CN220761354U - Automatic printing resistance tester - Google Patents

Abstract

The utility model relates to the technical field of resistor processing, in particular to an automatic printing resistor measuring machine. According to the utility model, the elements are conveyed to the conveying guide rail one by one through the feeding assembly, the sorting assembly screens the elements and then marks the elements, the marking assembly marks the elements, the detection assembly detects the resistance value of the marked elements, and then the conveying guide rail conveys the resistance elements to the receiving assembly for receiving, so that the automatic operation of the resistance elements is realized, an operator can automatically sort, convey, mark and detect and recycle the resistance value by only putting the resistance elements on the feeding assembly, the automation degree is high, the labor cost is greatly saved, and the detection data difference caused by incorrect manual operation is reduced; the marking assembly and the detecting assembly realize the integration of printing and resistance detection, and combine the related flow steps, thereby not only improving the working efficiency, but also effectively reducing the influence of improper manual operation on experimental data acquisition.

Description

Automatic printing resistance tester

Technical Field

The utility model relates to the technical field of resistor processing, in particular to an automatic printing resistor measuring machine.

Background

The traditional test fixture can only detect the resistance value of a resistor at each time, test data can only be recorded manually, and the whole-process operation is performed manually, so that the efficiency of the mode is low, the error is large, the experimental test and data acquisition of batch products are not facilitated, the labor cost is greatly increased, and the corresponding quality problem is likely to occur. Moreover, the printing and the data of resistance detection cannot be synchronized, the detection data and the printing on the resistor are required to be manually corresponding, the middle link process is complicated, and the experiment is easy to be improper.

Disclosure of Invention

The utility model aims to solve the technical problem of providing the automatic printing resistor measuring machine which can automatically perform resistor sorting, conveying, marking, resistor detection and recovery, has high degree of automation, greatly saves labor cost and improves working efficiency and precision.

In order to solve the technical problems, the technical scheme adopted by the utility model for solving the technical problems is as follows:

an automatic printing resistor-measuring machine, comprising:

the feeding assembly is used for conveying the elements to the conveying guide rail one by one;

the marking assembly is arranged on one side of the conveying guide rail and is used for marking the elements on the conveying guide rail;

the detection assembly is arranged on one side of the conveying guide rail and is used for detecting the resistance value of the element after marking;

the material receiving assembly is arranged at the discharge end of the conveying guide rail and is used for loading the element for finishing resistance detection;

the sorting assembly is arranged at the joint of the feeding assembly and the conveying guide rail and is used for screening elements on the conveying guide rail.

In one embodiment of the utility model, the sorting assembly comprises:

the sorting frame is provided with a mounting frame, and the mounting frame is arranged above the conveying guide rail;

the sorting camera is arranged on the mounting frame, is arranged right above the conveying guide rail and is used for shooting elements to screen the elements;

and the pushing component is arranged on the sorting frame and is used for pushing the elements which do not pass through screening to the upper material assembly.

In one embodiment of the utility model, the pushing component comprises an air blowing pipe, the air blowing pipe is connected with the sorting frame through a bracket, the air blowing pipe is arranged opposite to the conveying guide rail, and the air blowing pipe blows the elements on the conveying guide rail to enable the elements to be blanked onto the feeding component.

In one embodiment of the utility model, the conveying guide rail is provided with a blanking notch, the blanking notch is arranged on the side wall, close to the feeding assembly, of the conveying guide rail, and the pushing component pushes the element on the conveying guide rail from the position of the blanking notch to the feeding assembly.

In one embodiment of the utility model, the feeding assembly comprises a feeding frame, a vibration disc is arranged on the feeding frame, a discharging track is arranged on the vibration disc, the discharging track is connected with the conveying guide rail, and the vibration disc conveys the components onto the conveying guide rail one by one.

In one embodiment of the utility model, the marking assembly comprises a support frame, a laser marking machine is arranged on the support frame, a laser head of the marking machine is arranged right above the conveying guide rail, and the marking machine carries out serial number printing on elements on the conveying guide rail.

In one embodiment of the utility model, the detection assembly comprises a detection frame, a resistance value detector is arranged on the detection frame, a test head is arranged on the resistance value detector, a detection probe is arranged on the test head, the detection probe is arranged right above the conveying guide rail, and the test head drives the detection probe to contact with the element so as to realize resistance value detection of the element.

In one embodiment of the utility model, the material receiving assembly comprises a material receiving rack, a material box for loading the components is arranged on the material receiving rack, the material discharging end of the conveying guide rail is arranged above the opening of the material box, and the components on the conveying guide rail are blanked into the material box through the material discharging end.

In one embodiment of the utility model, the automatic marking device further comprises a supporting frame, the conveying guide rail is arranged on the supporting frame, the supporting frame comprises a base, the base is arranged right below the marking assembly or the detecting assembly, an adjusting seat is arranged on the base, and the conveying guide rail is arranged on the adjusting seat.

In one embodiment of the utility model, the adjusting seat comprises an adjusting plate, a cushion block is arranged on the adjusting plate, the conveying guide rail is arranged on the cushion block, adjusting screws are arranged at four corners of the adjusting plate, screw holes matched with the adjusting screws are arranged on the base, the adjusting screws are connected with the screw holes on the base, and the relative position between the adjusting plate and the base is adjusted by rotating the adjusting screws.

The utility model has the beneficial effects that:

according to the utility model, the elements are conveyed to the conveying guide rail one by one through the feeding assembly, the sorting assembly screens the elements and then marks the elements, the marking assembly marks the elements, the detection assembly detects the resistance value of the marked elements, and then the conveying guide rail conveys the resistance elements to the receiving assembly for receiving, so that the automatic operation of the resistance elements is realized, an operator can automatically sort, convey, mark and detect and recycle the resistance value by only putting the resistance elements on the feeding assembly, the automation degree is high, the labor cost is greatly saved, and the detection data difference caused by incorrect manual operation is reduced; the marking assembly and the detecting assembly realize the integration of printing and resistance detection, and combine the related flow steps, thereby not only improving the working efficiency, but also effectively reducing the influence of improper manual operation on experimental data acquisition.

Drawings

FIG. 1 is a schematic diagram of an automatic printing resistor tester according to the present utility model.

Fig. 2 is a schematic view of the pushing member of the present utility model.

The reference numerals in the figures illustrate: 1. a feeding assembly; 11. a vibration plate; 12. a discharge rail; 2. a sorting assembly; 21. a sorting rack; 23. a mounting frame; 24. sorting cameras; 25. an air blowing pipe; 3. a conveying guide rail; 31. a blanking notch; 4. a marking assembly; 41. laser head of the marking machine; 5. a detection frame; 51. a resistance value detector; 52. a test head; 53. detecting a probe; 6. a magazine; 61. a material receiving frame; 62. an opening; 7. a base; 71. an adjusting plate; 72. a cushion block; 73. and adjusting the screw.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the utility model and practice it.

Referring to fig. 1, an automatic printing resist tester includes:

the feeding assembly 1 is used for conveying the components to the conveying guide rail 3 one by one;

the marking assembly 4 is arranged on one side of the conveying guide rail 3, and the marking assembly 4 performs marking treatment on elements on the conveying guide rail 3;

the detection assembly is arranged on one side of the conveying guide rail 3 and is used for detecting the resistance value of the marked element;

the material receiving assembly is arranged at the discharge end of the conveying guide rail 3 and is used for loading the element for finishing resistance detection;

the sorting assembly 2 is arranged at the joint of the feeding assembly 1 and the conveying guide rail 3, and the sorting assembly 2 is used for screening elements on the conveying guide rail 3.

According to the utility model, the feeding assembly 1 is used for conveying the elements to the conveying guide rail 3 one by one, the sorting assembly 2 is used for screening the elements, the marking assembly 4 is used for marking, the detection assembly is used for detecting the resistance value of the marked elements, the conveying guide rail 3 is used for conveying the resistance elements to the receiving assembly for receiving materials, the automatic operation of the resistance elements is realized, an operator only needs to put the resistance elements on the feeding assembly 1, and the resistance sorting, conveying, marking and resistance value detection and recovery can be automatically carried out, so that the automation degree is high, the labor cost is greatly saved, and the detection data difference caused by improper manual operation is reduced; the marking assembly 4 and the detection assembly realize the integration of printing and resistance detection, and the related flow steps are combined together, so that the working efficiency is improved, and meanwhile, the influence of improper manual operation on experimental data acquisition can be effectively reduced.

In one embodiment of the utility model, the sorting assembly 2 comprises:

a sorting rack 21, wherein a mounting frame 23 is arranged on the sorting rack 21, and the mounting frame 23 is arranged above the conveying guide rail 3;

the sorting camera 24 is arranged on the mounting frame 23, the sorting camera 24 is arranged right above the conveying guide rail 3, and the sorting camera 24 is used for shooting elements to screen the elements;

and a pushing component is arranged on the sorting frame 21 and is used for pushing the components which do not pass through screening to the upper material assembly 1.

Specifically, the sorting camera 24 is transmitted to a sorting device for sorting, the sorting camera 24 is used for shooting elements, and the pushing component is used for pushing the elements which do not pass through the screening to the feeding assembly 1, so that the feeding resistor elements can be rapidly screened, the accuracy of the fed resistor elements is ensured, and the subsequent processing efficiency is ensured.

In one embodiment of the utility model, the pushing component comprises a blowing pipe 25, the blowing pipe 25 is connected with the sorting frame 21 through a bracket, the blowing pipe 25 is arranged opposite to the conveying guide rail 3, and the blowing pipe 25 blows the elements on the conveying guide rail 3 to enable the elements to be blanked onto the feeding assembly 1.

In one embodiment of the present utility model, a blanking notch 31 is disposed on the conveying rail 3, the blanking notch 31 is disposed on a side wall of the conveying rail 3 near the feeding assembly 1, and the pushing component pushes the element on the conveying rail 3 from the feeding notch to the feeding assembly 1.

Specifically, if the surface of the element having the print is directed upward, the air blowing pipe 25 blows air to the element on the conveying rail 3, and the element is blanked into the vibration plate 11 from the feeding notch. If the surface of the element with the printing is downward, the sample can safely enter the conveying guide rail 3, the pushing component pushes the element on the conveying guide rail 3 from the feeding notch to the feeding assembly 1, and then the screening and the transmission of the element can be completed, and the device is simple in structure and low in cost.

In one embodiment of the present utility model, the feeding assembly 1 includes a feeding frame, a vibration plate 11 is disposed on the feeding frame, a discharging rail 12 is disposed on the vibration plate 11, the discharging rail 12 is connected with the conveying guide rail 3, and the vibration plate 11 conveys the components onto the conveying guide rail 3 one by one.

Specifically, the resistor element is placed in the vibration disc 11, the resistor sample is conveyed to the joint of the conveying guide rail 3 and the vibration disc 11 one by one through the vibration disc 11, the problems of low element feeding speed, unstable feeding, clamping and the like one by one are solved, the rapid and stable feeding of materials is realized, and the working efficiency of the equipment is improved.

In one embodiment of the present utility model, the marking assembly 4 includes a support frame, on which a laser marking machine is disposed, and a laser head 41 of the marking machine is disposed directly above the conveying rail 3, and the marking machine prints serial numbers on the components on the conveying rail 3.

Specifically, the marking machine carries out serial number printing on the elements on the conveying guide rail 3, namely, samples are conveyed to the laser marking machine through the conveying guide rail 3 for serial number printing, and the resistor elements which are fed are printed and labeled one by one, so that the problem that workers mark one by one is solved, the marking efficiency is accelerated, and the labor burden of the workers is reduced.

In one embodiment of the present utility model, the detection assembly includes a detection frame 5, a resistance value detector 51 is disposed on the detection frame 5, a test head 52 is disposed on the resistance value detector 51, a detection probe 53 is disposed on the test head 52, the detection probe 53 is disposed directly above the conveying rail 3, and the test head 52 drives the detection probe 53 to contact with the component to implement resistance value detection of the component.

Specifically, after printing, the sample is continuously conveyed to the resistance value detector 51 through the conveying guide rail 3 for resistance value detection, the test head 52 drives the detection probe 53 to be in contact with the element for realizing resistance value detection of the element, the precision of the resistor is ensured to meet the precision requirement, and the resistance value detector is simple in structure and high in practicability.

In one embodiment of the utility model, the receiving assembly comprises a receiving rack 61, a material box 6 for loading components is arranged on the receiving rack 61, a discharging end of the conveying guide rail 3 is arranged above an opening 62 of the material box 6, and the components on the conveying guide rail 3 are blanked into the material box 6 through the discharging end.

Specifically, the components on the conveying guide rail 3 are blanked into the material box 6 through the discharge end, and the samples with the resistance value detection completed can be continuously conveyed to the material box 6 by the conveying guide rail 3 for recycling, so that the working efficiency is high, the labor hour and the manpower investment are less, the cost is low, and the production efficiency is high.

In one embodiment of the present utility model, the device further comprises a supporting frame, the conveying guide rail 3 is arranged on the supporting frame, the supporting frame comprises a base 7, the base 7 is arranged right below the marking assembly 4 or the detecting assembly, an adjusting seat is arranged on the base 7, and the conveying guide rail 3 is arranged on the adjusting seat.

Specifically, the conveying guide rail 3 is connected with the base 7 through the adjusting seat, and the height of the conveying guide rail 3 is adjusted through the adjusting seat, so that the safety and stability of the height adjusting process are effectively improved, and convenience is brought to the use under different working conditions.

In one embodiment of the present utility model, the adjusting seat comprises an adjusting plate 71, a cushion block 72 is arranged on the adjusting plate 71, the conveying guide rail 3 is arranged on the cushion block 72, adjusting screws 73 are arranged at four corners of the adjusting plate 71, screw holes matched with the adjusting screws 73 are arranged on the base 7, the adjusting screws 73 are connected with the screw holes on the base 7, and the relative position between the adjusting plate 71 and the base 7 is adjusted by rotating the adjusting screws 73.

Specifically, the rotation adjusting screw 73 adjusts the screwing depth of the adjusting screw 73 and the screw hole, so that the heights of four corners of the adjusting plate 71 are adjusted, the conveying guide rail 3 on the cushion block 72 is convenient for conveying elements, the height adjustment is realized, the whole height adjustment process can be realized through simple operation, the height adjustment can be completed in a short time, and the height adjustment efficiency is improved.

The using process comprises the following steps:

the resistor element is placed in the vibration disc 11, the resistor sample is conveyed to the joint of the conveying guide rail 3 and the vibration disc 11 one by one through the vibration disc 11, the resistor sample is conveyed to the sorting device of the sorting camera 24 for sorting, the sorting camera 24 is used for shooting the element, if the element is printed, the element on the conveying guide rail 3 is blown by the blowing pipe 25, and the element is blanked into the vibration disc 11 from the feeding notch. If the printed surface of the element is directed downward, the sample can pass through the conveyor rail 3 without any problem.

The sample is transported to the laser marking machine through the transport guide rail 3 for serial number printing, after printing, the sample is continuously transported to the resistance value detector 51 through the transport guide rail 3 for resistance value detection, and the test head 52 drives the detection probe 53 to be in contact with the element for realizing resistance value detection of the element.

Finally, the sample with the resistance value detected is continuously conveyed to the material box 6 by the conveying guide rail 3 for recycling. At the moment, serial numbers are marked on the sample resistor, so that the functions of integrating serial number marking and resistance detection are realized.

When the resistance value detector 51 detects the resistance value, the device synchronously generates and records detection data when detecting the resistance value, the related data is stored in the terminal computer, and a list is automatically generated by a PLC program so as to facilitate subsequent turning and reading and data export.

The above-described embodiments are merely preferred embodiments for fully explaining the present utility model, and the scope of the present utility model is not limited thereto. Equivalent substitutions and modifications will occur to those skilled in the art based on the present utility model, and are intended to be within the scope of the present utility model. The protection scope of the utility model is subject to the claims.

Claims (10)

1. An automatic printing resistor-measuring machine, comprising:

the feeding assembly is used for conveying the elements to the conveying guide rail one by one;

the marking assembly is arranged on one side of the conveying guide rail and is used for marking the elements on the conveying guide rail;

the detection assembly is arranged on one side of the conveying guide rail and is used for detecting the resistance value of the element after marking;

the material receiving assembly is arranged at the discharge end of the conveying guide rail and is used for loading the element for finishing resistance detection;

the sorting assembly is arranged at the joint of the feeding assembly and the conveying guide rail and is used for screening elements on the conveying guide rail.

2. The automatic printing resistor measuring machine of claim 1, wherein the sorting assembly comprises:

the sorting frame is provided with a mounting frame, and the mounting frame is arranged above the conveying guide rail;

the sorting camera is arranged on the mounting frame, is arranged right above the conveying guide rail and is used for shooting elements to screen the elements;

and the pushing component is arranged on the sorting frame and is used for pushing the elements which do not pass through screening to the upper material assembly.

3. The automatic printing and resistance measuring machine according to claim 2, wherein the pushing component comprises an air blowing pipe, the air blowing pipe is connected with the sorting frame through a bracket, the air blowing pipe is arranged opposite to the conveying guide rail, and the air blowing pipe blows the elements on the conveying guide rail to enable the elements to be blanked onto the feeding assembly.

4. The automatic printing resistor-measuring machine according to claim 3, wherein the conveying guide rail is provided with a blanking notch, the blanking notch is arranged on the side wall of the conveying guide rail, which is close to the feeding assembly, and the pushing component pushes the element on the conveying guide rail from the blanking notch to the feeding assembly.

5. The automatic printing resistor-measuring machine according to claim 1, wherein the feeding assembly comprises a feeding frame, a vibration plate is arranged on the feeding frame, a discharging track is arranged on the vibration plate, the discharging track is connected with the conveying guide rail, and the vibration plate conveys the components onto the conveying guide rail one by one.

6. The automatic printing resistor-measuring machine according to claim 1, wherein the marking assembly comprises a supporting frame, a laser marking machine is arranged on the supporting frame, a laser head of the marking machine is arranged right above the conveying guide rail, and the marking machine prints serial numbers on elements on the conveying guide rail.

7. The automatic printing resistor-measuring machine according to claim 1, wherein the detecting assembly comprises a detecting frame, a resistor-measuring machine is arranged on the detecting frame, a testing head is arranged on the resistor-measuring machine, a detecting probe is arranged on the testing head, the detecting probe is arranged right above the conveying guide rail, and the testing head drives the detecting probe to be in contact with the element so as to realize the resistor-measuring of the element.

8. The automatic printing resistor-measuring machine according to claim 1, wherein the material receiving assembly comprises a material receiving frame, a material box for loading elements is arranged on the material receiving frame, the material outlet end of the conveying guide rail is arranged above an opening of the material box, and the elements on the conveying guide rail are blanked into the material box through the material outlet end.

9. The automatic printing resistor-measuring machine of claim 1, further comprising a support frame, wherein the conveying guide rail is arranged on the support frame, the support frame comprises a base, the base is arranged right below the marking assembly or the detecting assembly, an adjusting seat is arranged on the base, and the conveying guide rail is arranged on the adjusting seat.

10. The automatic printing resistor-measuring machine according to claim 9, wherein the adjusting seat comprises an adjusting plate, a cushion block is arranged on the adjusting plate, the conveying guide rail is arranged on the cushion block, adjusting screws are arranged at four corners of the adjusting plate, screw holes matched with the adjusting screws are formed in the base, the adjusting screws are connected with the screw holes in the base, and the relative position between the adjusting plate and the base is adjusted by rotating the adjusting screws.