CN111517066B - Production line system - Google Patents

Abstract

The invention discloses a production line system, and relates to the technical field of production equipment. The system includes a material loading assembly line, and the material loading assembly line includes: the first conveying device comprises a first conveying belt, and the first conveying belt is used for conveying a sample to be detected; the first automatic adjusting mechanism is connected with the first conveying device and is used for adjusting the width of the first conveying belt; the controller is connected with the first automatic regulating mechanism, and the controller can control the first automatic regulating mechanism to regulate the width of the first conveying belt according to the size of the sample to be measured. When the automatic conveying device is used, the first conveying device and the controller are respectively connected with the first automatic adjusting mechanism, and the controller controls the first adjusting mechanism to adjust the width of the first conveying belt, so that the first conveying belt can adapt to the size of a sample to be detected so as to convey the sample to be detected, and further can convey the sample to be detected in different sizes, the automation degree of a production line system is improved, and continuous production is realized.

Description

Production line system

Technical Field

The invention belongs to the technical field of production equipment, and particularly relates to a production line system.

Background

In the production process of the notebook computer, the protective film carried by the notebook computer screen needs to be repeatedly torn off and pasted according to process requirements.

Aiming at the printing of the screen protective film, the conventional manual equipment can only realize the inching single-step control of the equipment and cannot realize the continuous production of the printing process of the protective film. For example, a screen without a protective film is manually fed into a feeding port of a printing device, the printing screen and the printing platform are manually aligned, and the printed notebook computer is manually taken out after the protective film is printed. Because the whole process is completed by manual operation of personnel, the labor cost is high, the production efficiency is low, and continuous generation cannot be realized.

Disclosure of Invention

The invention provides a production line system for realizing automatic continuous production.

The invention provides a production line system, which comprises a feeding assembly line, wherein the feeding assembly line comprises:

the first conveying device comprises a first conveying belt, and the first conveying belt is used for conveying a sample to be detected;

the first automatic adjusting mechanism is connected with the first conveying device and is used for adjusting the width of the first conveying belt;

the controller is connected with the first automatic adjusting mechanism, and the controller can control the first automatic adjusting mechanism to adjust the width of the first conveying belt according to the size of the sample to be detected.

Based on the above, when the production line system provided by the invention is used, the first conveying device and the controller of the feeding assembly line are respectively connected with the first automatic adjusting mechanism, and the controller controls the first adjusting mechanism to adjust the width of the first conveying belt in the first conveying device according to the size of the sample to be detected on the first conveying device, so that the first conveying belt can adapt to the size of the sample to be detected to convey the sample to be detected, and further, the samples to be detected with different sizes can be conveyed, the automation degree of the production line system is improved, and continuous production is realized.

Drawings

The drawings are included to provide a better understanding of the invention and are not to be construed as unduly limiting the invention. Wherein: in the drawings, the same or corresponding reference numerals indicate the same or corresponding parts.

FIG. 1 is a schematic view of a material loading line of a production line system according to the present invention;

FIG. 2 is a schematic view of a blanking line of the production line system according to the present invention;

FIG. 3 is a schematic structural view of a first adjustment mechanism;

fig. 4 is a schematic structural diagram of the primary aligner and the feeding platform.

10, a first conveying device, 101, a first conveying belt, 102, a second motor, 103, a limiting part, 104, a first conveying rail, 105, a second conveying rail, 106, a gap, 20, a first automatic regulating mechanism, 201, a third motor, 202, a coupler, 203, a screw rod, 204, a support, 30, a controller, 401, a jacking mechanism, 402, a positioner, 50, a testing jig, 601, a first motor, 602, an expansion rod, 603, a suction cup, 70, a feeding code reader, 80, a blanking platform, 90, a second conveying device, 100 and a second automatic regulating mechanism.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, an embodiment of the present invention provides a production line system including a loading line including: the device comprises a first conveying device 10, wherein the first conveying device 10 comprises a first conveying belt 101, and the first conveying belt 101 is used for conveying a sample to be detected; the first automatic adjusting mechanism 20 is connected with the first conveying device 10, and the first automatic adjusting mechanism 20 is used for adjusting the width of the first conveying belt 101; and the controller 30, the controller 30 is connected with the first automatic adjusting mechanism 20, and the controller 30 can control the first automatic adjusting mechanism 20 to adjust the width of the first conveying belt 101 according to the size of the sample to be measured.

Specifically, when the production line system of the embodiment of the invention is used, the first conveying device 10 and the controller 30 of the feeding line are respectively connected with the first automatic adjusting mechanism 20, and the controller 30 can control the first automatic adjusting mechanism 20 to adjust the width of the first conveying belt 101 in the first conveying device 10 according to the size of the sample to be measured on the first conveying device 10. From this, can be according to the width of the sample size quick adjustment that awaits measuring first conveyer belt 101 with the sample that awaits measuring of carrying unidimensional, because first conveyor 10 and controller 30 are connected with first automatic regulating mechanism 20 respectively, consequently improved the degree of automation of production line system control, realized serialization production, improved production efficiency.

In this embodiment, the loading line further comprises: just counterpoint ware and test fixture 50, first conveyer belt 101 has feed inlet and discharge gate, just the setting of counterpoint ware is between discharge gate and test fixture 50, test fixture 50 and just the counterpoint ware are connected with controller 30 respectively, test fixture 50 is used for placing the sample that awaits measuring and detects the sample that awaits measuring, just the counterpoint ware is used for fixing a position the positional information of the sample that awaits measuring of discharge gate department, controller 30 can be according to the position of just the counterpoint ware location result adjustment test fixture 50 so that the sample that awaits measuring can accurately place on test fixture 50.

Specifically, the test fixture 50 and the preliminary aligner are respectively connected to the controller 30, the preliminary aligner is disposed at the discharge port of the first conveyor belt 101, a sensor is mounted at the discharge port or on the preliminary aligner, and the controller 30 is connected to the sensor. When the first conveying belt 101 conveys a sample to be tested to the discharge opening, the sensor senses the sample to be tested and generates a sensing signal, the controller 30 receives the sensing signal of the sensor and then controls the primary aligner to position the position information of the sample to be tested at the discharge opening according to the sensing signal, and the position of the testing jig 50 can be adjusted according to the position information of the sample to be tested. Therefore, the sample to be tested can be positioned quickly and accurately, and the sample to be tested can be conveyed to the test fixture 50 accurately.

The test fixture 50 of the present embodiment may be a device for performing a performance test on a sample to be tested, or may be a device for re-processing a sample to be tested. The test fixture 50 is, for example, a printing apparatus.

In this embodiment, the preliminary alignment device includes climbing mechanism 401 and locator 402, and climbing mechanism 401 and locator 402 are connected with controller 30 respectively, and controller 30 can control climbing mechanism 401 and will await measuring the sample and the separation of the first conveyer belt 101 of discharge gate department and transport the sample that awaits measuring to appointed height department to make locator 402 can fix a position the position information of the sample that awaits measuring of appointed height department.

Specifically, the jacking mechanism 401 and the positioner 402 are respectively connected to the controller 30, and the controller 30 can control the jacking mechanism 401 to perform a conveying operation, at this time, the jacking mechanism 401 separates the sample to be detected on the first conveying belt 101 from the first conveying belt 101 and conveys the separated sample to be detected to a preset height above the first conveying belt 101. After receiving the instruction of the end of the conveying operation of the jacking mechanism 401, the controller 30 controls the positioner 402 to execute the positioning operation, and at this time, the positioner 402 positions the position information of the sample to be measured. From this, can realize fast the accurate positioning of the sample that awaits measuring of discharge gate department through climbing mechanism 401 and locator 402 mating reaction to automatic counterpoint has been realized, operation labour saving and time saving.

It should be noted that the initial aligner of this embodiment can also be of other structures, as long as can carry out accurate counterpoint to the sample that awaits measuring at discharge gate department, not list here. The present embodiment also does not limit the structures of the jacking mechanism 401 and the positioner 402.

For example, the positioner 402 may be an industrial camera or other positioning device; the jacking mechanism 401 may include a hydraulic cylinder, at least one hydraulic rod, and a tray; the first end and the hydraulic cylinder of hydraulic stem are connected, and the second end is connected with the tray, and hydraulic cylinder is connected with controller 30, and hydraulic cylinder can provide power for hydraulic stem, and the tray is used for supporting the sample that awaits measuring, and controller 30 can control hydraulic cylinder and drive hydraulic stem upward movement with the sample that awaits measuring on the first conveyer belt 101 and the first conveyer belt 101 phase separation and carry the sample that awaits measuring after the separation to the preset high department above first conveyer belt 101. When the jacking mechanism 401 has a plurality of hydraulic rods, each hydraulic rod is connected with a tray, and the plurality of trays can be uniformly distributed at the bottom of the sample to be tested so as to stably support the sample to be tested. Therefore, the reliability of the jacking mechanism 401 in conveying the sample to be tested is improved.

In this embodiment, the first conveyor belt 101 includes a first conveying track 104 and a second conveying track 105, the first conveying track 104 and the second conveying track 105 are spaced and arranged oppositely, a gap 106 is formed between the first conveying track 104 and the second conveying track 105, and the first conveying track 104 and the second conveying track 105 jointly convey a sample to be measured; the controller 30 can control the jacking mechanism 401 to move upwards through the gap 106 to separate the sample to be tested from the first conveyor belt 101 at the discharge port and transport the sample to be tested to a designated height.

Specifically, set up climbing mechanism 401 in first conveyer belt 101 below, when the sample that awaits measuring is carried to first conveyer belt 101, first conveying track 104 and second conveying track 105 support the sample that awaits measuring jointly, with the sample that awaits measuring is carried to the discharge gate, sensor sensing department generates sensing signal and sends sensing signal to controller 30 behind the sample that awaits measuring on first conveyer belt 101, controller 30 can control climbing mechanism 401 according to sensing signal and pass clearance 106 between first conveying track 104 and the second conveying track 105 in order to hold the sample that awaits measuring on the first conveyer belt 101, and then when climbing mechanism 401 rebound, climbing mechanism 401 separates the sample that awaits measuring and first conveyer belt 101 with the sample that awaits measuring of discharge gate department, and carry the sample that awaits measuring to predetermineeing high department. From this, can carry the sample that awaits measuring to predetermineeing high department from first conveyor 10 fast to realize carrying and the continuous operation of counterpoint, improved the degree of automation of production line.

It should be noted that the first conveyor belt 101 of the present embodiment may have other structures as long as it can convey a sample to be measured, and the other structures of the first conveyor belt 101 are not described here.

As shown in fig. 4, in this embodiment, the material loading assembly line further includes a material loading platform, the material loading platform is disposed between the initial alignment device and the test fixture 50 and connected to the controller 30, and the controller 30 can control the material loading platform to transport the sample to be tested at the designated height on the jacking mechanism 401 to the test fixture 50.

Specifically, the loading platform is connected to the controller 30. When the controller 30 receives the position information of the positioner 402, it controls the loading platform to execute the loading operation, and at this time, the loading platform conveys the sample to be tested on the jacking mechanism 401 to the testing fixture 50. Therefore, the sample to be tested can be rapidly conveyed to the test fixture 50 from the positioner 402, and the automatic loading operation is realized.

In this embodiment, the feeding platform includes first motor 601, telescopic link 602 and sucking disc 603, first motor 601 is connected with controller 30, the first end and the first motor 601 of telescopic link 602 are connected, the second end is connected with sucking disc 603, sucking disc 603 is used for adsorbing the sample that awaits measuring of appointed height department on climbing mechanism 401, so that the sample that awaits measuring separates with climbing mechanism 401, controller 30 can control first motor 601 and drive telescopic link 602 and remove so that sucking disc 603 can adsorb and be located climbing mechanism 401 on the sample that awaits measuring carry the sample that awaits measuring to test fixture 50 from climbing mechanism 401 appointed height department after.

Specifically, the first motor 601 and the test fixture 50 are respectively connected to the controller 30, and the controller 30 can control the first motor 601 to drive the telescopic rod 602 to move, so that the suction cup 603 on the telescopic rod 602 can adsorb the sample to be tested on the jacking mechanism 401 and transport the sample to be tested to the test fixture 50. Because the testing jig 50 is provided with the sensor, the sensor on the testing jig 50 generates a sensing signal and sends the sensing signal to the controller 30 after sensing the sample to be tested, and the controller 30 controls the testing jig 50 to test the sample to be tested according to the sensing signal. For example, the sample to be tested is a product screen, the testing fixture 50 is a printing apparatus, and when a protective film is printed on the product screen, the controller 30 controls the telescopic rod 602 to move so that the suction cup 603 on the telescopic rod 602 can suck the lower surface of the screen from the lower side of the product screen, and transport the screen to the printing apparatus. Therefore, the upper surface of the screen can be effectively protected from being polluted, and printing on the upper surface of the screen by the printing equipment is facilitated.

In this embodiment, the first conveying device 10 further includes a second motor 102, and the first conveying belt 101 is connected to the controller 30 and the second motor 102 respectively; the two end parts of the first conveyer belt 101 are respectively provided with a limiting piece 103, and the limiting pieces 103 are used for limiting the sample to be detected to be separated from the first conveyer belt 101 along the conveying direction of the first conveyer belt 101; the controller 30 can control the second motor 102 to drive the first conveyor belt 101 to convey the sample to be measured.

Specifically, the second motor 102 is connected to the first conveyor belt 101, the second motor 102 is connected to the controller 30, and the controller 30 can control the second motor 102 to drive the first conveyor belt 101 to convey the sample to be measured. Therefore, the conveying speed of the first conveying belt 101 can be conveniently and quickly adjusted, and therefore automatic adjustment of conveying of the first conveying belt 101 is achieved. When the sample to be detected is conveyed to the two ends of the first conveying belt 101, the two ends of the first conveying belt 101 are both provided with the limiting parts 103, so that the sample to be detected can be prevented from being separated from the first conveying belt 101 along the direction of the first conveying belt 101 in the conveying process. This improves the stability of the first conveyor belt 101.

In this embodiment, the material loading assembly line includes the feeding code reader 70, the feeding code reader 70 is disposed at the feeding port and connected to the controller 30, and the controller 30 can control the feeding code reader 70 to read the information of the sample to be tested on the first conveyor belt 101, and verify the sample to be tested according to the information read by the feeding code reader 70.

Specifically, be provided with sensor and feeding code reader 70 in feed inlet department, and be connected sensor and feeding code reader 70 with controller 30 respectively, when the sensor sensing to the signal of the sample that awaits measuring of feed inlet department, send sensing signal to controller 30, controller 30 can read the information of the sample that awaits measuring according to the sensing signal control feeding code reader 70 of sensor, and can check up the sample that awaits measuring on first conveyer belt 101 according to the information that the reading of feeding code reader 70, if the check-up passes, then controller 30 control first motor 601 drives first conveyer belt 101 and carries the sample that awaits measuring, if the check-up does not pass, the sample that awaits measuring that explains that the feed inlet department placed is not conform to the requirement, and do not carry out the transport operation of the sample that awaits measuring. From this, through set up feeding code reader 70 at the feed inlet, can ensure that the sample that awaits measuring that first conveyer belt 101 carried is unanimous with the sample that awaits measuring that the system set up, improved production line system operation automation, labour saving and time saving.

The positional relationship between the feed code reader 70 and the first transport device 10 is not limited as long as information on a sample to be measured can be read.

For example, the feeding code reader 70 is disposed below the first conveyor belt 101 and in the gap 106 formed by the first conveying track 104 and the second conveying track 105, and the feeding code reader 70 can scan the two-dimensional code on the sample to be measured through the gap 106, so as to obtain the information of the sample to be measured.

As shown in fig. 2, in this embodiment, a production line system further includes a blanking line; the blanking assembly line comprises a blanking platform 80, a second conveying device 90 and a second automatic adjusting mechanism 100, the blanking platform 80 is arranged between the test fixture 50 and the second conveying device 90, the second automatic adjusting mechanism 100 is connected with the second conveying device 90, the blanking platform 80, the second conveying device 90 and the second automatic adjusting mechanism 100 are respectively connected with the controller 30, the second conveying device 90 comprises a second conveying belt, and the second conveying belt is used for conveying a tested sample; the controller 30 can control the blanking platform 80 to transport the tested sample on the testing fixture 50 to the second conveyor belt and can control the second automatic adjusting mechanism 100 to adjust the width of the second conveyor belt according to the size of the tested sample on the second conveyor belt.

Specifically, a sensor is provided on the second conveyor 90, and the controller 30 is connected to the blanking platform 80, the second conveyor 90, and the second adjustment mechanism. The controller 30 receives the instruction of the test fixture 50 that the test operation is finished, controls the blanking platform 80 to convey the tested sample to the second conveying device 90, the sensor at the feed inlet of the second conveying device 90 senses the tested sample and then generates a sensing signal and sends the sensing signal to the controller 30, and the controller 30 controls the second adjusting structure to adjust the width of the second conveying belt according to the sensing signal. Therefore, the tested sample can be quickly and accurately conveyed from the test fixture 50 to the second conveying device 90, and continuous production is realized.

As shown in fig. 3, in the present embodiment, the specific structures of the first automatic adjustment mechanism 20 and the second automatic adjustment mechanism 100 are not limited as long as the width of the first conveyor belt 101 and the width of the second conveyor belt can be adjusted. The first automatic adjustment mechanism 20 and the second automatic adjustment mechanism 100 may have the same or different structures. For example, the first automatic adjustment mechanism includes two adjustment units installed to be connected with the first conveying rail and the second conveying rail, respectively. Each adjusting unit comprises a third motor 201, a coupler 202, a lead screw 203 and a bracket 204. The screw 203 is connected with the third motor 201 through the coupler 202, the first conveying track 104 is connected to the screw 203 through a bracket, and the third motor 201 drives the screw 203 to rotate through the coupler 202, so that the screw 203 drives the first conveying track 104 to move axially along the screw 203, and further the width between the first conveying track 104 and the second conveying track 104 is adjusted.

The second conveyor 90 and the first conveyor 10 may have the same or different structures, as long as the technical problems of the present invention can be solved. The blanking platform 80 and the loading platform may be identical or different in structure.

According to the production line system provided by the embodiment of the invention, by arranging the automatic feeding assembly line and the automatic discharging assembly line, different products can be tested and processed, accurate alignment of the products is realized, and the feeding and discharging are quickly and automatically switched, so that the yield of the products is improved, the automation degree of production is improved, the continuous production is realized, the production efficiency is improved, the process flow is simplified, and the cost is saved.

Exemplary embodiments of the present invention are described below with reference to the accompanying drawings, in which various details of embodiments of the invention are included to assist understanding, and which are to be considered as merely exemplary. Accordingly, those of ordinary skill in the art will recognize that various changes and modifications of the embodiments described herein can be made without departing from the scope and spirit of the invention. Also, descriptions of well-known functions and constructions are omitted in the following description for clarity and conciseness.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The above description is only an exemplary embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of changes or substitutions within the technical scope of the present invention, and the present invention shall be covered thereby. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (9)

1. A production line system, comprising a feed line, the feed line comprising:

the first conveying device comprises a first conveying belt, and the first conveying belt is used for conveying a sample to be detected;

the first automatic adjusting mechanism is connected with the first conveying device and is used for adjusting the width of the first conveying belt;

the controller is connected with the first automatic adjusting mechanism and can control the first automatic adjusting mechanism to adjust the width of the first conveying belt according to the size of the sample to be detected;

the material loading assembly line further comprises: a primary aligner; first conveyer belt has feed inlet and discharge gate, just counterpoint the ware includes climbing mechanism and locator, climbing mechanism with the locator respectively with the controller is connected, the controller can control climbing mechanism will await measuring the sample with the separation of the first conveyer belt of discharge gate department and transportation await measuring sample to appointed height department, so that the locator can fix a position appointed height department the positional information of the sample that awaits measuring.

2. The system of claim 1, wherein the feed line further comprises: the testing jig is arranged between the discharge port and the testing jig, the testing jig and the initial aligner are respectively connected with the controller, the testing jig is used for placing the sample to be tested and detecting the sample to be tested, the initial aligner is used for positioning the position information of the sample to be tested at the discharge port, and the controller can adjust the position of the testing jig according to the positioning result of the initial aligner so that the sample to be tested can be accurately placed on the testing jig.

3. The system of claim 2, wherein the first conveyor belt comprises a first conveyor track and a second conveyor track, the first conveyor track and the second conveyor track are spaced and arranged oppositely, a gap is formed between the first conveyor track and the second conveyor track, and the first conveyor track and the second conveyor track jointly convey the sample to be tested; the controller can control the jacking mechanism to penetrate through the gap to move upwards so as to separate the sample to be detected from the first conveying belt at the discharge port and convey the sample to be detected to a specified height.

4. The system of claim 2, wherein the loading assembly line further comprises a loading platform, the loading platform is disposed between the initial aligner and the test fixture and connected to the controller, and the controller is capable of controlling the loading platform to convey the sample to be tested at a specified height on the jacking mechanism to the test fixture.

5. The system according to claim 4, wherein the feeding platform comprises a first motor, a telescopic rod and a suction cup, the first motor is connected with the controller, a first end of the telescopic rod is connected with the first motor, a second end of the telescopic rod is connected with the suction cup, the suction cup is used for adsorbing the sample to be tested at the specified height on the jacking mechanism, so that the sample to be tested is separated from the jacking mechanism, and the controller can control the first motor to drive the telescopic rod to move, so that the suction cup can convey the sample to be tested from the specified height of the jacking mechanism to the test fixture after adsorbing the sample to be tested.

6. The system of claim 1, wherein the first conveyor further comprises a second motor, the first conveyor belt being connected to the controller, respectively the second motor; the two end parts of the first conveying belt are respectively provided with a limiting piece, and the limiting pieces are used for limiting the sample to be detected to be separated from the first conveying belt along the conveying direction of the first conveying belt; the controller can control the second motor to drive the first conveying belt to convey the sample to be detected.

7. The system of claim 1, wherein the feeding assembly line further comprises a feeding code reader, the feeding code reader is disposed at the feeding port and connected to the controller, and the controller is capable of controlling the feeding code reader to read information of the sample to be tested on the first conveyor belt and verify the sample to be tested according to the information read by the feeding code reader.

8. The system of claim 2, further comprising a blanking line; the blanking assembly line comprises a blanking platform, a second conveying device and a second automatic adjusting mechanism, the blanking platform is arranged between the test fixture and the second conveying device, the second automatic adjusting mechanism is connected with the second conveying device, the blanking platform, the second conveying device and the second automatic adjusting mechanism are respectively connected with the controller, the second conveying device comprises a second conveying belt, and the second conveying belt is used for conveying a tested sample; the controller can control the blanking platform to convey the tested sample on the test fixture to the second conveying belt and can control the second automatic adjusting mechanism to adjust the width of the second conveying belt according to the size of the tested sample on the second conveying belt.

9. The system of claim 8, wherein the first and second automatic adjustment mechanisms are identical in structure; the first automatic adjusting mechanism comprises two adjusting units, and each adjusting unit comprises a third motor, a coupler, a lead screw and a bracket; the lead screw passes through the shaft coupling with the third motor is connected, first delivery track passes through the leg joint is in on the lead screw, the third motor can drive the lead screw through the shaft coupling and rotate, so that the lead screw drives first delivery track and follows lead screw axial displacement.

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