CN216971011U - Code printing and detection integrated equipment for transformer testing - Google Patents

Abstract

The application relates to the technical field of transformer production equipment, in particular to a code printing and detection integrated equipment for transformer testing. The testing jig is sequentially arranged on a conveying path of the conveying assembly, the transferring assembly, the code printing assembly and the detecting assembly are arranged, the testing jig is used for testing the electrical performance of the transformer, the transferring assembly is arranged above the testing jig and used for transferring the transformer between the conveying assembly and the testing jig, the code printing assembly is arranged above one of the conveying assemblies and used for printing the codes on the transformer, the detecting assembly is arranged at the tail end of the conveying assembly and used for detecting the codes on the transformer, the electrical testing-code printing-detecting procedures are fully automatically completed, the production efficiency is high, the full-automatic mode production precision is high, the accuracy of the procedures such as the performance testing and the code printing detection is ensured, the quality of the finished transformer is improved, the whole structure is compact, the occupied space is small, the production time sequence connection among the procedures is smooth, and the production efficiency is high.

Description

Code printing and detection integrated equipment for transformer testing

Technical Field

The application relates to the technical field of transformer production equipment, in particular to a transformer test code printing and detection integrated equipment.

Background

Planar transformer need carry out electrical performance test after the wire winding assembly is accomplished, and need mark the sign indicating number and mark on the transformer, and in prior art, often need separately a plurality of equipment to carry out test marking work respectively, it is correct whether rethread manual detection beats the sign indicating number, it is big to set up a plurality of equipment occupation spaces, and need the manual work to shift the transformer between a plurality of equipment, semi-automatic operation causes production efficiency to hang down, manual operation's semi-automatic production mode leads to placing the precision of transformer low easily, lead to the test and beat the degree of accuracy of processes such as mark detection low, influence transformer finished product quality.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the application provides a transformer test code printing and detection integrated device which comprises a plurality of groups of conveying assemblies which are arranged side by side along the same conveying direction and used for conveying transformers, and a test jig, wherein the test jig is arranged between two groups of conveying assemblies and used for testing the electrical performance of the transformers; the transfer assembly is arranged above the test fixture and used for transferring the transformer between the conveying assembly and the test fixture; the coding assembly is arranged above one of the conveying assemblies and used for coding the transformer; and the detection component is arranged at the tail end of the conveying component and used for detecting the mark codes on the transformer.

Preferably, the transfer assembly comprises a vertical plate with an Jiong-shaped sliding groove, a clamping jaw assembly arranged on the vertical plate in a sliding manner, and a rotating shaft arranged on the sliding groove in a rolling manner and connected with the clamping jaw assembly, and the vertical plate is provided with a first driving assembly for driving the rotating shaft to move along the sliding groove.

Preferably, the first driving assembly comprises a connecting rod and a driving element for driving the connecting rod to rotate; the connecting rod is formed with a limiting groove for accommodating the rotating shaft.

Preferably, the test fixture comprises a test machine for detecting the electrical performance of the transformer and fixing components arranged around the test machine, and a probe for detecting the conduction of the magnetic core of the transformer is arranged above the test machine.

Preferably, the coding assembly comprises a laser coding machine arranged above the conveying assembly and a transfer assembly used for transferring the transformer; and the tail end of the conveying component is positioned under the laser coding machine and is provided with a positioning component.

Preferably, the positioning assembly comprises a positioning table arranged in a lifting manner and a positioning block detachably mounted on the positioning table; a limiting groove for accommodating the transformer pin is formed in the positioning table; and a sensor for sensing the in-place of the transformer and a magnetic part for fixing the transformer are arranged on the side face of the positioning block.

Preferably, the transfer assembly comprises a vertical frame with a U-shaped groove, a transmission assembly and a clamping assembly fixed on the transmission assembly; the transmission assembly comprises a slide rail and a roller, the slide rail is horizontally arranged on the vertical frame in a sliding manner, and the roller is fixedly connected to the slide rail and is arranged in the U-shaped groove in a rolling manner; and a second driving component for driving the rolling shaft to move along the U-shaped groove is arranged on the vertical frame.

Preferably, the detection assembly comprises a turntable assembly for loading the transformer, a transfer assembly arranged above the turntable assembly and used for transferring the transformer, and a detection assembly arranged above the turntable assembly and used for detecting the mark code of the transformer.

Preferably, the turntable assembly comprises a turntable which can be rotatably arranged and a plurality of material carrying platforms which are annularly distributed on the turntable; and the material carrying platform is provided with a limiting structure for fixing the transformer.

Preferably, the transformer transfer device further comprises a first blanking assembly arranged on the transfer assembly transfer path and used for conveying qualified transformers and a second blanking assembly used for conveying unqualified transformers.

From the above, the following beneficial effects can be obtained by applying the method provided by the present application: the testing jig, the transferring component, the marking component and the detecting component are sequentially arranged on the conveying path of the conveying component, the testing jig is used for testing the electrical performance of the transformer and is arranged between two groups of conveying components, the transferring component is arranged above the testing jig and is used for transferring the transformer between the conveying component and the testing jig, the marking component is arranged above one conveying component and is used for marking the transformer, the detecting component is arranged at the tail end of the conveying component and is used for detecting the mark on the transformer, the electrical testing, marking and detecting procedures are further completed fully automatically, the production efficiency is high, the full-automatic mode production precision is high, the accuracy of the procedures such as the performance testing, the marking and detecting is ensured, the quality of the finished product of the transformer is improved, the overall structure is compact, the occupied space is small, and the production time sequence connection among the procedures is smooth, the production efficiency is high.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments of the present application or the prior art will be briefly described below. It should be apparent that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained by those skilled in the art without inventive exercise.

FIG. 1 is an overall structure diagram of a transformer test code printing and detection integrated device in the embodiment of the application;

FIG. 2 is a structural diagram of a transfer assembly of the test coding and detection integrated equipment of the transformer in the embodiment of the application;

FIG. 3 is a side view of a transfer assembly of the integrated equipment for testing, coding and detecting the transformer according to the embodiment of the present application;

FIG. 4 is a structural diagram of a positioning assembly of the test code printing and detection integrated device of the transformer in the embodiment of the application;

FIG. 5 is a structural diagram of a transfer assembly of the integrated equipment for testing, coding and detecting the transformer according to the embodiment of the present application;

FIG. 6 is a side view of a transfer module of the integrated apparatus for testing, coding and detecting transformers according to the embodiment of the present application;

FIG. 7 is a partial enlarged view of the test code printing and detection integrated equipment of the transformer in the embodiment of the application;

FIG. 8 is a structural diagram of a detection assembly of the test coding and detection integrated device for the transformer in the embodiment of the application;

FIG. 9 is a structural diagram of a turntable assembly of the test code printing and detection integrated equipment for the transformer in the embodiment of the application;

fig. 10 is a material loading table structure diagram of the test code printing and detection integrated equipment for the transformer in the embodiment of the application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all 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 application.

In order to solve the above technical problem, this embodiment provides a code printing and detecting integrated device for testing transformers, as shown in fig. 1, which includes a plurality of sets of conveying assemblies 10 arranged side by side along a same conveying direction and used for conveying transformers, and a testing jig 20, a transferring assembly 30, a code printing assembly 40, and a detecting assembly 50 arranged in sequence along a conveying path of the conveying assemblies 10, wherein the testing jig 20 is used for testing electrical performance of transformers and arranged between two sets of conveying assemblies 10, the transferring assembly 30 is arranged above the testing jig 20 and used for transferring transformers between the conveying assemblies 10 and the testing jig 20, the code printing assembly 40 is arranged above one of the conveying assemblies 10 and used for printing codes on the transformers, the detecting assembly 50 is arranged at an end of the conveying assembly 10 and used for detecting codes on the transformers, thereby fully automatically completing an electrical testing-code printing-detecting process, the production efficiency is high, the full-automatic mode production precision is high, the accuracy of procedures such as performance testing, marking detection and the like is ensured, and the quality of transformer finished products is improved.

As shown in fig. 2-3, the conveying assemblies 10 are straight vibrating feeding devices and at least include three groups, the testing fixture 20 and the transferring assembly 30 are disposed between the first group and the second group of conveying assemblies 10, the coding assembly 40 is disposed above the second group of conveying assemblies 10, the detecting assembly 50 is disposed above the end of the third group of conveying assemblies 10, the first group of conveying assemblies 10 conveys the transformer, and the transformer on the conveying assemblies 10 is transferred to the testing fixture 20 through the transferring assembly 30 for testing, wherein the testing fixture 20 includes a testing machine 21 for detecting the electrical performance of the transformer and fixing assemblies 22 disposed around the testing machine 21, and a probe 23 for detecting the conduction of the transformer core is disposed above the testing machine 21. The fixing component 22 is an adjusting cylinder, the position of the testing machine 21 is accurately adjusted by arranging the fixing component 22 around the testing machine 21, the accuracy of the placement position of the transformer is guaranteed, and the accuracy of the electrical performance test is improved. And a prober 23 extending to the side surface of the transformer is arranged above the testing machine 21, and the prober 23 is contacted with the magnetic core on the side surface of the transformer so as to test the conduction condition of the magnetic core.

In order to accurately transfer the transformer from the conveying assembly 10 to the testing fixture 20, a transfer assembly 30 is disposed above the testing fixture 20, the transfer assembly 30 includes a vertical plate 31 formed with a sliding slot 311 shaped like Jiong, a clamping jaw assembly 32 slidably disposed on the vertical plate 31, and a rotating shaft 33 rotatably disposed on the sliding slot 311 and connected to the clamping jaw assembly 32, and a first driving assembly 34 for driving the rotating shaft 33 to move along the sliding slot 311 is disposed on the vertical plate 31. The clamping jaw assemblies 32 are arranged in two groups along the conveying direction, and are respectively used for grabbing the transformer on the first group of conveying assemblies 10 and moving the transformer to the test fixture 20, grabbing the transformer on the test fixture 20 and moving the transformer to the second group of conveying assemblies 10, and meanwhile grabbing and moving the transformer to realize efficient synchronous transfer, so that the working efficiency is improved.

Further, a linear guide 312 extending horizontally is disposed on the vertical plate 31, a sliding plate 313 is slidably disposed on the linear guide 312, the clamping jaw assembly 32 includes a mounting plate 321 fixed on the sliding plate 313 and two sets of clamping jaws 322 fixed on the mounting plate 321, the clamping jaws 322 drive the clamping transformer by the air cylinder, the mounting plate 321 is slidably disposed on the sliding plate 313, the rotating shaft 33 is fixedly connected with the mounting plate 321, the first driving assembly 34 includes a connecting rod 341 and a driving element 342 driving the connecting rod 341 to rotate, the driving element 342 is a driving motor, and the connecting rod 341 is formed with a limiting groove 3411 accommodating the rotating shaft 33. The rotating shaft 33 is formed with a rotating wheel 331 respectively connected with the sliding slot 311 and the limiting slot 3411 in a rolling fit manner, when the driving element 342 drives the connecting rod 341 to rotate, the limiting slot 3411 of the connecting rod 341 drives the rotating wheel 331 of the rotating shaft 33 to roll in the limiting slot 3411, and further drives the rotating shaft 33 to move along the Jiong-shaped sliding slot 311, at this time, the rotating shaft 33 drives the mounting plate 321 to slide on the sliding plate 313, and simultaneously drives the sliding plate 313 to horizontally move along the linear guide rail 312, so that the clamping jaw 322 clamps the transformer to form a Jiong-shaped moving path.

In order to realize sorting the transformers with unqualified performance after the test of the test fixture 20, further, a conveyor belt 36 is arranged between the test fixture 20 and the second group of conveying assemblies 10, the conveyor belt 36 can be arranged in a lifting manner and is positioned on a moving path in the shape of a clamping jaw 322 Jiong, the conveyor belt 36 is higher than the second group of conveying assemblies 10, when the clamping jaw 322 moves along a Jiong-shaped sliding groove 311 to pass through the conveyor belt 36, if the transformer is unqualified in test, the transformer is placed on the conveyor belt 36, if the transformer is qualified in test, the transformer continues to move and is placed on the second group of conveying assemblies 10, the moving path is short, the structure is compact, the occupied space is small, and efficient production of the transformers is realized. The material transfer of different height position points is realized only through a set of driving assembly, and for the material transfer of specific position, the problem that large-scale transmission equipment causes high cost and large occupied space can be avoided, and the cost of production equipment is reduced while the transformer is transferred with high efficiency.

In order to realize marking and coding of the transformer, the coding assembly 40 comprises a laser coding machine 41 arranged above the second group of conveying assemblies 10 and a transferring assembly 42 for transferring the transformer; and a positioning component 11 is arranged at the tail end of the conveying component 10 and is positioned right below the laser coding machine 41. After the conveying assembly 10 conveys the transformer to the tail end, the transformer is fixed through the positioning assembly 11, and then the laser coding machine 41 can accurately code the transformer.

Specifically, as shown in fig. 4, the positioning assembly 11 includes a positioning table 13 capable of being set up in a lifting manner and a positioning block 12 detachably mounted on the positioning table 13, a limiting groove 16 for accommodating a pin of the transformer is formed in the positioning table 13, the transformer is limited by the limiting groove 16, the position of the transformer is prevented from inclining, and a sensor 14 for sensing that the transformer is in place and a magnetic part 15 for fixing the transformer are arranged on the side surface of the positioning block 12 facing the conveying assembly 10. After the sensor 14 senses that the transformer abuts against the positioning block 12, the electromagnetic control magnetic part 15 absorbs the fixed transformer, so that the laser coding machine 41 codes the fixed transformer, and the accuracy of a coding position is guaranteed.

As shown in fig. 5 to 6, in order to move the transformer from the second group of conveyor assemblies 10 to the third group of conveyor assemblies 10, the transfer assembly 42 includes a stand 421 having a U-shaped slot 4211 formed therein, a transmission assembly 422, and a clamping assembly 424 fixed to the transmission assembly 422; the transmission assembly 422 comprises a slide rail 4222 horizontally arranged on the vertical frame 421 in a sliding manner, and a roller 4221 fixedly connected to the slide rail 4222 and arranged in the U-shaped groove 4211 in a rolling manner; the stand 421 is provided with a second driving assembly 423 for driving the roller 4221 to move along the U-shaped groove 4211. Second drive assembly 423 drive roller 4221 moves along U-shaped groove 4211, and then makes centre gripping subassembly 424 on the drive assembly 422 be the arc orbit and move, only realizes the material of different height position points through a set of drive assembly and shifts, to the material of specific position shifts, can avoid large-scale transmission equipment to cause the problem that the high occupation space of cost is big, has reduced production facility's cost when guaranteeing that the transformer is transferred to the high efficiency.

In order to realize that the driving transmission assembly 422 moves along the U-shaped groove 4211, as shown in fig. 6-7, the driving assembly 423 includes a transmission rod 4231 and a driving element 4232 for driving the transmission rod 4231 to rotate, the transmission rod 4231 is formed with a sliding slot 42311 for accommodating the roller 4221, the roller 4221 is simultaneously connected with the sliding slot 4231 and the U-shaped groove 4211 in a rolling manner, one end of the roller 4221 is inserted and fixed on the sliding rail 4222, the driving roller 4221 moves along the U-shaped groove 4211 through the transmission rod 4231, and the clamping assembly 424 is driven to move in an arc shape.

Specifically, as shown in fig. 7, the roller 4221 is formed with a roller 42211 provided in a U-shaped groove 4211 and a slide groove 42311, respectively. The two rollers 42211 are respectively matched with the U-shaped groove 4211 and the sliding groove 42311 in a rolling manner, so that the transmission rod 4231 rotates to drive the rolling shaft 4221 to move along the U-shaped groove 4211, and the sliding rail 4222 moves in an arc track.

Furthermore, a rail 4212 extending in the horizontal direction is arranged below the U-shaped groove 4211 on the stand 421, a slider 4223 is arranged on the rail 4212 in a sliding manner, the slide rail 4222 is vertically arranged on the slider 4223 in a sliding manner, the clamping component 424 is fixed at the bottom of the slide rail 4222, when the transmission rod 4231 rotates to drive the roller 4221 to move along the U-shaped groove 11, the roller 4221 drives the slide rail 4222 to move along the track of the U-shaped groove 4211, the slide rail 4222 vertically slides on the slider 4223 to drive the slide rail 4222 to horizontally slide on the rail 4212, and finally the slide rail 4222 moves in an arc track.

And limiting blocks 4213 for limiting the position of the transmission rod 4231 are fixed on the vertical frame 421 at two sides of the bottom of the U-shaped groove 4211. A fixed block 4225 for mounting a sensing element is arranged on the limit block 4213, a mounting block 4224 for fixing a sensing piece is arranged at the top of the sliding rail 4222, and when the transmission rod 4231 rotates to the bottom of the U-shaped groove 4211, the mounting block 4224 on the sliding rail 4222 moves to the position corresponding to the fixed block 25, and the sensing element on the fixed block 25 senses that the transmission rod 4231 rotates in place.

In order to realize stable clamping of the transformer, the clamping assembly 424 comprises a driving cylinder 4242 fixed at the bottom of the sliding rail 4222, and a clamping block 4241 driven and clamped by the driving cylinder 4242. The clamping surfaces of the clamping jaws 4241 are provided with positioning grooves, so that the transformer can be stably clamped through the positioning grooves, and the accuracy of the transfer position of the transformer is improved.

In actual production, the conditions of wrong code printing and code printing missing can occur in the code printing process of the laser code printing machine 41, and therefore detection needs to be performed after the code printing of the transformer is completed, for this reason, a detection assembly 50 is arranged at the tail end of the third group of conveying assemblies 10, as shown in fig. 8-9, the detection assembly 50 comprises a rotary table assembly 51 used for loading the transformer, a transmission assembly 53 arranged above the rotary table assembly 51 and used for transferring the transformer, and a visual detection assembly 52 arranged above the rotary table assembly 51 and used for detecting the code of the transformer. The detection component 20 is a CCD camera vision detection system, which is used for visually identifying and detecting whether the mark code of the transformer on the turntable component 51 is correct, so as to achieve the purpose of accurate detection, wherein the turntable component 51 comprises a turntable 512 which can be rotatably arranged, and a plurality of material loading platforms 511 which are annularly distributed on the turntable 512, a transmission component 53 for loading the transformer is arranged above one material loading platform 511, a vision detection component 52 is arranged above the other material loading platform 511, the transfer component 30 transfers the transformer to the detection station of the vision detection component 52 by rotating the turntable 512 after placing the transformer on one material loading platform 511 at the loading station, so as to visually detect the mark code on the transformer by the vision detection component 52, a limit structure for fixing the transformer is arranged on the material loading platform 511, and the positioning and fixing of the transformer are achieved by the limit structure, the rotary table 512 is guaranteed that the position of the transformer cannot deviate in the rotary transfer process, the position precision is improved, the detection accuracy is guaranteed, and the automatic feeding, transferring and detecting greatly improve the detection efficiency.

Specifically, in order to position and fix the transformer by the turntable assembly 51, as shown in fig. 10, a containing groove 5111 for limiting the transformer is formed in the material loading platform 511, an electromagnet 5112 for sucking and fixing the transformer is installed below the containing groove 5111 on the material loading platform 511, after the transformer is placed on the containing groove 5111, the electromagnet 5112 sucks the magnetic core of the transformer, the electromagnet 5112 can be an electromagnet, so that the sucking and releasing of the electromagnet 5112 can be controlled, the containing groove 5111 and the electromagnet 5112 form a limiting structure, the limiting and fixing effects on the transformer are realized through the containing groove 5111 and the electromagnet 5112, and it is ensured that the position of the transformer does not deviate in the rotation process of the turntable 512.

Further, the two sides of the accommodating groove 5111 are respectively provided with a slot 5113 and a groove 5114 for accommodating a transformer pin, the pin of the transformer is limited through the slot 5113 and the groove 5114, so that the purpose of limiting the transformer is achieved, the transformer is fixed through the electromagnet 5112, and the transformer is detected through the visual detection assembly 52.

In order to realize the position transfer of the transformer between the visual inspection component 52 and the conveying component 53, the turntable component 51 further includes a rotation driving component 513 installed below the turntable 512, and the rotation driving component 513 is composed of a driving motor and a driving belt, so as to drive the turntable 512 to rotate, thereby realizing the position transfer of the transformer on the loading platform 511 between the visual inspection component 52 and the conveying component 53. The material loading platform 511 of this embodiment includes four and evenly distributed on the turntable 512 in a ring shape, the sensor assemblies 514 are disposed on two sides of the turntable 512, and the sensor assemblies 514 are correlation sensors and located on two opposite sides of the material loading platform 511, and are configured to detect whether the transformer on the material loading platform 511 is in place, so as to ensure that the transmission assembly 53 places the transformer on the material loading platform 511.

In order to realize the automatic transformer feeding, as shown in fig. 8, a first feeding unit 61 for conveying a qualified transformer and a second feeding unit 62 for conveying a unqualified transformer are provided on a transfer path of the transfer unit 53. First unloading subassembly 50 and second unloading subassembly 60 all can be the conveyor that directly shakes, and first unloading subassembly 61 and second unloading subassembly 62 all establish in revolving stage subassembly 51 one side, and conveying assembly 53 will detect qualified product and place at first unloading subassembly 61 and carry out the unloading, and detect unqualified product and then place at second unloading subassembly 62, realize the high-efficient letter sorting of transformer.

In order to realize the transformer clamping and transferring, the conveying assembly 53 includes a plurality of sets of clamping members 531 for clamping the transformer, and a linear driving assembly 532 for driving the clamping members 531 to move, the clamping members 531 can move downwards and clamp the transformer on the loading assembly 54, the linear driving assembly 532 drives the clamping members 531 to move above the object stage 511, and then the transformer is placed on the object stage 511, wherein the clamping members 531 of the embodiment include two sets, while one set of clamping members 531 clamps the transformer on the loading assembly 54 and transfers to the object stage 511, the other set of clamping members 531 clamps the transformer which has been detected on the object stage 511 and transfers to the first unloading assembly 61 or the second unloading assembly 62, and the synchronous transfer improves the detection efficiency.

In summary, the scheme of the application comprises a test jig, a transfer assembly, a code printing assembly and a detection assembly which are sequentially arranged on a conveying path of a conveying assembly, wherein the test jig is used for testing the electrical performance of a transformer and is arranged between two groups of conveying assemblies, the transfer assembly is arranged above the test jig and is used for transferring the transformer between the conveying assemblies and the test jig, the code printing assembly is arranged above one of the conveying assemblies and is used for printing a code on the transformer, the detection assembly is arranged at the tail end of the conveying assemblies and is used for detecting the code on the transformer, so that the electrical test, the code printing and the detection procedures are fully automatically completed, the production efficiency is high, the production precision in a full-automatic mode is high, the accuracy of the procedures such as the performance test, the code printing and the detection is ensured, the quality of a transformer finished product is improved, the whole structure is compact, the occupied space is small, and the production time sequence connection among the procedures is smooth, the production efficiency is high.

The above-described embodiments do not limit the scope of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the above-described embodiments should be included in the protection scope of the technical solution.

Claims (10)

1. The utility model provides a test of transformer is beaten sign indicating number and is detected integrative equipment which characterized in that: comprises a plurality of groups of conveying components (10) which are arranged side by side along the same conveying direction and are used for conveying transformers, and

the testing jig (20) is arranged between the two groups of conveying assemblies (10) and is used for testing the electrical performance of the transformer;

the transfer component (30) is arranged above the test fixture (20) and is used for transferring the transformer between the conveying component (10) and the test fixture (20);

the coding assembly (40) is arranged above one of the conveying assemblies (10) and used for coding the transformer;

and the detection assembly (50) is arranged at the tail end of the conveying assembly (10) and is used for detecting the code on the transformer.

2. The transformer test coding and detection integrated device according to claim 1, characterized in that: the transfer assembly (30) comprises a vertical plate (31) formed with an Jiong-shaped sliding groove (311), a clamping jaw assembly (32) arranged on the vertical plate (31) in a sliding mode, and a rotating shaft (33) arranged on the sliding groove (311) in a rolling mode and connected with the clamping jaw assembly (32), and a first driving assembly (34) used for driving the rotating shaft (33) to move along the sliding groove (311) is arranged on the vertical plate (31).

3. The transformer test coding and detection integrated device according to claim 2, characterized in that: the first driving assembly (34) comprises a connecting rod (341) and a driving element (342) for driving the connecting rod (341) to rotate; the connecting rod (341) is formed with a restriction groove (3411) for receiving the rotating shaft (33).

4. The transformer test coding and detection integrated device according to claim 1, characterized in that: the testing jig (20) comprises a testing machine (21) for detecting the electrical performance of the transformer and fixing components (22) arranged on the periphery of the testing machine (21), and a probe (23) for detecting the conduction of the magnetic core of the transformer is arranged above the testing machine (21).

5. The transformer test coding and detection integrated device according to claim 1, characterized in that: the coding assembly (40) comprises a laser coding machine (41) arranged above the conveying assembly (10) and a transfer assembly (42) used for transferring a transformer; and the tail end of the conveying component (10) is positioned under the laser coding machine (41) and is provided with a positioning component (11).

6. The transformer test coding and detection integrated device according to claim 5, wherein: the positioning assembly (11) comprises a positioning table (13) which can be arranged in a lifting way and a positioning block (12) which is detachably arranged on the positioning table (13); a limiting groove (16) for accommodating a transformer pin is formed in the positioning table (13); and a sensor (14) for sensing the in-place of the transformer and a magnetic part (15) for fixing the transformer are arranged on the side surface of the positioning block (12).

7. The transformer test coding and detection integrated device according to claim 5, wherein: the transfer assembly (42) comprises a vertical frame (421) with a U-shaped groove (4211), a transmission assembly (422) and a clamping assembly (424) fixed on the transmission assembly (422); the transmission assembly (422) comprises a sliding rail (4222) which is arranged on the vertical frame (421) in a sliding mode along the horizontal direction, and a rolling shaft (4221) which is fixedly connected to the sliding rail (4222) and is arranged in the U-shaped groove (4211) in a rolling mode; and a second driving assembly (423) for driving the roller (4221) to move along the U-shaped groove (4211) is arranged on the stand (421).

8. The transformer test coding and detection integrated device according to claim 1, characterized in that: the detection assembly (50) comprises a rotary table assembly (51) used for loading the transformer, a transmission assembly (53) arranged above the rotary table assembly (51) and used for transferring the transformer, and a visual detection assembly (52) arranged above the rotary table assembly (51) and used for detecting the mark code of the transformer.

9. The transformer test coding and detection integrated device according to claim 8, wherein: the rotary table assembly (51) comprises a rotary table (512) which can be arranged in a rotating way and a plurality of material carrying tables (511) which are distributed on the rotary table (512) in an annular way; and a limiting structure for fixing the transformer is arranged on the material loading platform (511).

10. The transformer test coding and detection integrated device according to claim 8, wherein: the transformer feeding device further comprises a first blanking assembly (61) and a second blanking assembly (62), wherein the first blanking assembly (61) is arranged on the transfer path of the conveying assembly (53) and is used for conveying qualified transformers, and the second blanking assembly (62) is used for conveying unqualified transformers.

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