CN219572977U - Full-automatic flatness testing machine - Google Patents

Abstract

The utility model relates to the technical field of flatness testing of mobile phone shells, in particular to a full-automatic flatness testing machine which comprises a machine table, wherein a guide mechanism for guiding and positioning a mobile phone shell to be tested, a feeding mechanism for feeding the mobile phone shell to be tested, a testing jig mechanism for placing the mobile phone shell to be tested, a testing mechanism for detecting the flatness of the mobile phone shell, a discharging mechanism for discharging the mobile phone shell to be tested and a control system for controlling the operation of the testing machine are arranged on the machine table. The utility model adopts the structure arrangement, replaces manual operation by full-automatic mechanical operation, and has low labor and high working efficiency.

Description

Full-automatic flatness testing machine

Technical Field

The utility model relates to the technical field of flatness testing of mobile phone shells, in particular to a full-automatic flatness testing machine.

Background

At present, in the manufacturing industry of mobile phone shells, flatness testing of the mobile phone shells is completed by manual operation, flatness of the outer frames of the mobile phone shells is tested by using a plug gauge through a flatness jig, flatness of hardware in the middle of the mobile phone shells is tested by using a manual hardware flatness testing instrument, and the flatness testing device is high in labor and low in working efficiency.

In view of the above, there is a need for improvements in the art.

Disclosure of Invention

Aiming at the problems, the utility model provides a full-automatic flatness testing machine, which effectively solves the defects and shortcomings of the prior art.

In order to achieve the above purpose, the technical scheme of the utility model is as follows:

the utility model provides a full-automatic flatness testing machine, includes the board, is equipped with on the board and is used for waiting to examine the guide mechanism of cell-phone shell direction location, is used for waiting to examine the feed mechanism of cell-phone shell material loading, is used for waiting to examine the test fixture mechanism that the cell-phone shell was placed, is used for detecting the test mechanism of cell-phone shell flatness, is used for the unloading mechanism of cell-phone shell unloading and is used for controlling the control system of test machine work.

According to the scheme, the material guide mechanism is located above the assembly line and comprises a material guide rod and a material feeding sensor, and the material feeding sensor is in signal connection with the control system.

According to the above scheme, feed mechanism includes first slide rail, first elevator motor, first sucking disc and first driving motor, and first elevator motor slides and locates on the first slide rail, and first sucking disc locates first elevator motor's output, and first driving motor drives first elevator motor and reciprocates on first slide rail.

According to the above scheme, test fixture mechanism includes second slide rail, test station, clamp material mechanism and second driving motor, and the test station slides and locates on the second slide rail, and clamp material mechanism locates on the test station, and second driving motor drive test station round trip movement on the second slide rail.

According to the above scheme, the testing mechanism comprises a third sliding rail, a third driving motor and a testing camera, wherein the testing camera is slidably arranged on the third sliding rail, and the third driving motor drives the testing camera to move back and forth on the third sliding rail.

According to the above scheme, unloading mechanism includes fourth driving motor, fourth slide rail, second lift motor, rotating electrical machines and second sucking disc, and second lift motor slides and locates on the fourth slide rail, and the rotating electrical machines is connected in the output of second lift motor, and the second sucking disc is connected in the output of rotating electrical machines, and fourth driving motor drive second lift motor reciprocates on the fourth slide rail.

According to the scheme, the machine is provided with the hood at the upper part, and the roller and the supporting legs are arranged at the bottom of the machine.

The utility model has the beneficial effects that:

the utility model adopts the structure arrangement, replaces manual operation by full-automatic mechanical operation, and has low labor and high working efficiency.

Drawings

FIG. 1 is an exterior view of the overall structure of the present utility model;

FIG. 2 is a left side interior view of the overall structure of the present utility model;

fig. 3 is a right side interior view of the overall structure of the present utility model.

In the figure: 1. a machine table; 2. a hood; 3. a control system; 4. a roller; 5. supporting feet; 6. a material guiding mechanism; 7. a first slide rail; 8. a first lifting motor; 9. a first suction cup; 10. a first driving motor; 11. a second slide rail; 12. a testing station; 13. a clamping mechanism; 14. a second driving motor; 15. a third slide rail; 16. a third driving motor; 17. testing a camera; 18. a fourth driving motor; 20. a fourth slide rail; 21. a second lifting motor; 22. a rotating electric machine; 23. and a second suction cup.

Detailed Description

The technical scheme of the utility model is described below with reference to the accompanying drawings and examples.

As shown in fig. 1 to 3, the full-automatic flatness testing machine provided by the utility model comprises a machine table 1, wherein a guide mechanism 6 for guiding and positioning a mobile phone shell to be tested, a feeding mechanism for feeding the mobile phone shell to be tested, a testing jig mechanism for placing the mobile phone shell to be tested, a testing mechanism for detecting the flatness of the mobile phone shell, a discharging mechanism for discharging the detected mobile phone shell and a control system 3 for controlling the work of the testing machine are arranged on the machine table 1. The above constitutes the basic structure of the present utility model.

The utility model adopts the structure arrangement, replaces manual operation by full-automatic mechanical operation, and has low labor and high working efficiency.

In this embodiment, the material guiding mechanism 6 is located above the assembly line, and the material guiding mechanism 6 includes a material guiding rod and a material feeding sensor, where the material feeding sensor is in signal connection with the control system 3. By adopting the structure, when feeding, the feeding of the mobile phone shell on the assembly line is guided by the feeding rod, and after the guiding is completed, the feeding is fed back to the control system 3 by the feeding inductor.

In this embodiment, the feeding mechanism includes a first slide rail 7, a first lifting motor 8, a first suction cup 9 and a first driving motor 10, where the first lifting motor 8 is slidably disposed on the first slide rail 7, the first suction cup 9 is disposed at an output end of the first lifting motor 8, and the first driving motor 10 drives the first lifting motor 8 to reciprocate on the first slide rail 7. By adopting the structure, during feeding, the first driving motor 10 drives the first lifting motor 8 to move to the guiding material taking area on the first sliding rail 7, the mobile phone shell is adsorbed and fixed through the first sucker 9, and the first driving motor 10 drives the first lifting motor 8, the first sucker 9 and the mobile phone shell to move to the test fixture mechanism for discharging.

It should be noted that, the material guiding mechanism 6 is installed at one side of the first sliding rail 7 extending out of the machine table 1, and is located above the assembly line.

In this embodiment, the test fixture mechanism includes a second slide rail 11, a test station 12, a clamping mechanism 13, and a second driving motor 14, where the test station 12 is slidably disposed on the second slide rail 11, the clamping mechanism 13 is disposed on the test station 12, and the second driving motor 14 drives the test station 12 to reciprocate on the second slide rail 11. By adopting the structure, after the feeding mechanism discharges materials to the test station 12, the mobile phone shell is clamped and fixed through the clamping mechanism 13, the second driving motor 14 drives the test station 12 to move to the test area on the second sliding rail 11 for testing, and after the testing is completed, the second driving motor 14 drives the test station 12 to continue to move to the discharging area on the second sliding rail 11.

It should be noted that, the test fixture mechanism has two sets of, set up side by side, can improve work efficiency, first product material loading to first test fixture mechanism on earlier during the material loading, can return material loading second product to another test fixture mechanism on, can remove to test the position and test after first test fixture mechanism receives the material, can remove to test the position and test after second test fixture mechanism receives the material, also test according to the material order earlier during the test, also carry out the unloading according to the order during the unloading, that is to say, follow material loading, test and unloading all can not influence each other.

In this embodiment, the test mechanism includes a third slide rail 15, a third driving motor 16, and a test camera 17, where the test camera 17 is slidably disposed on the third slide rail 15, and the third driving motor 16 drives the test camera 17 to reciprocate on the third slide rail 15. By adopting the structure, during testing, the third driving motor 16 drives the test camera 17 to move to the test position on the third sliding rail 15, the test camera 17 scans and tests the mobile phone shell on the test station 12 and feeds back the scanning value to the control system 3, and the control system 3 judges whether the split board is good or not.

The control system 3 is pre-stored with the number of good products as a reference, and the number exceeding the number of good products is the defective product of NG.

In this embodiment, the discharging mechanism includes a fourth driving motor 18, a fourth sliding rail 20, a second lifting motor 21, a rotating motor 22 and a second suction cup 23, where the second lifting motor 21 is slidably disposed on the fourth sliding rail 20, the rotating motor 22 is connected to the output end of the second lifting motor 21, the second suction cup 23 is connected to the output end of the rotating motor 22, and the fourth driving motor 18 drives the second lifting motor 21 to reciprocate on the fourth sliding rail 20. By adopting the structure, when in blanking, the fourth driving motor 18 drives the second lifting motor 21 to move to a blanking area on the fourth sliding rail 20, the second lifting motor 21 drives the second sucker 23 to adsorb and fix the mobile phone shell and move to a production line for blanking, wherein OK good products are directly blanked, NG products can be blanked by rotating the rotating motor 22 by a certain angle, and next process personnel can distinguish whether good products or defective products through angle change of the mobile phone shell on the production line.

In this embodiment, a hood 2 is disposed at the upper portion of the machine 1, and rollers 4 and supporting legs 5 are disposed at the bottom of the machine 1. By adopting the structure, the whole machine can be conveniently moved through the roller 4, and the whole machine can be conveniently positioned through the supporting legs 5.

It should be noted that, the supporting leg 5 can adjust the lifting and the horizontal position of the whole machine.

The working principle of the utility model is as follows:

the mobile phone shell flows in from the upper working procedure through a production line, is guided and positioned under the action of a guide rod, and is fed back to the control system 3 through a feed inductor; after receiving the incoming material signal, the control system 3 sends a working instruction to the feeding mechanism, the first driving motor 10 drives the first lifting motor 8 to move on the first sliding rail 7 to a material taking position, the first lifting motor 8 drives the first sucker 9 to descend to adsorb and lift the mobile phone shell to an initial starting point, and the first driving motor 10 drives the first lifting motor 8 to move on the first sliding rail 7 and place the mobile phone shell on the testing station 12; the clamping mechanism 13 clamps and fixes the mobile phone shell, the second driving motor 14 drives the testing station 12 to drive the mobile phone shell to move to the testing position on the second sliding rail 11, and a signal to be tested is fed back to the control system 3; after receiving the incoming material signal, the control system 3 sends a working instruction to the testing mechanism, the third driving motor 16 drives the testing camera 17 to move above the mobile phone shell on the third sliding rail 15, the mobile phone shell is subjected to planeness scanning test, the scanned numerical value is fed back to the control system 3 and displayed on the display panel, wherein the NG product is marked by red, after detection, the second driving motor 14 drives the testing station 12 to drive the mobile phone shell to move to a discharging position on the second sliding rail 11, the fourth driving motor 18 drives the second lifting motor 21 to move to the discharging position on the fourth sliding rail 20, the second lifting motor 21 drives the rotating motor 22 and the second sucker 23 to descend to adsorb and ascend the mobile phone shell to an initial starting point, and the fourth driving motor 18 drives the second lifting motor 21 to move to the discharging position on the fourth sliding rail 20 to finish discharging.

It should be noted that, the good products of OK are directly fed onto the production line, and the defective products of NG are two kinds, one is the product of the middle hardware flatness NG of the mobile phone shell, after the rotating motor 22 rotates 90 degrees, the product is fed onto the production line, the other is the product of the outer frame flatness NG of the mobile phone shell, after the rotating motor 22 rotates 45 degrees, the product is fed onto the production line, and the staff in the next procedure distinguishes the good products of OK or the product of the middle hardware flatness NG of the mobile phone shell or the product of the outer frame flatness NG of the mobile phone shell according to the angle position where the product is placed.

The embodiments of the present utility model have been described above with reference to the accompanying drawings, but the present utility model is not limited to the above-described embodiments, which are merely illustrative, not restrictive, and many forms may be made by those having ordinary skill in the art without departing from the spirit of the present utility model and the scope of the claims, which are all within the scope of the present utility model.

Claims (7)

1. The utility model provides a full-automatic flatness testing machine, includes board (1), its characterized in that: the mobile phone shell detection device is characterized in that a guide mechanism (6) for guiding and positioning the mobile phone shell to be detected, a feeding mechanism for feeding the mobile phone shell to be detected, a test jig mechanism for placing the mobile phone shell to be detected, a test mechanism for detecting the flatness of the mobile phone shell, a discharging mechanism for discharging the mobile phone shell to be detected and a control system (3) for controlling the operation of the test machine are arranged on the machine table (1).

2. The fully automatic flatness testing machine of claim 1, wherein: the material guide mechanism (6) is located above the assembly line, and the material guide mechanism (6) comprises a material guide rod and a material feeding sensor which is connected with the control system (3) in a signal mode.

3. The fully automatic flatness testing machine of claim 1, wherein: the feeding mechanism comprises a first sliding rail (7), a first lifting motor (8), a first sucker (9) and a first driving motor (10), wherein the first lifting motor (8) is arranged on the first sliding rail (7) in a sliding mode, the first sucker (9) is arranged at the output end of the first lifting motor (8), and the first driving motor (10) drives the first lifting motor (8) to move back and forth on the first sliding rail (7).

4. The fully automatic flatness testing machine of claim 1, wherein: the test jig mechanism comprises a second slide rail (11), a test station (12), a clamping mechanism (13) and a second driving motor (14), wherein the test station (12) is arranged on the second slide rail (11) in a sliding mode, the clamping mechanism (13) is arranged on the test station (12), and the second driving motor (14) drives the test station (12) to move back and forth on the second slide rail (11).

5. The fully automatic flatness testing machine of claim 1, wherein: the testing mechanism comprises a third sliding rail (15), a third driving motor (16) and a testing camera (17), wherein the testing camera (17) is slidably arranged on the third sliding rail (15), and the third driving motor (16) drives the testing camera (17) to reciprocate on the third sliding rail (15).

6. The fully automatic flatness testing machine of claim 1, wherein: the blanking mechanism comprises a fourth driving motor (18), a fourth sliding rail (20), a second lifting motor (21), a rotating motor (22) and a second sucker (23), wherein the second lifting motor (21) is arranged on the fourth sliding rail (20) in a sliding mode, the rotating motor (22) is connected to the output end of the second lifting motor (21), the second sucker (23) is connected to the output end of the rotating motor (22), and the fourth driving motor (18) drives the second lifting motor (21) to reciprocate on the fourth sliding rail (20).

7. The fully automatic flatness testing machine of claim 1, wherein: the machine is characterized in that a hood (2) is arranged on the upper portion of the machine table (1), and rollers (4) and supporting legs (5) are arranged at the bottom of the machine table (1).