CN109116180B - Self-recovery fuse sweep a yard detection mechanism and sweep a yard check out test set thereof - Google Patents

Abstract

The invention discloses a code scanning detection mechanism of a self-recovery fuse and code scanning detection equipment thereof. The invention relates to a code scanning detection mechanism of a self-recovery fuse and code scanning detection equipment thereof, which can scan a code of the self-recovery fuse and determine whether the self-recovery fuse is installed at a correct position, thereby avoiding the self-recovery fuse from being inserted at a wrong position on a circuit board, ensuring that the self-recovery fuse on the circuit board can be accurately inserted, reducing the rejection rate of the circuit board, improving the quality of the circuit board and the productivity of the circuit board, further improving the stability of a circuit on the circuit board, and further improving the production efficiency of the circuit board with the self-recovery fuse.

Description

Self-recovery fuse sweep a yard detection mechanism and sweep a yard check out test set thereof

Technical Field

The invention relates to the field of automation equipment, in particular to a code scanning detection mechanism of a self-recovery fuse and code scanning detection equipment thereof.

Background

The self-healing fuse is composed of a specially treated polymeric resin and conductive particles distributed therein. Under normal operation, the polymer resin tightly binds the conductive particles outside the crystalline structure to form a chain-shaped conductive electric path, the self-recovery fuse is in a low-resistance state at the moment, and the heat energy generated by the current flowing through the self-recovery fuse on the circuit is small, so that the crystal structure cannot be changed. When the circuit is short-circuited or overloaded, the polymer resin is melted by the heat generated by the large current flowing through the self-recovery fuse, the volume is rapidly increased to form a high-resistance state, and the working current is rapidly reduced, so that the circuit is limited and protected. After the fault is eliminated, the self-recovery fuse is cooled and crystallized again, the volume shrinks, the conductive particles form a conductive path again, and the self-recovery fuse is recovered to be in a low-resistance state, so that the circuit is protected without manual replacement.

However, in the process of installing the self-healing fuse on the circuit board, the self-healing fuse is manually plugged on the circuit board, but in the plugging process, a position of the self-healing fuse may be incorrectly plugged, if the position of the self-healing fuse is incorrectly plugged on the circuit board, the self-healing fuse cannot be electrically connected with a circuit on the circuit board or a connection error occurs, so that the circuit cannot be protected, and if the position of the self-healing fuse is incorrectly plugged on the circuit board, the circuit board may be scrapped, and the stability of the circuit board and the production efficiency of the circuit board are reduced.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides a code scanning detection mechanism of a self-recovery fuse and code scanning detection equipment thereof, which can scan the code of the self-recovery fuse and determine whether the self-recovery fuse is installed at the correct position, so that the self-recovery fuse is prevented from being inserted at the wrong position on a circuit board, the self-recovery fuse on the circuit board can be ensured to be accurately inserted, the rejection probability of the circuit board is reduced, the quality of the circuit board and the capacity of the circuit board are improved, the stability of the circuit on the circuit board is improved, and the production efficiency of the circuit board with the self-recovery fuse is further improved.

The purpose of the invention is realized by the following technical scheme:

a sweep code detection mechanism for a self-healing fuse, comprising: the automatic recovery fuse code scanning device comprises a self-recovery fuse code scanning device, a loading conveying device, a positioning device and a code scanning support, wherein the code scanning support is arranged on the base, and the self-recovery fuse code scanning device, the loading conveying device and the positioning device are respectively arranged on the code scanning support;

the feeding and conveying device comprises a first guide rail assembly, a second guide rail assembly and a conveying support, the first guide rail assembly and the second guide rail assembly are respectively arranged on the conveying support, and the conveying support is arranged on the code scanning support;

the self-recovery fuse code scanning device comprises a first code scanning assembly, a second code scanning assembly and a code scanning lifting assembly, wherein the first code scanning assembly, the second code scanning assembly and the code scanning lifting assembly are respectively arranged on the code scanning support, the first code scanning assembly comprises a first inductor, a first camera and a first mounting frame, the first inductor is arranged on the first guide rail assembly, the first camera is arranged on the first mounting frame, the second code scanning assembly comprises a second inductor, a second camera and a second mounting frame, the second inductor is arranged on the first guide rail assembly, and the second camera is arranged on the second mounting frame;

the positioning device comprises a first positioning assembly and a second positioning assembly, the first positioning assembly and the second positioning assembly are respectively arranged on the code scanning support, the first positioning assembly comprises a first driving part, a first pushing plate and a positioning plate, the first driving part is arranged on the code scanning support, the first pushing plate is arranged at the driving end of the first driving part, and the positioning plate is arranged on the first pushing plate; the second positioning assembly comprises a second driving part, a second pushing plate and a plurality of positioning columns, the second driving part is arranged on the code scanning support, the second pushing plate is arranged on the second driving part, and the plurality of positioning columns are respectively arranged on the second pushing plate.

As a further preferred scheme, the first guide rail assembly comprises a first guide rail mounting plate and a first guide rail, the first guide rail mounting plate is arranged on the conveying support, and the first guide rail is arranged on the first guide rail mounting plate.

As a further preferred scheme, the second guide rail assembly comprises a second guide rail mounting plate and a second guide rail, the second guide rail mounting plate is arranged on the conveying support, and the second guide rail is arranged on the second guide rail mounting plate.

As a further preferred scheme, sweep a yard lifting unit and include lift mounting panel, lifter and lift driver, first mounting bracket with the second mounting bracket set up respectively in on the lift mounting panel, the first end of lifter set up in on the lift mounting panel, the second end of lifter set up in on the lift driver, the lift driver set up in on the base, the lift driver is used for the drive the lifter rises or descends.

As a further preferred scheme, first scanning code assembly still includes first regulating plate, first regulating plate set up in on the lift mounting panel, first mounting bracket set up in on the first regulating plate.

As a further preferred scheme, the second code scanning assembly further comprises a second adjusting plate, the second adjusting plate is arranged on the lifting mounting plate, and the second mounting frame is arranged on the second adjusting plate.

As a further preferred scheme, the locating plate includes fixed plate body and stopper, the fixed plate body set up in on the first slurcam, the stopper set up in on the fixed plate body.

As a further preferred scheme, the limiting block has a trapezoidal cross section.

As a further preferred scheme, the number of the positioning columns is four, and the four positioning columns are respectively arranged on the second pushing plate.

A code scanning detection device for a self-healing fuse, comprising: the code scanning detection mechanism of the self-recovery fuse is described above.

Compared with the prior art, the invention has the following advantages and beneficial effects:

the invention relates to a code scanning detection mechanism of a self-recovery fuse and code scanning detection equipment thereof, which can scan a code of the self-recovery fuse and determine whether the self-recovery fuse is installed at a correct position, thereby avoiding the self-recovery fuse from being inserted at a wrong position on a circuit board, ensuring that the self-recovery fuse on the circuit board can be accurately inserted, reducing the rejection rate of the circuit board, improving the quality of the circuit board and the productivity of the circuit board, further improving the stability of a circuit on the circuit board, and further improving the production efficiency of the circuit board with the self-recovery fuse.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic structural diagram of a code scanning detection apparatus for a self-healing fuse according to an embodiment of the present invention;

FIG. 2 is a schematic view of another angle of the code scanning detection device of the self-restoring fuse shown in FIG. 1;

FIG. 3 is a schematic view of the code scanning detection mechanism shown in FIG. 1;

FIG. 4 is a schematic structural view of the positioning device shown in FIG. 3;

FIG. 5 is a schematic structural diagram of the circuit detection mechanism shown in FIG. 1;

FIG. 6 is a schematic structural diagram of the detecting and positioning device shown in FIG. 5;

FIG. 7 is a schematic structural view of the test plug assembly and vertical drive assembly shown in FIG. 6;

FIG. 8 is a schematic view of the circuit detecting mechanism shown in FIG. 6;

FIG. 9 is a schematic structural diagram of the zero power resistance test mechanism shown in FIG. 1;

fig. 10 is a schematic structural diagram of another angle of the zero power resistance test mechanism shown in fig. 1.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

In the process of installing the self-recovery fuse on the circuit board, the self-recovery fuse is manually inserted on the circuit board, but the position of the self-recovery fuse is possibly inserted in a wrong way in the inserting process, if the position of the self-recovery fuse is inserted in a wrong way on the circuit board, the self-recovery fuse cannot be electrically connected with a circuit on the circuit board or the situation of connection error occurs, so that the protection effect on the circuit cannot be realized, and if the position of the self-recovery fuse is inserted in a wrong way on the circuit board, the circuit board can be scrapped, and the stability of the circuit board and the production efficiency of the circuit board are reduced.

For example, referring to fig. 1 and 2, a code scanning detection device 10 for a resettable fuse includes: the code scanning detection device comprises a code scanning detection mechanism 1, a circuit detection mechanism 2, a zero-power resistance testing mechanism 3 and a base 4, wherein the code scanning detection mechanism 1, the circuit detection mechanism 2 and the zero-power resistance testing mechanism 3 are respectively arranged on the base 4; it should be noted that the code scanning detection mechanism 1 is used for scanning the self-healing fuse and determining whether the self-healing fuse is correctly inserted; the circuit detection mechanism 2 is used for detecting whether the circuit board inserted with the self-recovery fuse can be normally used; the zero-power resistance testing mechanism 3 is used for judging whether the resistance of the self-recovery fuse is in a normal range or not; the base 4 is used for installing a code scanning detection mechanism 1, a circuit detection mechanism 2 and a zero-power resistance testing mechanism 3.

Referring to fig. 3, the code scanning detection mechanism 1 includes a self-recovery fuse code scanning device 100, a feeding conveyor 200, a positioning device 300, and a code scanning bracket 400, wherein the code scanning bracket 400 is disposed on the base, and the self-recovery fuse code scanning device 100, the feeding conveyor 200, and the positioning device 300 are respectively disposed on the code scanning bracket; it should be noted that the self-healing fuse code scanning device 100 is used for scanning a code of a self-healing fuse; the feeding conveying device 200 is used for feeding the circuit board with the self-recovery fuse; the positioning device 300 is used for positioning the circuit board with the self-recovery fuse; the code scanning bracket 400 is used for fixing the self-recovery fuse code scanning device 100, the feeding and conveying device 200 and the positioning device 300.

Referring to fig. 3, the feeding and conveying device 200 includes a first guide rail assembly 210, a second guide rail assembly 220 and a conveying bracket 230, wherein the first guide rail assembly and the second guide rail assembly are respectively disposed on the conveying bracket, and the conveying bracket is disposed on the code scanning bracket; the first guide rail assembly 210 comprises a first guide rail mounting plate 211 and a first guide rail 212, the first guide rail mounting plate is arranged on the conveying bracket, and the first guide rail is arranged on the first guide rail mounting plate; the second guide rail assembly 220 includes a second guide rail mounting plate 221 and a second guide rail 222, the second guide rail mounting plate is disposed on the conveying bracket, and the second guide rail is disposed on the second guide rail mounting plate; it should be noted that the first rail assembly 210 and the second rail assembly 220 are used for loading a circuit board; the transfer carriage 230 is used to fix the first rail assembly 210 and the second rail assembly 220; the first guide rail 212 and the second guide rail 222 play a role of guiding, and the circuit board is conveyed.

Referring to fig. 3, the self-restoring fuse code scanning device 100 includes a first code scanning assembly 110, a second code scanning assembly 120, and a code scanning lifting assembly 130, wherein the first code scanning assembly 110, the second code scanning assembly 120, and the code scanning lifting assembly 130 are respectively disposed on the code scanning bracket, the first code scanning assembly 110 includes a first sensor 111, a first camera 112, and a first mounting bracket 113, the first sensor is disposed on the first rail assembly, the first camera is disposed on the first mounting bracket, the second code scanning assembly includes a second sensor 121, a second camera 122, and a second mounting bracket 123, the second sensor is disposed on the first rail assembly, and the second camera is disposed on the second mounting bracket; it should be noted that, the first code scanning component 110 is used for performing a first code scanning to confirm that the circuit board starts to enter the positioning area; the second code scanning assembly 120 is used for performing a second code scanning to confirm that the circuit board needs to be positioned. Thus, the first sensor 111 and the first camera 112 are arranged, so that the circuit board can be subjected to first code scanning, and when the first sensor senses the circuit board, the first camera scans codes, so that the information of the self-recovery fuse on the circuit board can be confirmed; through setting up second inductor 121, second camera 122, can be so that sweep the sign indicating number to the circuit board for the second time, when the circuit board was sensed to the second inductor, the sign indicating number is swept to the second camera, confirms whether the information of self-resuming fuse is the same with correct self-resuming fuse.

Referring to fig. 3, the code scanning lifting assembly 130 includes a lifting mounting plate 131, a lifting rod 132 and a lifting driver 133, the first mounting frame and the second mounting frame are respectively disposed on the lifting mounting plate, a first end of the lifting rod is disposed on the lifting mounting plate, a second end of the lifting rod is disposed on the lifting driver, the lifting driver is disposed on the base, and the lifting driver is configured to drive the lifting rod to ascend or descend; the first code scanning assembly 110 further comprises a first adjusting plate 114 disposed on the lifting mounting plate, and the first mounting frame is disposed on the first adjusting plate; the second code scanning assembly 120 further comprises a second adjusting plate 124 disposed on the lifting mounting plate, and the second mounting frame is disposed on the second adjusting plate; the lifting driver is an air cylinder. It should be noted that, by providing the lifting mounting plate 131, the lifting rod 132 and the lifting driver 133, the first mounting frame and the second mounting frame can be lifted and lowered; and by arranging the first adjusting plate 114 and the second adjusting plate 124, the angles of the first code scanning assembly 110 and the second code scanning assembly 120 can be adjusted respectively, so as to improve the code scanning range of the code scanning assembly on the self-recovery fuse.

Referring to fig. 4, the positioning device 300 includes a first positioning assembly 310 and a second positioning assembly 320, the first positioning assembly and the second positioning assembly are respectively disposed on the code scanning bracket, the first positioning assembly 310 includes a first driving portion 311, a first pushing plate 312 and a positioning plate 313, the first driving portion is disposed on the code scanning bracket, the first pushing plate is disposed at a driving end of the first driving portion, and the positioning plate is disposed on the first pushing plate; the second positioning assembly 320 includes a second driving portion 321, a second pushing plate 322 and a plurality of positioning posts 323, the second driving portion is disposed on the code scanning bracket, the second pushing plate is disposed on the second driving portion, and the plurality of positioning posts are disposed on the second pushing plate respectively; the positioning plate comprises a fixing plate body and a limiting block, the fixing plate body is arranged on the first pushing plate, and the limiting block is arranged on the fixing plate body; the limiting block is provided with a trapezoidal cross section; the positioning columns are four and are respectively arranged on the second pushing plate. It should be noted that the first positioning component 310 is used for positioning the circuit board for the first time; the second positioning assembly 320 is used for supporting the circuit board after the first positioning, so that the positioning of the circuit board is more accurate.

When in work: the circuit board with the self-recovery fuse is loaded from the first guide rail assembly 210 and the second guide rail assembly 220, and then enters a code scanning positioning area along the first guide rail 212 and the second guide rail 222, when the first sensor senses the circuit board, the first camera scans codes, so that the information of the self-recovery fuse on the circuit board can be confirmed, then the circuit board continuously enters the code scanning area, when the second sensor senses the circuit board, the second camera scans codes, whether the information of the self-recovery fuse is the same as the correct self-recovery fuse is confirmed, it needs to be noted that a plurality of self-recovery fuses with two-dimensional codes can be arranged on the circuit board, and after the codes are sequentially scanned by the first camera 112 and the second camera 122, whether the self-recovery fuse is the correct self-recovery fuse is judged, and whether the self-recovery fuse is installed on the correct position is determined, therefore, the insertion of the self-recovery fuse at a wrong position on the circuit board is avoided, the self-recovery fuse on the circuit board can be accurately inserted, the rejection rate of the circuit board is reduced, the quality of the circuit board and the capacity of the circuit board are improved, the stability of the circuit on the circuit board is further improved, and the production efficiency of the circuit board with the self-recovery fuse is further improved. So, can sweep the sign indicating number to the self-resuming fuse to confirm whether the self-resuming fuse is installed on the exact position, thereby avoid the self-resuming fuse to insert the wrong position on the circuit board, guarantee that the self-resuming fuse on the circuit board can accurately be pegged graft, reduce the probability of scrapping of circuit board, improve the quality of circuit board and the productivity of circuit board, and then improve the stability of circuit on the circuit board, and further improve the production efficiency of the circuit board of taking the self-resuming fuse.

It can be understood, at the in-process that self-resuming fuse installed on the circuit board, need carry out the current test to the self-resuming fuse on the circuit board, but among the current testing arrangement, can not pinpoint the circuit board, after the circuit board conveying comes, can't remove test connector, perhaps can't remove the circuit board, can't make test head and circuit board carry out accurate being connected, thereby make and need artifical real-time supervision, or need the artifical position of adjusting circuit board, could reach the purpose of test, the current test efficiency to the circuit board has been reduced, the production cost is increased, the production efficiency of circuit board has been reduced.

For example, referring to fig. 5, the circuit detecting mechanism 2 includes a detecting and positioning device 500, a circuit detecting device 600 and a detecting and conveying device 700, the circuit detecting device 600 and the detecting and conveying device 700 are respectively disposed on the base, and the detecting and positioning device 500 is disposed on the detecting and conveying device 700; it should be noted that the detection positioning device 500 is used for positioning the circuit board to prevent the circuit board from exceeding the detection area; the circuit detection device 600 is used for realizing the current test efficiency of the circuit board; the detection and transmission device 700 is used for transmitting the circuit board from the code scanning detection mechanism. Through setting up the detection positioner, circuit detection device and detection conveyer, can pinpoint the circuit board, when the circuit board conveying comes, can remove test connector or remove the circuit board, make test head and circuit board can carry out accurate being connected, can monitor also need not be adjusted the position of circuit board by the manual work with not artifical, just can reach the purpose of test, the current test of circuit board has been improved, the production cost is reduced, the production efficiency of circuit board has been improved.

Referring to fig. 5, the detecting and conveying device 700 includes a first conveying rail assembly 710, a second conveying rail assembly 720 and a conveying fixing frame 730, wherein the conveying fixing frame is disposed on the base, and the first conveying rail assembly and the second conveying rail assembly are respectively disposed on the conveying fixing frame; the first conveying guide rail assembly comprises a first guide rail fixing plate and a first conveying guide rail, the first guide rail fixing plate is arranged on the conveying fixing frame, and the first conveying guide rail is arranged on the first guide rail fixing plate; the second conveying guide rail assembly comprises a second guide rail fixing plate and a second conveying guide rail, the second guide rail fixing plate is arranged on the conveying fixing frame, and the second conveying guide rail is arranged on the second guide rail fixing plate. Thus, the first conveying guide rail assembly 710, the second conveying guide rail assembly 720 and the conveying fixing frame 730 are arranged, so that the conveying stability and the conveying efficiency of the circuit board can be improved.

Referring to fig. 6, the detecting and positioning device 500 includes a detecting bracket 510, a detecting driving assembly 520, and a positioning baffle assembly 530, the detecting bracket is disposed on the base, the detecting driving assembly and the positioning baffle assembly are disposed on the detecting bracket respectively, the positioning baffle assembly is disposed between the first conveying rail assembly and the second conveying rail assembly, the detecting driving assembly is configured to drive the positioning baffle assembly to move up and down, the positioning baffle assembly 530 includes a first baffle 531, a second baffle 532, and a positioning baffle 533, the first baffle and the second baffle are disposed on the detecting driving assembly at intervals, the positioning baffle is disposed on the detecting driving assembly, and the positioning baffle is disposed at an interval between the first baffle and the second baffle; it should be noted that the detection bracket 510 is used for fixing a detection positioning device; the detection driving assembly 520 is used for driving the positioning baffle assembly 530 to ascend or descend; the positioning baffle plate component 530 is used for blocking the forward route of the circuit board, so as to realize the positioning of the circuit board; the first baffle 531, the second baffle 532 and the positioning stopper 533 are all used to position a circuit board.

Referring to fig. 6, the detection driving assembly 520 includes a detection driver 521, a connecting shaft 522 and a horizontal pushing plate 523, the detection driver is disposed on the detection bracket, the connecting shaft is respectively connected to the detection driver and the horizontal pushing plate, and the first baffle, the second baffle and the positioning stop block are respectively disposed on the horizontal pushing plate; it should be noted that the detection driver 521 is used for driving the connecting shaft 522 to ascend and descend, and further drives the horizontal pushing plate 523 to ascend and descend, so that the positioning baffle assembly 530 ascends or descends.

Referring to fig. 6, the detecting and positioning device 500 further includes an infrared detecting assembly 540, and the infrared detecting assembly is disposed on the first conveying rail assembly; it should be noted that the infrared detection assembly 540 includes a first infrared sensor 541, a second infrared sensor 542, and a third infrared sensor 543, where the first infrared sensor, the second infrared sensor, and the third infrared sensor are respectively disposed on the first guide rail fixing plate; the detection driver is an air cylinder. Thus, the stability and reliability of detection can be improved.

Referring to fig. 5, the circuit detecting device 600 includes a horizontal driving component 610, a vertical driving component 620 and a detecting plug component 630, wherein the horizontal driving component is slidably disposed on the base, the vertical driving component is disposed on the horizontal driving component, and the detecting plug component is disposed on the vertical driving component; it should be noted that, the transverse driving component 610 is used for driving the detection plug component 630 to move horizontally; the vertical driving assembly 620 is used for driving the detection plug assembly 630 to move vertically; the detection plug assembly 630 is used for being plugged on a circuit board, so that the current of the self-recovery fuse on the circuit board can be detected.

Referring to fig. 7, the detection plug assembly 630 includes a plug mounting plate 631, a sensor 632, a clamping rod 633 and a plug connector 634, the plug mounting plate is disposed on the vertical driving assembly, the sensor is disposed on the vertical driving assembly, the clamping rod is disposed on the plug mounting plate, a mounting groove is formed in the plug mounting plate, the plug connector is disposed in the mounting groove, the plug connector is used for being plugged into a circuit board, and the plug connector is also used for being connected to an external detection upper computer; it should be noted that the plug mounting plate 631 is used to mount the detection plug assembly 630; the sensor 632 is used for detecting the height of the plug assembly 630 and the circuit board; the clamping rod 633 is used for mounting the detection plug assembly 630 on the vertical driving assembly 620; the plug connector 634 is used for being plugged on a circuit board to realize the current testing efficiency of the circuit board. So, through setting up grafting mounting panel 631, inductor 632, joint pole 633 and bayonet joint 634, can be so that the realization is to the current test efficiency of circuit board to confirm whether up to standard the performance of self-resuming fuse.

Referring to fig. 8, the transverse driving assembly 610 includes a horizontal rail 611, a horizontal driving portion 612 and a driving mounting rack 613, the horizontal rail is disposed on the base, the driving mounting rack is slidably disposed on the horizontal rail, and the horizontal driving portion is configured to drive the driving mounting rack to slide back and forth along the horizontal rail; by providing the horizontal guide rail 611, the horizontal driving part 612, and the driving mounting frame 613, the horizontal movement of the detection plug assembly 630 can be stably realized.

Referring to fig. 7 and 8, the vertical driving assembly 620 includes a lifting support plate 621, a lifting frame 622, a lifting driving cylinder 623 and a lifting installation block 624, the lifting support plate is disposed on the driving installation frame, the lifting frame is disposed on the lifting support plate, the lifting driving cylinder is disposed on the lifting frame, the lifting installation block is disposed at a driving output end of the lifting driving cylinder, a clamping hole is formed in the lifting installation block, and the clamping rod penetrates through the clamping hole. Through setting up lift backup pad 621, crane 622, lift drive actuating cylinder 623, can realize stably detecting the vertical removal of grafting subassembly 630 to through setting up lift installation piece 624, can be with detecting grafting subassembly 630 joint on lift installation piece 624. The sensor is an infrared sensor; the horizontal driving part is a motor.

During operation, when the first transfer rail assembly 710 and the second transfer rail assembly 720 are transferred into a circuit board, the first infrared sensor 541 senses that the circuit board enters a current detection area, so as to start a detection program, the transverse driving assembly 610 and the vertical driving assembly 620 start to reset and move to the initial positions, it should be noted that the initial positions are positions accurately aligned with the circuit board insertion ports; when the circuit board continues to enter the current region, the second infrared sensor 542 senses the circuit board, the detection driver 521 drives the connecting shaft 522 to ascend, so that the first baffle 531, the second baffle 532 and the positioning baffle 533 on the transverse plate 523 are pushed to ascend, the circuit board can be close to the positioning baffle, when the third infrared sensor 543 detects the circuit board, the circuit board reaches the accurate current detection region, the work of the detection conveying device is stopped, and the circuit board can be positioned at the accurate position. At this time, the lifting driving cylinder 623 drives the lifting mounting block 624 to descend, so that the plug connector 634 can be plugged on the plugging port of the circuit board, and current detection can be performed.

So, through setting up detection positioner, circuit detection device and detection conveyer, can pinpoint the circuit board, when the circuit board conveying comes, can remove test connector or remove the circuit board, make test head and circuit board can carry out accurate being connected, can monitor also need not be adjusted the position of circuit board by the manual work without the manual work, just can reach the mesh of test, the current test of circuit board has been improved, the production cost is reduced, the production efficiency of circuit board has been improved.

It can be understood that in the process of installing the self-recovery fuse on the circuit board, the zero-power resistor of the self-recovery fuse needs to be tested, namely the internal resistance value of the element, and each model has a nominal resistance value range to see whether the zero-power resistor is in the range or not; however, the existing resistance test is manually performed, the resistance error of the test may be large in the test process, after a normal circuit is connected, elements on the circuit board cannot be protected, the normal work of the circuit board cannot be guaranteed, the stability of the circuit board is reduced, and the quality of the circuit board cannot be guaranteed due to the large test error, so that the quality of the circuit board is reduced.

For example, referring to fig. 9, the zero-power resistance testing mechanism 3 includes a resistance testing device 800, a testing positioning device 900 and a testing transmission device, and the resistance testing device 800, the testing positioning device 900 and the testing transmission device are respectively disposed on the base; it should be noted that the resistance testing device 800 is used for moving the test positioning device; the test positioning device 900 is used for positioning the circuit board and performing zero-power resistance test on the self-recovery fuse on the circuit board; the test conveying device is used for conveying the circuit board. Through setting up the detection positioner, circuit detection device and detection conveyer, can pinpoint the circuit board, when the circuit board conveying comes, can remove test connector or remove the circuit board, make test head and circuit board can carry out accurate being connected, can monitor also need not be adjusted the position of circuit board by the manual work with not artifical, just can reach the purpose of test, the current test of circuit board has been improved, the production cost is reduced, the production efficiency of circuit board has been improved.

Referring to fig. 9, the resistance testing apparatus 800 includes a resistance testing bracket 810 disposed on the base, a moving component 820 disposed on the resistance testing bracket, and a fixing component 830 disposed on the moving component; the moving assembly 820 comprises a horizontal moving part 821, a vertical moving part 822 and a resistance testing fixing plate 823, the horizontal moving part is arranged on the resistance testing bracket, the vertical moving part is arranged on the horizontal moving part, the resistance testing fixing plate is arranged on the vertical moving part, and the fixing assembly is arranged on the resistance testing fixing plate; the fixing assembly 830 comprises a limiting ring body 831 and a limiting plate body 832, the limiting plate body is arranged on the resistance test fixing plate, and the limiting ring body is arranged on the limiting plate body; it should be noted that the resistance testing bracket 810 is used for fixing the moving component 820 and the fixing component 830; the moving component 820 is used for realizing horizontal movement or vertical movement of the fixed component 830; the fixing assembly 830 is used for fixing a circuit board; the horizontal moving part 821 is used for realizing the horizontal movement of the fixed component 830; the vertical moving part 822 is used for realizing vertical movement of the fixed component 830; the resistance test fixing plate 823 is used for installing the fixing component 830; the limiting ring body 831 is used for limiting the circuit board; the limiting plate 832 is used for connecting the resistance testing fixing plate 823.

It should be further noted that the horizontal moving part includes a first test driver and a first test connecting shaft, and the first test connecting shaft is disposed at a driving end of the first test driver; the first test driver is a motor; the vertical moving part comprises a second test driver and a second test connecting shaft, and the second test connecting shaft is arranged at the driving end of the second test driver; the second test driver is a motor; the test conveying device comprises a first test guide rail and a second test guide rail, and the first test guide rail and the second test guide rail are respectively arranged on the base; therefore, the stability of movement can be improved, and the stability and the reliability of resistance testing of the circuit board are further improved.

Referring to fig. 10, the test positioning apparatus 900 includes a first positioning code scanning assembly 910, a second positioning code scanning assembly 920 and a test positioning assembly 930, the first positioning code scanning assembly is disposed on the first test guide rail, the second positioning code scanning assembly is disposed on the first test guide rail, and the test positioning assembly is disposed on the limiting plate; the first positioning code scanning assembly 910 includes a first positioning sensor 911 and a first positioning camera 912, the first positioning sensor is disposed on the first test rail, the first positioning camera is disposed on the second test rail, and the first positioning camera is disposed toward the first positioning sensor; the second positioning code scanning assembly 920 comprises a second positioning sensor 921 and a second positioning camera 922, the second positioning sensor is arranged on the first test guide rail, the second positioning camera is arranged on the second test guide rail, and the second positioning camera faces the second positioning sensor; the first positioning sensor is an infrared sensor, and the second positioning sensor is an infrared sensor; the testing positioning assembly 930 includes a resistance testing plug 931 disposed on the plug mounting plate and a plug mounting plate 932 disposed on the limiting plate 832; it should be noted that, the first positioning code scanning component 910 is configured to scan a code of a circuit board for the first time; the second positioning code scanning assembly 920 is used for scanning a code of the circuit board for the second time; the test positioning component 930 is used for performing resistance test on the circuit board; the first positioning inductor 911 and the second positioning inductor 921 are used for inducing a circuit board; the first positioning camera 912 is used for scanning a self-recovery fuse on the circuit board; the second positioning camera 922 is used for scanning a self-recovery fuse on the circuit board; the resistance test plug 931 is provided with a plurality of pins, wherein intervals are respectively arranged among the plurality of pins, and the pins are inserted into the test ports of the circuit board; the plug mounting plate 932 is used for mounting a resistance test plug 931.

When in work: the circuit board that has the self-resuming fuse gets into in the resistance detection region from first test guide rail and second test guide rail, first location inductor 911 on the code subassembly 910 is swept to first location after the circuit board gets into the resistance detection region, first location camera 912 begins to sweep the code to the circuit board, let horizontal migration portion 821 and vertical migration portion 822 reset, and then drive resistance test plug 931 and remove, make resistance test plug 931 move to the very beginning position, after second location inductor 921 senses the circuit board and gets into the resistance detection region, remove the drive of subassembly 820 spacing ring body 831 joint is on the circuit board, thereby make the circuit board fix a position, and resistance test plug 931 also will insert on the test port of circuit board, thereby can make zero power resistance test mechanism carry out the resistance test. So, through setting up detection positioner, circuit detection device and detection conveyer, can pinpoint the circuit board, when the circuit board conveying comes, can remove test connector or remove the circuit board, make test head and circuit board can carry out accurate being connected, can monitor also need not be adjusted the position of circuit board by the manual work without the manual work, just can reach the mesh of test, the current test of circuit board has been improved, the production cost is reduced, the production efficiency of circuit board has been improved.

Compared with the prior art, the invention has the following advantages and beneficial effects:

the invention relates to a code scanning detection mechanism of a self-recovery fuse and code scanning detection equipment thereof, which can scan a code of the self-recovery fuse and determine whether the self-recovery fuse is installed at a correct position, thereby avoiding the self-recovery fuse from being inserted at a wrong position on a circuit board, ensuring that the self-recovery fuse on the circuit board can be accurately inserted, reducing the rejection rate of the circuit board, improving the quality of the circuit board and the productivity of the circuit board, further improving the stability of a circuit on the circuit board, and further improving the production efficiency of the circuit board with the self-recovery fuse.

The above embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. The utility model provides a yard detection mechanism is swept to self-resuming fuse which characterized in that includes: the system comprises a self-recovery fuse code scanning device, a loading conveying device, a positioning device and a code scanning support, wherein the code scanning support is arranged on a base, and the self-recovery fuse code scanning device, the loading conveying device and the positioning device are respectively arranged on the code scanning support;

the feeding and conveying device comprises a first guide rail assembly, a second guide rail assembly and a conveying support, the first guide rail assembly and the second guide rail assembly are respectively arranged on the conveying support, and the conveying support is arranged on the code scanning support;

the self-recovery fuse code scanning device comprises a first code scanning assembly, a second code scanning assembly and a code scanning lifting assembly, wherein the first code scanning assembly, the second code scanning assembly and the code scanning lifting assembly are respectively arranged on the code scanning support, the first code scanning assembly comprises a first inductor, a first camera and a first mounting frame, the first inductor is arranged on the first guide rail assembly, the first camera is arranged on the first mounting frame, the second code scanning assembly comprises a second inductor, a second camera and a second mounting frame, the second inductor is arranged on the first guide rail assembly, and the second camera is arranged on the second mounting frame;

the positioning device comprises a first positioning assembly and a second positioning assembly, the first positioning assembly and the second positioning assembly are respectively arranged on the code scanning support, the first positioning assembly comprises a first driving part, a first pushing plate and a positioning plate, the first driving part is arranged on the code scanning support, the first pushing plate is arranged at the driving end of the first driving part, and the positioning plate is arranged on the first pushing plate; the second positioning assembly comprises a second driving part, a second pushing plate and a plurality of positioning columns, the second driving part is arranged on the code scanning support, the second pushing plate is arranged on the second driving part, and the plurality of positioning columns are respectively arranged on the second pushing plate.

2. The sweep code detection mechanism of a resettable fuse of claim 1 wherein the first rail assembly comprises a first rail mounting plate and a first rail, the first rail mounting plate disposed on the transport bracket and the first rail disposed on the first rail mounting plate.

3. The sweep code detection mechanism of a resettable fuse as claimed in claim 1, wherein the second rail assembly comprises a second rail mounting plate and a second rail, the second rail mounting plate being disposed on the transport bracket and the second rail being disposed on the second rail mounting plate.

4. The self-healing fuse code-scanning detection mechanism according to claim 1, wherein the code-scanning lifting assembly includes a lifting mounting plate, a lifting rod and a lifting driver, the first mounting frame and the second mounting frame are respectively disposed on the lifting mounting plate, a first end of the lifting rod is disposed on the lifting mounting plate, a second end of the lifting rod is disposed on the lifting driver, the lifting driver is disposed on the base, and the lifting driver is configured to drive the lifting rod to ascend or descend.

5. The self-healing fuse code scanning detection mechanism according to claim 4, wherein the first code scanning assembly further comprises a first adjustment plate disposed on the lifting mounting plate, the first mounting bracket being disposed on the first adjustment plate.

6. The self-healing fuse code scanning detection mechanism according to claim 4, wherein the second code scanning assembly further comprises a second adjustment plate disposed on the lifting mounting plate, the second mounting bracket disposed on the second adjustment plate.

7. The self-restoring fuse code-scanning detection mechanism according to claim 1, wherein the positioning plate comprises a fixing plate body and a limiting block, the fixing plate body is disposed on the first pushing plate, and the limiting block is disposed on the fixing plate body.

8. The sweep code detection mechanism of a resettable fuse of claim 7 wherein the stop block has a trapezoidal cross section.

9. The code scanning detection mechanism for the self-recovery fuse as claimed in claim 1, wherein the number of the positioning posts is four, and the four positioning posts are respectively disposed on the second pushing plate.

10. The utility model provides a yard check out test set sweeps of self-resuming fuse which characterized in that includes: the code scanning detection mechanism for the self-recovery fuse of any one of claims 1 to 9.

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