CN109365312B

CN109365312B - Big data management screening assembly line of contact lens

Info

Publication number: CN109365312B
Application number: CN201811077768.3A
Authority: CN
Inventors: 匡艳红
Original assignee: Jiaxing Meirui Network Technology Co Ltd
Current assignee: Jiaxing Meirui Network Technology Co., Ltd
Priority date: 2018-09-16
Filing date: 2018-09-16
Publication date: 2020-10-13
Anticipated expiration: 2038-09-16
Also published as: CN109365312A

Abstract

The invention relates to a contact lens big data management screening assembly line which comprises a base, a rotary material placing table, a feeding structure, an optometry structure, a marking structure and a material receiving structure, wherein the rotary material placing table is arranged on the base; the parameters of the contact lenses are analyzed through the principle of optical induction, and then the parameters of each contact lens are finally obtained through quantizing the analysis result, so that the parameters of the contact lenses can be sampled, the classification of the contact lenses is facilitated, and then the product is printed and marked by combining big data, so that a screening effect is achieved.

Description

Big data management screening assembly line of contact lens

Technical Field

The invention relates to the technical field of contact lens production or processing, in particular to a contact lens big data management screening production line.

Background

Contact lenses, also known as contact lenses, are lenses that are worn on the cornea of the eye to correct vision or protect the eye. It includes three kinds of hard, semi-hard and soft according to the hardness of the material. The contact lens brings great improvement to patients with ametropia such as myopia, hyperopia, astigmatism and the like from the aspects of appearance and convenience. The visual field is wide, the visual objects are vivid, and the special effects are exerted on the aspects of controlling the development of myopia and astigmatism of teenagers, treating special eye diseases and the like. The hospital specialist reminds a regular hospital or a lens dispensing mechanism to carry out detailed examination when wearing the contact lenses, selects the contact lenses suitable for being worn by the hospital specialist, pays attention to eye hygiene, avoids causing other eye symptoms, and timely goes to the hospital to carry out examination if finding discomfort after wearing. Silicone hydrogel, hydrated polymers (methyl methacrylate, hydroxyethyl methacrylate, glycerolipid methacrylate, etc.).

At present, parameters of the contact lenses are detected in a manual recording mode, and the contact lenses cannot be detected, so that the contact lenses cannot be uniformly and effectively managed.

Disclosure of Invention

In view of the above, the present invention provides a contact lens big data management screening pipeline to solve the above problems.

In order to solve the technical problems, the technical scheme of the invention is as follows: a contact lens big data management screening assembly line comprises a base, a rotary material placing table, a feeding structure, an optometry structure, a marking structure and a material receiving structure;

the rotary material placing table is provided with a plurality of material placing grooves and a rotary driving piece, the material placing grooves are used for placing glasses packaging pieces, a packaging cavity is formed in each glasses packaging piece, contact lenses are placed in the packaging cavity, and the rotary driving piece is used for driving the rotary material placing table to rotate so that each material placing groove sequentially passes through the material feeding structure, the optometry structure, the marking structure and the material receiving structure;

the feeding structure comprises a feeding driving piece and a feeding track, the feeding driving piece is used for feeding the glasses packaging piece into the feeding track, and the glasses packaging piece falls into the material placing groove along the feeding track;

the optometry structure comprises an upper light sealing frame and a lower light sealing seat, an upper light sealing piece and a light sealing driving piece are arranged on the upper light sealing frame, the light sealing driving piece is used for driving the upper light sealing piece to move so as to tightly press or loosen the glasses packaging piece to the lower light sealing seat, and an upper alignment structure and a lower alignment structure are respectively arranged at two ends of the glasses packaging piece; the upper light sealing frame is also provided with a light supply structure, the light supply structure comprises a light supply spotlight and a light supply probe, and the light supply spotlight is used for providing a preset convergence light source and outputting the convergence light source from the light supply probe through a first light path preset in the light supply structure; the lower light sealing seat is provided with a light collecting structure, the light collecting structure comprises a light collecting probe and a light collecting plate, the light collecting probe is used for receiving a light source and sending the light source to the light collecting plate through a third light path preset in the light collecting structure, and the light collecting plate outputs light collecting irradiation information according to the distribution of light and the illumination intensity; when the glasses packaging piece is pressed on the lower light sealing seat, a second light path is formed inside the packaging cavity, the input end of the second light path is formed by matching the light supply probe and the upper alignment structure, and the output end of the second light path is formed by matching the light collecting probe and the lower alignment structure;

the marking structure is provided with a marking generator and a marker, the marking generator is provided with a marking table, the marking table stores a plurality of mutually related light collecting irradiation information and corresponding lens characteristic information, when the optometry structure outputs one piece of light collecting irradiation information, the corresponding lens characteristic information is obtained according to the marking table, a corresponding marking code is generated according to the lens characteristic information, and the marker prints the marking code to a corresponding glasses packaging piece;

the material receiving structure comprises a material receiving rail, and when the material placing groove passes through the material receiving rail, the material receiving rail receives the glasses packaging piece on the material placing groove.

Further: the mark code is set as a two-dimensional graphic code, and the two-dimensional graphic code is scanned to obtain corresponding lens characteristic information.

Further: the upper alignment structure further comprises a sealing layer, and when the light supply probe is matched with the upper alignment structure, the sealing layer is extruded to reduce the space in the packaging cavity so that the contact lens in the packaging cavity is horizontally placed under the impact of extrusion force.

Further: and a sodium chloride solution is filled in the packaging cavity.

Further: the light collecting device is characterized by further comprising a controller, wherein the controller is provided with a triggering strategy, the triggering strategy comprises that a triggering illumination sensor is arranged in the center of the light collecting plate, the triggering illumination sensor is used for detecting the illumination intensity of the position where the triggering illumination sensor is located, when the illumination intensity fed back by the triggering illumination sensor exceeds a triggering illumination threshold value, triggering information is output, and the controller receives the light collecting illumination information according to the triggering information.

Further: the triggering illumination threshold value is in direct proportion to the illumination intensity of the beam-converging light source.

Further: the light supply structure comprises a light supply pipe, the light supply probe is arranged on the light supply pipe, the first light path is formed in the light supply pipe, and the light supply pipe and the light supply probe are fixed through clamping.

Further: the light supply adjusting structure is provided with a plurality of light supply tubes, different light adjusting mirrors are arranged in the light supply tubes to enable first light paths in the light supply tubes to be different, the light supply adjusting structure is provided with a mechanical hand grip, and the light supply tubes are replaced on the upper sealing light frame through the mechanical hand grip.

The technical effects of the invention are mainly reflected in the following aspects: through setting up like this, the parameter of contact lens is analyzed through the principle of optical induction, then through quantizing the parameter that obtains every contact lens at last to the analysis result, just so can sample the parameter of contact lens, is favorable to the classification to contact lens, secondly combines big data to print the mark to the product, plays a screening effect.

Drawings

FIG. 1: the structure schematic diagram of the contact lens big data management screening production line is disclosed;

FIG. 2: an enlarged view of part a of fig. 2 of the contact lens big data management screening pipeline of the present invention;

FIG. 3: the structure schematic diagram of the lens packaging part of the contact lens big data management screening production line is disclosed;

FIG. 4: the contact lens big data management screening production line comprises an optometry structure schematic diagram;

FIG. 5: the system of the invention is constructed by a topological diagram.

Reference numerals: 1. an eyeglass package; 11. a packaging cavity; 12. an upper alignment structure; 13. a lower alignment structure; 2. a controller; 100. a base; 200. rotating the material placing table; 210. a material placing groove; 220. a rotary drive member; 300. an optometric structure; 310. an upper sealing frame; 311. an upper sealing member; 312. a sealing light driving member; 320. a lower sealing seat; 321. a light collecting probe; 322. a light collecting plate; 331. a light supply spot lamp; 332. a light supply probe; 333. a light supply pipe; 400. a light-providing regulating structure; 410. a mechanical gripper; 500. a feeding structure; 510. a feeding driving member; 520. feeding a material track; 600. a marker structure; 610. a marker generator; 620. A marker; 710. receive the material track.

Detailed Description

The following detailed description of the embodiments of the present invention is provided in order to make the technical solution of the present invention easier to understand and understand.

Referring to fig. 1, a contact lens big data management screening assembly line includes a base 100, a rotary material placing table 200, a material feeding structure 500, an optometry structure 300, a marking structure 600, and a material receiving structure; the entire contact lens line is first detailed in terms of functional principles.

The rotary material placing table 200 is provided with a plurality of material placing grooves 210 and a rotary driving member 220, the material placing grooves 210 are used for placing the spectacle packages 1, a packaging cavity 11 is formed inside the spectacle package 1, contact lenses are placed in the packaging cavity 11, and the rotary driving member 220 is used for driving the rotary material placing table 200 to rotate so that each material placing groove 210 sequentially passes through the material feeding structure 500, the optometry structure 300, the marking structure 600 and the material receiving structure; first, as shown in fig. 1, each material placing groove 210 is formed by two clamping blocks, and the height of the whole glasses package 1 is greater than that of the material placing groove 210, so that the subsequent operation and the driving of the glasses package 1 can be facilitated.

The feeding structure 500 comprises a feeding driving member 510 and a feeding track 520, the feeding driving member 510 is used for feeding the glasses package 1 into the feeding track 520, and the glasses package 1 falls into the material placing groove 210 along the feeding track 520; the feeding track 520 is simple, and the glasses package member 1 is a cylindrical body, so that feeding can be realized through the feeding vibrating screen machine, and the glasses package member 1 is conveyed to the material placing groove 210 through the track, so that a fixing effect can be achieved, and feeding is realized.

The optometry structure 300 comprises an upper light sealing frame 310 and a lower light sealing base 320, wherein an upper light sealing piece 311 and a light sealing driving piece 312 are arranged on the upper light sealing frame 310, the light sealing driving piece 312 is used for driving the upper light sealing piece 311 to move so as to press or loosen the glasses packaging piece 1 to the lower light sealing base 320, and an upper alignment structure 12 and a lower alignment structure 13 are respectively arranged at two ends of the glasses packaging piece 1; the upper sealing optical frame 310 is further provided with an optical supply structure, the optical supply structure comprises an optical supply lamp 331 and an optical supply probe 332, the optical supply lamp 331 is used for providing a preset beam-receiving light source and outputting from the optical supply probe 332 through a first optical path preset in the optical supply structure; a light collecting structure is arranged on the lower light sealing seat 320, the light collecting structure comprises a light collecting probe 321 and a light collecting plate 322, the light collecting probe 321 is used for receiving a light source and sending the light source to the light collecting plate 322 through a third light path preset in the light collecting structure, and the light collecting plate 322 outputs light collecting irradiation information according to the distribution of light and the illumination intensity; when the eyeglass package 1 is pressed against the lower light sealing seat 320, a second light path is formed inside the package cavity 11, an input end of the second light path is formed by the light supply probe 332 and the upper alignment structure 12 in a matching manner, and an output end of the second light path is formed by the light collection probe 321 and the lower alignment structure 13 in a matching manner; the optometry structure 300 is a more central design point of the present invention, and firstly, the optometry structure 300 is composed of two parts, one is an upper wall-broken structure, as shown in fig. 2, the upper light-sealing member 311 is driven by the light-sealing driving member 312 to move downwards, and then can be matched with the lens package 1, a light source is projected inside the light-sealing cavity, and the light source is irradiated on the lower light-sealing seat 320 under the condition of the refraction of the contact lens according to the light source distribution of the light-collecting plate 322 on the lower light-sealing seat 320, so that the parameters of the contact lens can be extracted, and the optometry structure is particularly suitable for recovering the contact lens and then carrying out subsequent application, and thus the parameters of the contact lens can be retrieved under the most economical and effective conditions, and then the classification and recovery can be carried out. The upper alignment structure 12 further includes a sealing layer, and when the light-providing probe 332 is matched with the upper alignment structure 12, the sealing layer is pressed to reduce the space in the package cavity 11 so that the contact lens inside the package cavity 11 is placed in a flat state under the impact of the pressing force. Therefore, the contact lens can be ensured to be horizontally arranged during detection, and the detection effect is improved. And the packaging cavity 11 is filled with sodium chloride solution. The controller 2 is configured with a triggering strategy, the triggering strategy includes that a triggering illuminance sensor is configured in the center of the light collection plate 322, the triggering illuminance sensor is used for detecting the illumination intensity of the position where the triggering illuminance sensor is located, when the illumination intensity fed back by the triggering illuminance sensor exceeds a triggering illuminance threshold value, triggering information is output, and the controller 2 receives the light collection irradiation information according to the triggering information. Firstly, only when the contact lens is horizontally placed, the illumination intensity fed back by the trigger illumination sensor can exceed the trigger illumination threshold, and by judging the condition, the light collecting illumination information can be ensured to be acquired when the contact lens is horizontally placed, so that the accuracy is improved. The upper end and the lower end of the glasses package 1 are made of transparent materials, and have light transmittance, and specifically, the glasses package can be made of transparent plastics and has a smooth surface.

The marking structure 600 is configured with a marking generator 610 and a marker 620, the marking generator 610 is configured with a marking table, the marking table stores a plurality of light collection irradiation information and corresponding lens characteristic information which are related to each other, when the optometry structure 300 outputs a light collection irradiation information, the corresponding lens characteristic information is obtained according to the marking table, and a corresponding marking code is generated according to the lens characteristic information, and the marker 620 prints the marking code onto the corresponding glasses package 1; the mark code is set as a two-dimensional graphic code, and the two-dimensional graphic code is scanned to obtain corresponding lens characteristic information. Firstly, a marking table is detailed, the marking table can be recorded and stored in advance according to actual conditions, then corresponding contact lenses can be found according to the light-collecting irradiation information for parameter analysis, then lens characteristic information can be printed on the glasses package 1, so that the glasses package 1 can be managed, and specifically, the marking code can be printed in a laser graphic printing mode.

The material receiving structure comprises a material receiving rail 710, and when the material placing groove 210 passes through the material receiving rail 710, the material receiving rail 710 receives the glasses packaging part 1 on the material placing groove 210. At first, the material receiving rail 710 is driven by the rotating frame through a bending guide structure to receive material, and is simple and convenient.

The light supply structure comprises a light supply pipe 333, the light supply probe 332 is arranged on the light supply pipe 333, the first light path is formed inside the light supply pipe 333, and the light supply pipe 333 and the light supply probe 332 are fixed through clamping. The light supply adjusting structure 400 is further included, the light supply adjusting structure 400 is provided with a plurality of light supply pipes 333, different light adjusting mirrors are arranged in the light supply pipes 333, so that first light paths in the light supply pipes 333 are different, the light supply adjusting structure 400 is provided with a mechanical hand grip 410, and the light supply pipes 333 are replaced from the upper sealing frame 310 through the mechanical hand grip 410. The triggering illumination threshold value is in direct proportion to the illumination intensity of the beam-converging light source. Firstly, the light supply structure is different in the configuration of the first light path because the prism of the light supply tube 333 is arranged differently through the light supply tube 333, and the light supply tube 333 can be detached and replaced through the mechanical hand grip 410, so that the detection effect is ensured.

The above are only typical examples of the present invention, and besides, the present invention may have other embodiments, and all the technical solutions formed by equivalent substitutions or equivalent changes are within the scope of the present invention as claimed.

Claims

1. A contact lens big data management screening assembly line comprises a base, a rotary material placing table, a feeding structure, an optometry structure, a marking structure and a material receiving structure;

2. The contact lens big data management screening pipeline of claim 1, wherein: the mark code is set as a two-dimensional graphic code, and the two-dimensional graphic code is scanned to obtain corresponding lens characteristic information.

3. The contact lens big data management screening pipeline of claim 1, wherein: the upper alignment structure further comprises a sealing layer, and when the light supply probe is matched with the upper alignment structure, the sealing layer is extruded to reduce the space in the packaging cavity so that the contact lens in the packaging cavity is horizontally placed under the impact of agent pressure.

4. The contact lens big data management screening pipeline of claim 2, wherein: and a sodium chloride solution is filled in the packaging cavity.

5. The contact lens big data management screening pipeline of claim 1, wherein: the light collecting device is characterized by further comprising a controller, wherein the controller is provided with a triggering strategy, the triggering strategy comprises that a triggering illumination sensor is arranged in the center of the light collecting plate, the triggering illumination sensor is used for detecting the illumination intensity of the position where the triggering illumination sensor is located, when the illumination intensity fed back by the triggering illumination sensor exceeds a triggering illumination threshold value, triggering information is output, and the controller receives the light collecting illumination information according to the triggering information.

6. The contact lens big data management screening pipeline of claim 5, wherein: the triggering illumination threshold value is in direct proportion to the illumination intensity of the beam-converging light source.

7. The contact lens big data management screening pipeline of claim 1, wherein: the light supply structure comprises a light supply pipe, the light supply probe is arranged on the light supply pipe, the first light path is formed in the light supply pipe, and the light supply pipe and the light supply probe are fixed through clamping.

8. The contact lens big data management screening pipeline of claim 7, wherein: the light supply adjusting structure is provided with a plurality of light supply tubes, different light adjusting mirrors are arranged in the light supply tubes to enable first light paths in the light supply tubes to be different, the light supply adjusting structure is provided with a mechanical hand grip, and the light supply tubes are replaced on the upper sealing light frame through the mechanical hand grip.