CN113815964B - Production line and method for automatically detecting mantle of bottle products - Google Patents

Abstract

The invention relates to a production line for automatically detecting a mantle of bottle products, which comprises a bottle arranging unit for ordering bottle bodies, a bottle sorting unit for sequentially conveying the ordered bottle bodies to a first detection station, a first removing station, a second detection station, a second removing station, a mantle station, a third detection station, a third removing station, a pre-shrinking station, a drying station, a first shrinking station, a second shrinking station, a fourth detection station and a transmission unit of the fourth removing station, a metal pollution detection unit, a first side pushing device, a leakage detection unit, a second side pushing device, a mantle unit, a first video detection unit, a third side pushing device, a pre-shrinking unit, a drying unit, a first shrinking unit, a second video detection unit and a fourth side pushing device. The invention has the advantages of saving hands and improving production efficiency.

Description

Production line and method for automatically detecting mantle of bottle products

Technical Field

The invention relates to the technical field of automatic production, in particular to a production line and a method for automatically detecting a mantle of a bottle product.

Background

In the traditional technology, workers are required to manually put bottles for detection and film covering, the whole production process is not connected, the labor cost is high, the efficiency is low, and the quality problem is frequent. Therefore, the problem to be solved by the person skilled in the art is to provide a production line and a method for automatically detecting the mantle of the bottle products.

Disclosure of Invention

Therefore, the invention aims to solve the technical problem that the bottle is required to be put manually in the production process in the prior art, and the whole production process is not connected into a line.

In order to solve the technical problems, the invention provides a production line for automatically detecting a mantle of a bottle product, the device comprises a bottle sorting unit for sorting bottles, a first side pushing device for sequentially conveying the sorted bottles to a first detection station, a first rejection station, a second detection station, a second rejection station, a film sleeving station, a third detection station, a third rejection station, a pre-shrinking station, a drying station, a first shrinkage station, a second shrinkage station, a fourth detection station and a transmission unit of the fourth rejection station, a metal pollution detection unit for detecting metal of the bottles reaching the first detection station, a first side pushing device for rejecting unqualified bottles reaching the first detection station, a leakage detection unit for detecting leakage of the bottles reaching the second detection station, a second side pushing device for rejecting unqualified bottles reaching the second rejection station, a film sleeving unit for sleeving the bottles reaching the film sleeving station, a first video detection unit for detecting first secondary video of the bottles reaching the third detection station, a first side pushing device for detecting the bottles reaching the third detection station, a second side pushing device for detecting the unqualified bottles reaching the third detection station, a second shrinkage unit for shrinking the second shrinkage unit for the second shrinkage unit, a second shrinkage unit for drying the bottles reaching the first shrinkage unit, a second shrinkage unit for drying the bottles reaching the second shrinkage unit, and the fourth side pushing device is used for removing unqualified products reaching the fourth detection station.

Further, reason bottle unit includes reason bottle device and sweeps bottle device, reason bottle device includes the rotary disk, locates the motor of rotary disk bottom and locates the peripheral baffle of rotary disk, the central zone of rotary disk is the hemisphere that makes progress, hemispherical with form the annular groove that is used for accepting the bottle between the baffle, the size of annular groove slightly is greater than the radial dimension of bottle, the motor drives the rotary disk is rotatory with bottle on the hemisphere revolves to the annular groove in and carries out horizontal sequencing, the baffle is equipped with the confession bottle in the annular groove shifts out the opening, the opening is equipped with and is used for carrying out the bottle device of sweeping that water conservancy diversion was exported to the bottle after ordering, sweep bottle device includes pivot and a plurality of blade, the pivot drives the blade rotates and carries out water conservancy diversion output to the bottle.

Further, the motor is an adjustable speed motor.

Further, the transmission unit comprises two parallel transmission belts, the bottle opening part is lapped on the edges of the two parallel transmission belts, and the bottle body part is suspended in a gap between the two parallel transmission belts.

Further, the leakage detection unit comprises a leakage detection machine, and the leakage detection machine is a rotary disc type leakage detection machine.

Further, the pre-shrinking unit comprises a heat shrinking machine, and the heat shrinking machine is a steam heat shrinking machine.

The method for automatically detecting the mantle of the bottle products is characterized by comprising the following steps of:

s1, sorting the bottle bodies;

s2, conveying the bottle bodies to a metal detection station, detecting metal pollution on the bottle bodies on the metal detection station, conveying the bottle bodies subjected to metal detection to a first rejecting station, and rejecting the bottle bodies with metal pollution;

s3, conveying the bottle bodies without metal pollution to a leakage detection station, performing leakage detection on the bottle bodies on the leakage detection station, conveying the bottle bodies with the leakage detection to a second rejecting station, and rejecting the leaked bottle bodies;

s4, conveying the bottle bodies without leakage to a film sleeving station, and sleeving the bottle bodies on the film sleeving station;

s5, conveying the bottle body subjected to the film coating to a first video detection station, carrying out first video detection on the bottle body on the first video detection station, conveying the bottle body subjected to the first video detection to a third removing station, and removing the bottle body with the incorrect film coating;

s6, conveying the bottle body with the correct film to a pre-shrinking station, and preheating and shrinking the bottle body on the pre-shrinking station;

s7, conveying the pre-contracted bottle bodies to a drying station, and drying the bottle bodies on the drying station;

s8, conveying the dried bottle bodies to a first shrinkage station, and performing primary heat shrinkage on the bottle bodies on the first shrinkage station;

s9, conveying the bottle body subjected to the primary heat shrinkage to a second shrinkage station, and performing secondary heat shrinkage on the bottle body on the second shrinkage station;

s10, conveying the bottle body subjected to the secondary heat shrinkage to a second video detection station, carrying out second video detection on the bottle body on the second video detection station, conveying the bottle body subjected to the second video detection to a third rejection station, and rejecting the bottle body with the film which is not fully shrunk;

s11, outputting the bottle body with the completely contracted film, and boxing.

Further, in step S6, the temperature required for preheating and shrinking is 80-82 ℃ and the required time is 10S; in the step S8, the temperature required by primary heat shrinkage is 80-82 ℃ and the time required by primary heat shrinkage is 10S; in the step S9, the temperature required for the secondary heat shrinkage is 80-82 ℃ and the time required for the secondary heat shrinkage is 10S.

Further, in step S7, the temperature required for drying is 70 ℃ and the time required for drying is 50S.

Compared with the prior art, the technical scheme of the invention has the following advantages:

1) Compared with the traditional manual bottle placing production, the invention has the advantages of saving hands and improving production efficiency.

Drawings

In order that the invention may be more readily understood, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings, in which,

FIG. 1 is a first section of a production line for automatically detecting a mantle of a bottle product according to the present invention;

FIG. 2 is a second section of the production line for automatically inspecting a film coating for bottle-like products according to the present invention;

FIG. 3 is a third section of the production line for automatically detecting a mantle of a bottle product according to the present invention;

FIG. 4 is a fourth section of the production line for automatically detecting a mantle of a bottle product according to the present invention.

Description of the specification reference numerals: 10. a bottle arranging unit; 101. a rotating disc; 102. a baffle; 103. an annular groove; 104. a rotating shaft; 105. a blade; 20. a transmission unit; 30. a metal contamination detection unit; 31. a leak detection unit; 32. a film covering unit; 33. a first video detection unit; 34. a pre-shrinking unit; 35. a drying unit; 36. a first shrink unit; 37. a second shrink unit; 38. a second video detection unit; 40. a first side pushing device; 41. a second side pushing device; 42. a third side pushing device; 43. and a fourth side pushing device.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the invention and practice it.

Referring to fig. 1 to 4, a production line for automatically detecting a mantle of a bottle product, comprises a bottle arranging unit 10 for arranging bottles, a transmission unit 20 for sequentially conveying the ordered bottles to a first detection station, a first rejection station, a second detection station, a second rejection station, a film sleeving station, a third detection station, a third rejection station, a pre-shrinking station, a drying station, a first shrinking station, a second shrinking station, a fourth detection station and a fourth rejection station, a metal pollution detection unit 30 for detecting the metal of the bottles reaching the first detection station, a first side pushing device 40 for rejecting the unqualified bottles reaching the first detection station, a leakage detection unit 31 for detecting the leakage of the bottles reaching the second detection station, a second side pushing device 41 for rejecting the unqualified products reaching the second rejection station a film coating unit 32 for coating the bottle body reaching the film coating station, a first video detection unit 33 for performing a first video detection on the bottle body reaching the third detection station, a third side pushing device 42 for removing defective products reaching the third removal station, a pre-shrinking unit 34 for pre-shrinking the bottle body reaching the pre-shrinking station, a drying unit 35 for drying the bottle body reaching the drying station, a first shrinking unit 36 for performing a first heat shrinking treatment on the bottle body reaching the first shrinking station, a second shrinking unit 37 for performing a second heat shrinking treatment on the bottle body reaching the second shrinking station, a second video detection unit 38 for performing a second video detection on the bottle body reaching the fourth detection station, and a fourth side pushing device 43 for removing defective products reaching the fourth detecting station.

In the above, the invention realizes full-automatic production, saves labor cost and improves efficiency.

In a preferred embodiment of the present invention, the bottle arranging unit 10 includes a bottle arranging device and a bottle sweeping device, the bottle arranging device includes a rotary disc 101, a motor disposed at the bottom of the rotary disc, and a baffle plate 102 disposed at the periphery of the rotary disc, a central area of the rotary disc is an upward protruding hemispherical surface, an annular groove 103 for receiving bottles is formed between the hemispherical surface and the baffle plate 102, the size of the annular groove 103 is slightly larger than the radial size of the bottles, the motor drives the rotary disc 101 to rotate so as to spin the bottles on the hemispherical surface into the annular groove 103 for horizontal sorting, the baffle plate 102 is provided with an opening for removing the bottles in the annular groove 103, the opening is provided with a bottle sweeping device for conducting flow to the sorted bottles, the bottle sweeping device includes a rotating shaft 104 and a plurality of blades 105, and the rotating shaft 104 drives the blades 105 to rotate for conducting flow to the bottles.

In a preferred embodiment of this embodiment, the motor is an adjustable speed motor.

In the above, the speed-adjustable motor can control the production speed to reasonably arrange production.

In a preferred embodiment of the present invention, the conveying unit 20 includes two parallel conveying belts, the bottle mouth portion is mounted on edges of the two parallel conveying belts, and the bottle body portion is suspended in a gap between the two parallel conveying belts.

In a preferred embodiment of this embodiment, the leakage detecting unit 31 includes a leak detector, and the leak detector is a turntable type leak detector.

Above, carousel formula leak hunting machine can be fast accurate detect the bottle whether have the problem of leaking the defect.

In a preferred embodiment of the present embodiment, the pre-shrinking unit 34 includes a heat shrinking machine, and the heat shrinking machine is a steam heat shrinking machine.

Above, the steam heat shrinking machine is small in size, does not occupy space, is rapid and quick to install, has wide-range adjustment, and can be suitable for various conveying belts and slideways.

The method for automatically detecting the mantle of the bottle products is characterized by comprising the following steps of:

s1, sorting the bottle bodies;

s2, conveying the bottle bodies to a metal detection station, detecting metal pollution on the bottle bodies on the metal detection station, conveying the bottle bodies subjected to metal detection to a first rejecting station, and rejecting the bottle bodies with metal pollution;

s3, conveying the bottle bodies without metal pollution to a leakage detection station, performing leakage detection on the bottle bodies on the leakage detection station, conveying the bottle bodies with the leakage detection to a second rejecting station, and rejecting the leaked bottle bodies;

s4, conveying the bottle bodies without leakage to a film sleeving station, and sleeving the bottle bodies on the film sleeving station;

s5, conveying the bottle body subjected to the film coating to a first video detection station, carrying out first video detection on the bottle body on the first video detection station, conveying the bottle body subjected to the first video detection to a third removing station, and removing the bottle body with the incorrect film coating;

s6, conveying the bottle body with the correct film to a pre-shrinking station, and preheating and shrinking the bottle body on the pre-shrinking station;

s7, conveying the pre-contracted bottle bodies to a drying station, and drying the bottle bodies on the drying station;

s8, conveying the dried bottle bodies to a first shrinkage station, and performing primary heat shrinkage on the bottle bodies on the first shrinkage station;

s9, conveying the bottle body subjected to the primary heat shrinkage to a second shrinkage station, and performing secondary heat shrinkage on the bottle body on the second shrinkage station;

s10, conveying the bottle body subjected to the secondary heat shrinkage to a second video detection station, carrying out second video detection on the bottle body on the second video detection station, conveying the bottle body subjected to the second video detection to a third rejection station, and rejecting the bottle body with the film which is not fully shrunk;

s11, outputting the bottle body with the completely contracted film, and boxing.

In a preferred embodiment of this embodiment, in step S6, the temperature required for preheating and shrinking is 80-82 ℃ and the time required for preheating and shrinking is 10S; in the step S8, the temperature required by primary heat shrinkage is 80-82 ℃ and the time required by primary heat shrinkage is 10S; in the step S9, the temperature required for the secondary heat shrinkage is 80-82 ℃ and the time required for the secondary heat shrinkage is 10S.

In a preferred embodiment of this embodiment, in step S7, the temperature required for drying is 70 ℃ and the time required for drying is 50S.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations and modifications of the present invention will be apparent to those of ordinary skill in the art in light of the foregoing description. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the invention.

Claims (7)

1. A production line for automatically detecting a mantle of a bottle product is characterized in that, the device comprises a bottle sorting unit for sorting bottles, a first side pushing device for sequentially conveying the sorted bottles to a first detection station, a first rejection station, a second detection station, a second rejection station, a film sleeving station, a third detection station, a third rejection station, a pre-shrinking station, a drying station, a first shrinkage station, a second shrinkage station, a fourth detection station and a transmission unit of the fourth rejection station, a metal pollution detection unit for detecting metal of the bottles reaching the first detection station, a first side pushing device for rejecting unqualified bottles reaching the first detection station, a leakage detection unit for detecting leakage of the bottles reaching the second detection station, a second side pushing device for rejecting unqualified bottles reaching the second rejection station, a film sleeving unit for sleeving the bottles reaching the film sleeving station, a first video detection unit for detecting first secondary video of the bottles reaching the third detection station, a first side pushing device for detecting the bottles reaching the third detection station, a second side pushing device for detecting the unqualified bottles reaching the third detection station, a second shrinkage unit for shrinking the second shrinkage unit for the second shrinkage unit, a second shrinkage unit for drying the bottles reaching the first shrinkage unit, a second shrinkage unit for drying the bottles reaching the second shrinkage unit, A fourth side pushing device for removing the unqualified products reaching the fourth detection station;

the bottle arranging unit comprises a bottle arranging device and a bottle sweeping device, the bottle arranging device comprises a rotary disc, a motor arranged at the bottom of the rotary disc and a baffle arranged at the periphery of the rotary disc, the central area of the rotary disc is a hemispherical surface protruding upwards, an annular groove for bearing a bottle body is formed between the hemispherical surface and the baffle, the size of the annular groove is slightly larger than the radial size of the bottle body, the motor drives the rotary disc to rotate so as to rotate the bottle body on the hemispherical surface into the annular groove for transverse sorting, the baffle is provided with an opening for removing the bottle body in the annular groove, the opening is provided with the bottle sweeping device for conducting flow guiding output on the sorted bottle body and enabling the bottle body to stand, the bottle sweeping device comprises a rotary shaft and a plurality of blades, and the rotary shaft drives the blades to rotate so as to conduct flow guiding output on the bottle body;

the conveying unit comprises two conveying belts which are arranged in parallel, the bottle opening part of the bottle body is lapped on the edges of the two conveying belts which are arranged in parallel, and the bottle body part of the bottle body is suspended in a gap between the two conveying belts which are arranged in parallel.

2. The automatic bottle product detection and film covering production line according to claim 1, wherein the motor is an adjustable speed motor.

3. The production line for automatically detecting a sleeve film for bottle products according to claim 1, wherein the leakage detecting unit comprises a leakage detecting machine, and the leakage detecting machine is a rotary disc type leakage detecting machine.

4. The automatic bottle product detection film covering production line according to claim 1, wherein the pre-shrinking unit comprises a heat shrinking machine, and the heat shrinking machine is a steam heat shrinking machine.

5. The method for automatically detecting the mantle of the bottle products is characterized by comprising the following steps of:

s1, sorting the bottle bodies;

s2, conveying the bottle bodies to a metal detection station, detecting metal pollution on the bottle bodies on the metal detection station, conveying the bottle bodies subjected to metal detection to a first rejecting station, and rejecting the bottle bodies with metal pollution;

s3, conveying the bottle bodies without metal pollution to a leakage detection station, performing leakage detection on the bottle bodies on the leakage detection station, conveying the bottle bodies with the leakage detection to a second rejecting station, and rejecting the leaked bottle bodies;

s4, conveying the bottle bodies without leakage to a film sleeving station, and sleeving the bottle bodies on the film sleeving station;

s5, conveying the bottle body subjected to the film coating to a first video detection station, carrying out first video detection on the bottle body on the first video detection station, conveying the bottle body subjected to the first video detection to a third removing station, and removing the bottle body with the incorrect film coating;

s6, conveying the bottle body with the correct film to a pre-shrinking station, and preheating and shrinking the bottle body on the pre-shrinking station;

s7, conveying the pre-contracted bottle bodies to a drying station, and drying the bottle bodies on the drying station;

s8, conveying the dried bottle bodies to a first shrinkage station, and performing primary heat shrinkage on the bottle bodies on the first shrinkage station;

s9, conveying the bottle body subjected to the primary heat shrinkage to a second shrinkage station, and performing secondary heat shrinkage on the bottle body on the second shrinkage station;

s10, conveying the bottle body subjected to the secondary heat shrinkage to a second video detection station, carrying out second video detection on the bottle body on the second video detection station, conveying the bottle body subjected to the second video detection to a third rejection station, and rejecting the bottle body with the film which is not fully shrunk;

s11, outputting the bottle body with the completely contracted film, and boxing.

6. The method for automatically detecting a mantle of a bottle product according to claim 5, wherein in the step S6, the temperature required for preheating and shrinking is 80-82 ℃ and the time required for preheating and shrinking is 10S; in the step S8, the temperature required by primary heat shrinkage is 80-82 ℃ and the time required by primary heat shrinkage is 10S; in the step S9, the temperature required for the secondary heat shrinkage is 80-82 ℃ and the time required for the secondary heat shrinkage is 10S.

7. The method for automatically inspecting a coating film for bottle products according to claim 5, wherein in step S7, the temperature required for drying is 70 ℃ and the time required for drying is 50S.