the guard rail adjusting seat of the present invention.

In the figure: 10. a housing; 11. a notch; 20. a driving mechanism; 21. a motor; 22. a first pulley; 23. a belt; 24. a second pulley; 25. an output shaft; 30. a wheel mechanism; 31. a rotating wheel; 311. a hub; 312. a buffer baffle; 313. a receiving channel; 40. a guardrail assembly; 41. a top split retainer ring; 42. a first side split ring; 43. a second side split ring; 50. a preform guide; 51. an arc-shaped embryo inlet channel; 52. an arc-shaped embryo outlet channel; 60. a guardrail adjusting seat; 61. fixing the sleeve; 611. a large radius connection hole; 612. a small radius connection hole; 62. a clamping member; 621. a plug-in part; 6211. an internal threaded hole; 622. a clamping part; 6221. a clamping hole; 63. a bolt; 631. an external thread connection; 70. a nozzle; 80. a bottle embryo input guide rail; 81. a bottle embryo input channel; 90. a bottle embryo output guide rail; 91. a bottle embryo output channel; 100. a bottle embryo; 200. a spiral guide rail.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and detailed description, wherein it is to be understood that, on the premise of no conflict, the following embodiments or technical features may be arbitrarily combined to form new embodiments. The materials used in this example are all commercially available.

Example 1:

referring to fig. 3-10, a bottle embryo overturning cleaning system comprises a bottle embryo input guide rail 80, a rotary wheel type bottle embryo overturning mechanism and a bottle embryo output guide rail 90 which are arranged obliquely from left to right in sequence;

the rotating wheel type bottle embryo overturning mechanism comprises a shell 10, a driving mechanism 20 fixedly arranged on the shell 10 and a rotating wheel mechanism 30 arranged inside the shell 10; an output shaft 25 of the driving mechanism 20 extends into the shell 10, and the driving mechanism 20 drives the rotating wheel mechanism 30 to rotate; the top of the shell 10 is provided with a notch 11 for inputting and outputting bottle blanks;

the wheel mechanism 30 includes a wheel 31 mounted on the output shaft 25; the rotating wheel 31 comprises a hub 311 and a plurality of buffer baffle plates 312 which are arranged along the radial direction of the hub 311 in an outward extending way, wherein the buffer baffle plates 312 are uniformly distributed along the circumferential direction of the hub 311, and a containing channel 313 for containing the bottle embryo 100 is formed between every two adjacent buffer baffle plates 312; the housing 10 also has a barrier assembly 40 disposed therein for preventing the bottle blank 100 from falling out of the receiving channel 313 during tipping. A bottle embryo guide piece 50 is arranged on the shell 10 at the position of the notch 11, and an arc embryo inlet channel 51 and an arc embryo outlet channel 52 which are not communicated with each other are arranged on the bottle embryo guide piece 50. The arc-shaped blank inlet channel 51 and the arc-shaped blank outlet channel 52 respectively receive the linear conveying guide rail, and transitional bottle blanks smoothly enter and exit the accommodating channel 313 of the rotating wheel.

The bottle embryo output port of the bottle embryo input guide rail 80 is connected with the input port of the arc-shaped embryo inlet channel, and the output port of the arc-shaped embryo outlet channel is connected with the bottle embryo input port of the bottle embryo output guide rail 90.

Further, the bottle embryo feeding channel 81 and the bottle embryo outputting channel 91 are also closed; the bottle embryo input guide rail is fixedly arranged in the bottle embryo input channel, the bottle embryo output guide rail is fixedly arranged in the bottle embryo output channel, and the rotating wheel type bottle embryo turnover mechanism is arranged between the bottle embryo input channel and the bottle embryo output channel.

As a preferred embodiment, at least one nozzle 70 is arranged in the shell 10 at a position corresponding to the bottle mouth of the bottle embryo downwards, and the nozzle 70 is connected with a cleaning gas circuit containing negative ions. The cleaning gas circuit comprises a high-pressure cleaning main pipeline, one end of the high-pressure cleaning main pipeline is connected with a high-pressure cleaning pipe, and the other end of the high-pressure cleaning main pipeline is connected with a negative ion generator; the other end of the negative ion generator is connected with a high-pressure cleaning fan. When the bottle blank 100 moves to the corresponding position with the bottle mouth downward along with the rotating wheel mechanism 30, the high-pressure negative ion gas is utilized to wash the bottle blank 100.

As a preferred embodiment, the lower part of the housing 10 is provided with a drain port connected to the cleaner through an air duct. The sewage outlet is connected with the high-efficiency negative pressure industrial dust collector through an air pipe, so that the functions of dust removal and sundry removal are realized.

As a preferred embodiment, the receiving channel 313 has a top opening, a first side opening and a second side opening;

the guardrail assembly 40 includes a top split collar 41, a first side split collar 42 and a second side split collar 43 secured to the inner wall of the housing 10, respectively; the first side split ring 42 and the second side split ring 43 are respectively disposed at positions of opposite sides of the buffer baffle 312; the top split washer 41 is located circumferentially outside the buffer baffle 312; the top split ring 41, the first side split ring 42 and the second side split ring 43 are provided with a fracture for the bottle embryo 100 to pass through at positions corresponding to the notch 11 of the shell 10.

The top split ring 41 is used for preventing the bottle embryo 100 from falling out of the top opening of the accommodating channel 313 during the overturning process, the first side split ring 42 is used for preventing the bottle embryo from falling out of the first side opening of the accommodating channel 313 during the overturning process, and the second side split ring 43 is used for preventing the bottle embryo 100 from falling out of the second side opening of the accommodating channel 313 during the overturning process.

As a preferred embodiment, both sides of the buffer baffle 312 are provided with grooves. The first and second split collars 42, 43 may be embedded in corresponding grooves.

As a preferred embodiment, the top split ring 41, the first side split ring 42 and the second side split ring 43 are all bead ring structures. The bottle embryo 100 can be kept and guided by matching with a plurality of bead ring structures. The head and tail of the fracture of each bead ring structure is reasonably designed and bent, so that the bottle embryo 100 can be guided into and out of the accommodating channel 313 of the rotating wheel conveniently.

As a preferred embodiment, the top split ring 41, the first side split ring 42 and the second side split ring 43 are fixedly connected to the inner wall of the housing 10 through a plurality of guard rail adjusting seats 60; at least one guardrail adjusting seat 60 is arranged on the top split retaining ring 41 corresponding to each accommodating channel 313, at least one guardrail adjusting seat 60 is arranged on the first side split retaining ring 42 corresponding to each accommodating channel 313, and at least one guardrail adjusting seat 60 is arranged on the second side split retaining ring 43 corresponding to each accommodating channel 313.

As a preferred embodiment, the guard rail adjusting seat 60 includes a fixed sleeve 61, a clamping piece 62, and a bolt 63; the fixed sleeve 61 is provided with a large-radius connection hole 611 and a small-radius connection hole 612, and the large-radius connection hole 611 and the small-radius connection hole 612 are communicated with each other; the fixed sleeve 61 is embedded on the inner wall of the shell 10, and the large radius end of the fixed sleeve 61 is positioned inside the shell 10; the clamping piece 62 comprises a plug-in part 621 which is plugged into the large-radius connecting hole 611 of the fixed sleeve 61 and a clamping part 622 which is positioned outside the large-radius connecting hole 611, wherein the radius of the clamping part 622 is larger than that of the plug-in part 621; the clamping part 622 is axially provided with a clamping hole 6221 for clamping the top split retainer 41, the first side split retainer 42 or the second side split retainer 43, and the plug part 621 is axially provided with an internal threaded hole 6211; the bolt 63 has an externally threaded connecting portion 631, and the externally threaded connecting portion 631 is screwed with the internally threaded hole 6211 of the holder 62 through the small-radius connecting hole 612 of the fixed sleeve 61. When the bolt 63 is rotated clockwise, the clamping member 62 is moved in a direction away from the accommodation channel 313, so that the bead ring structure is released; when the bolt 63 is rotated counterclockwise, the clamping member 62 is moved in a direction approaching the receiving passage 313, so that the bead ring structure is tightened.

In a preferred embodiment, the buffer spacer 312 is a nylon plate.

As a preferred embodiment, the driving mechanism 20 comprises a motor 21, a first belt pulley 22, a belt 23 and a second belt pulley 24, wherein the motor 21 is fixed on the housing 10 and is in transmission connection with the first belt pulley 22, the belt is sleeved on the first belt pulley 22 and the second belt pulley 24, and the second belt pulley 24 is in transmission connection with the output shaft 25. More preferably, the motor 21 is a variable frequency motor or a servo motor.

Other embodiments:

the number of the receiving passages 313 is three, twelve, twenty-four or more.

The above embodiments are only preferred embodiments of the present invention, and the scope of the present invention is not limited thereto, but any insubstantial changes and substitutions made by those skilled in the art on the basis of the present invention are intended to be within the scope of the present invention as claimed.

Claims (6)

1. A bottle embryo overturning cleaning system, which is characterized in that: comprises a bottle embryo input guide rail, a rotating wheel type bottle embryo overturning mechanism and a bottle embryo output guide rail which are arranged obliquely from left to right in sequence;

the rotating wheel type bottle embryo overturning mechanism comprises a shell, a driving mechanism fixedly arranged on the shell and a rotating wheel mechanism arranged in the shell; an output shaft of the driving mechanism extends into the shell, and the driving mechanism drives the rotating wheel mechanism to rotate; the top of the shell is provided with a notch for inputting and outputting bottle blanks; the rotating wheel mechanism comprises a rotating wheel arranged on the output shaft; the rotating wheel comprises a hub and a plurality of buffer baffle plates which are arranged along the radial direction of the hub in an outward extending way, wherein the buffer baffle plates are uniformly distributed along the circumferential direction of the hub, and a containing channel for containing bottle blanks is formed between every two adjacent buffer baffle plates; the inside of the shell is also provided with a guardrail component for preventing the bottle embryo from falling off from the accommodating channel in the overturning process; a bottle embryo guide piece is arranged at the position of the notch on the shell, and an arc embryo inlet channel and an arc embryo outlet channel which are not communicated with each other are arranged on the bottle embryo guide piece;

the bottle embryo output port of the bottle embryo input guide rail is connected with the input port of the arc-shaped embryo inlet channel, and the output port of the arc-shaped embryo outlet channel is connected with the bottle embryo input port of the bottle embryo output guide rail;

the receiving channel has a top opening, a first side opening, and a second side opening;

the guardrail assembly comprises a top split retaining ring, a first side split retaining ring and a second side split retaining ring which are respectively fixed on the inner wall of the shell; the first side split retaining ring and the second side split retaining ring are respectively arranged at the positions of two opposite sides of the buffer baffle; the top split retaining ring is positioned at the outer side of the circumference of the buffer baffle; the top split retaining ring, the first side split retaining ring and the second side split retaining ring are respectively provided with a fracture for a bottle embryo to pass through at positions corresponding to the notches of the shell;

the top split retaining ring, the first side split retaining ring and the second side split retaining ring are fixedly connected with the inner wall of the shell through a plurality of guardrail adjusting seats; the position of the top split ring corresponding to each containing channel is provided with at least one guardrail adjusting seat, the position of the first side split ring corresponding to each containing channel is provided with at least one guardrail adjusting seat, and the position of the second side split ring corresponding to each containing channel is provided with at least one guardrail adjusting seat;

the guardrail adjusting seat comprises a fixed sleeve, a clamping piece and a bolt;

the fixed sleeve is provided with a large-radius connecting hole and a small-radius connecting hole, and the large-radius connecting hole and the small-radius connecting hole are communicated with each other; the fixed sleeve is embedded on the inner wall of the shell, and the large-radius end of the fixed sleeve is positioned in the shell;

the clamping piece comprises a plugging part plugged in the large-radius connecting hole of the fixed sleeve and a clamping part positioned outside the large-radius connecting hole, and the radius of the clamping part is larger than that of the plugging part; the clamping part is axially provided with a clamping hole for clamping the top split retaining ring, the first side split retaining ring or the second side split retaining ring, and the inserting part is axially provided with an internal threaded hole;

the bolt is provided with an external thread connecting part, and the external thread connecting part penetrates through the small-radius connecting hole of the fixed sleeve and is in threaded connection with the internal thread hole of the clamping piece;

the bottle embryo overturning cleaning system further comprises a closed bottle embryo input channel and a bottle embryo output channel; the bottle embryo input guide rail is fixedly arranged in the bottle embryo input channel, the bottle embryo output guide rail is fixedly arranged in the bottle embryo output channel, and the rotating wheel type bottle embryo turnover mechanism is arranged between the bottle embryo input channel and the bottle embryo output channel.

2. The bottle embryo overturning cleaning system according to claim 1, wherein at least one nozzle is arranged in the shell at a position corresponding to the bottle opening of the bottle embryo downwards, and the nozzle is connected with a cleaning gas circuit containing anions.

3. The bottle embryo overturning cleaning system of claim 1 wherein a drain is provided at a lower portion of the housing, the drain being connected to the vacuum cleaner by an air duct.

4. The bottle embryo tumble cleaning system according to claim 1 wherein the top split ring, the first side split ring and the second side split ring are all bead ring structures.

5. The bottle embryo tumble cleaning system according to claim 1 wherein the drive mechanism comprises a motor, a first pulley, a belt and a second pulley, the motor being secured to the housing and in driving connection with the first pulley, the belt being journaled on the first pulley and the second pulley, the second pulley being in driving connection with the output shaft.

6. The bottle embryo overturning cleaning system of claim 1, wherein the buffer baffle is a nylon plate; the number of the accommodating channels is more than three.

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