CN220961709U - Testing mechanism of automatic capacitance detection equipment - Google Patents

Abstract

The utility model provides a testing mechanism of automatic capacitance detection equipment, which comprises a lifting material placing module arranged on a workbench, wherein the material placing module comprises a plurality of independent material placing blocks, the material placing blocks are arranged in a spaced mode, one end of the material placing module is provided with a detection module, the detection module comprises a detection control device and a plurality of independent detection units capable of horizontally moving, the detection units are arranged in a spaced mode, the positions of the detection units correspond to the positions of the material placing blocks, and the detection units are respectively electrically connected with the detection control device. The mutual detection of the capacitors can not be interfered, the whole capacitor test is completed in a few seconds, the whole detection process is completed automatically, the detection efficiency and the detection accuracy are very high, and the detection accuracy and the detection efficiency are ensured as the capacitors are tested simultaneously.

Description

Testing mechanism of automatic capacitance detection equipment

Technical Field

The utility model relates to detection equipment, in particular to a test mechanism of automatic capacitance detection equipment.

Background

The utility model patent of CN116475087A discloses an automatic small-capacitor full-size detector, which adopts the technical scheme that the capacitors are automatically detected one by one so as to ensure the detection accuracy, but in the technical scheme, the capacitors are continuously detected one by one, so that the detection efficiency is lower and the detector cannot be applied to large-scale detection.

Disclosure of utility model

In order to solve the problems, the application provides a testing mechanism of automatic capacitance detection equipment, which comprises a lifting material placing module arranged on a workbench, wherein the material placing module comprises a plurality of independent material placing blocks, the material placing blocks are arranged at intervals, one end of the material placing module is provided with a detection module, the detection module comprises a detection control device and a plurality of independent horizontally movable detection units, the detection units are arranged at intervals, the positions of the detection units correspond to the positions of the material placing blocks one by one, and the detection units are respectively electrically connected with the detection control device.

Furthermore, the material placing blocks are connected in series by the first connecting rods, the two ends of the first connecting rods are provided with first lifting mechanisms, and the first lifting mechanisms drive the first connecting rods to lift.

Further, the detection unit includes first detection tool and the second detection tool of setting in first detection tool top, be provided with the wire connecting hole on first detection tool and the second detection tool, a plurality of independent detection unit carries out one-to-one electric connection through the wire connecting hole with detection controlling means respectively, the second detection tool is established ties each other through the second connecting rod the both ends of second connecting rod are provided with second elevating system, second elevating system drives the second connecting rod and carries out elevating system the bottom of detection unit is provided with first horizontal migration mechanism.

Further, a pushing mechanism is arranged at the other end of the material placing module, the pushing mechanism comprises a pushing rod and pushing blocks arranged at the bottom of the pushing rod, the arrangement direction of the pushing rod is parallel to the arrangement direction of the material placing blocks, the pushing blocks are arranged on the upper parts of the material placing blocks and correspond to the positions of the material placing blocks one by one, and a second horizontal moving structure is arranged at the bottom of the pushing rod.

Furthermore, the first lifting mechanism comprises a first lifting cylinder arranged at the bottom of the workbench, a first connecting block is fixed at the driving end of the first lifting cylinder, the first connecting blocks are respectively connected with two ends of the first connecting rod, the second lifting mechanism comprises a second lifting cylinder at the upper part of the workbench, a second connecting block is fixed at the driving end of the second lifting cylinder, and the second connecting blocks are respectively connected with two ends of the second connecting rod.

Further, the first horizontal movement mechanism comprises a first horizontal pushing cylinder arranged at the bottom of the workbench, a first connecting plate is connected to the driving end of the first horizontal pushing cylinder, the first connecting plate is of an L shape, the first connecting plate is fixedly connected with the bottom of the detection unit, a sliding block is arranged at the bottom of the first connecting plate, a sliding rail matched with the sliding block is arranged on the workbench, the second horizontal movement mechanism comprises a second horizontal pushing cylinder arranged at the bottom of the workbench, and the driving end of the second horizontal pushing cylinder is connected with the pushing rod.

Furthermore, a sorting module is arranged on one side of the detection module, the sorting module comprises a sorting conveyor belt arranged on the other side of the detection module, a guide rail is horizontally arranged above the sorting conveyor belt, and a sorting conveying mechanism is arranged on the guide rail.

Further, the sorting conveyor is divided into a number of sorting channels.

Further, the sorting and carrying mechanism comprises a connecting seat arranged on the guide rail, a second connecting plate is arranged at the bottom of the connection, a third lifting cylinder is arranged on the second connecting plate, the driving end of the third lifting cylinder faces downwards and is fixedly provided with a support, and a plurality of suckers are arranged on the support.

Furthermore, a fourth lifting cylinder is further arranged at the bottom of the connecting seat, a driving end of the third lifting cylinder faces downwards, a third connecting rod is arranged at the tail end of the third lifting cylinder, a plurality of connecting frames which are arranged at intervals are arranged on the third connecting rod, the arrangement direction of the connecting frames corresponds to the same positions of the material placing blocks one by one, and suction cups are arranged at the bottom of the connecting frames.

Compared with the prior art, the utility model has the beneficial effects that:

The detection units are independent and are respectively connected with the detection control device one by one, so that the mutual detection of the capacitors can not be interfered, the whole capacitor is usually tested in a few seconds, the whole detection process is automatically finished, the detection efficiency and the detection accuracy are very high, and the detection accuracy is ensured while the detection efficiency is ensured due to the fact that the detection is simultaneously carried out by the capacitors.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of a test mechanism of the automatic capacitance detection device of the present utility model;

FIG. 2 is a schematic diagram of a material placing module of a testing mechanism of the automatic capacitance detecting device according to the present utility model;

FIG. 3 is a schematic structural diagram of a detection module of a testing mechanism of the automatic capacitance detection device of the present utility model;

FIG. 4 is a schematic diagram of another preferred embodiment of a test mechanism of the automatic capacitance detection apparatus of the present utility model;

FIG. 5 is a schematic diagram of a sorting module of a test mechanism of the automatic capacitance detection device;

Fig. 6 is a schematic view of another angle of the sorting module of the testing mechanism of the automatic capacitance detecting device.

Reference numerals and names in the drawings are as follows:

the device comprises a workbench 100, a material placing module 200, a material placing block 210, a material placing groove 220, a first connecting rod 230, a first lifting mechanism 240, a detection module 300, a detection control device 320, a detection unit 310, a first detection jig 311, a second detection jig 312, a wire connecting hole 313, a second connecting rod 330, a second lifting mechanism 340, a first horizontal moving mechanism 350, a material pushing mechanism 400, a material pushing rod 410, a material pushing block 420, a second horizontal moving mechanism 430, a first lifting cylinder 241, a first connecting block 242, a second lifting cylinder 341, a second connecting block 342, a first horizontal pushing cylinder 351, a first connecting plate 352, a sliding block 353, a sliding rail 354, a second horizontal pushing cylinder 431, a third connecting plate 432, a sorting module 500, a sorting conveyor 510, a guide rail 520, a sorting conveying mechanism 530, a sorting groove 511, a connecting seat 531, a second connecting plate 532, a third lifting cylinder 533, a bracket 534, a sucker 535, a fourth lifting cylinder 536, a third connecting rod 537, a connecting frame 538, a capacitor 600, and a pole 610.

Detailed Description

The following description of the technical solutions in the embodiments of the present utility model will be clear and complete, and it is obvious that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-3, the testing mechanism of the automatic capacitance detecting device includes a material placing module 200 disposed on a workbench 100, where the material placing module 200 includes a plurality of independent material placing blocks 210, the material placing blocks 210 are arranged at intervals, the material placing blocks 210 are used for placing a capacitance 600 to be tested, preferably, a concave material placing groove 220 is disposed on the material placing, when the capacitance 600 is placed on the material placing groove 220 on the material placing block 210, the capacitance 600 is more easily fixed on the material placing block 210, the material placing blocks 210 are connected in series with each other by a first connecting rod 230, and two ends of the first connecting rod 230 are provided with a first lifting mechanism 240, and the first lifting mechanism 240 can drive the first connecting rod 230 to perform lifting motion, so as to drive the material placing block 210 to perform lifting motion.

The one end of putting material module 200 is provided with detection module 300, detection module 300 includes detection controlling means 320 and a plurality of independent detection unit 310, detection unit 310 presents the interval arrangement setting, detection unit 310's position and the position one-to-one of putting material piece 210, detection unit 310 includes first detection tool 311 and sets up the second detection tool 312 on first detection tool 311, be provided with wire connecting hole 313 on first detection tool 311 and the second detection tool 312, a plurality of independent detection unit 310 carries out one-to-one electric connection through wire connecting hole 313 with detection controlling means 320 respectively, second detection tool 312 is established ties each other through second connecting rod 330 the both ends of second connecting rod 330 are provided with second elevating system 340, second elevating system 340 can drive second connecting rod 330 and go up and down elevating system to move to drive second detection tool 312, second detection tool 312 consequently can cooperate first detection tool 311 to stretch into the article that forms under first detection tool 311 and the upper and lower article that detects between the tool 312. The bottom of the detection unit 310 is provided with a first horizontal movement mechanism 350, the first horizontal movement mechanism 350 can push the detection module 300 to move close to or away from the material placing module 200 relatively, under the initial working state of the embodiment, the first horizontal movement mechanism 350 pushes the detection unit 310 to move away from the material placing module 200, at this time, the capacitors 600 are placed on the material placing blocks 210 of the material placing module 200 one by one, the direction of the pole 610 of the capacitors 600 is aligned with the detection module 300, then the first lifting mechanism 240 is started to lift the material placing blocks 210 to a preset height, at this time, the first horizontal movement mechanism 350 pushes the detection unit 310 to move close to the material placing module 200, so that the pole 610 of the capacitors 600 can extend into between the first detection jig 311 and the second detection jig 312, then the second lifting mechanism 340 drives the second detection jig 312 to move downwards, thereby being capable of matching with the first detection jig 311 to form up-down clamping effect on the pole 610 of the capacitors 600 extending into the first detection jig 311 and the second detection jig 312, and finally, the detection control device 320 is started to lift the detection unit 310 to the preset height, and the whole detection unit is not only can detect the capacitors 600, but also can detect the capacitors 600 accurately and automatically simultaneously, and the whole detection process is completed because of the detection device is controlled by one, and the detection device is connected with the full detection device 600, and the detection efficiency is high, and the detection accuracy is guaranteed, and the detection efficiency is high, and the detection accuracy can be achieved, and the detection accuracy and the detection efficiency can be achieved.

A pushing mechanism 400 is disposed at the other end of the material placing module 200, the pushing machine comprises a pushing rod 410 and pushing blocks 420 disposed at the bottom of the pushing rod 410, the direction of the pushing rod 410 is parallel to the arrangement direction of the material placing modules 210, the pushing blocks 420 are disposed at the upper part of the material placing modules 210 and are in one-to-one correspondence with the positions of the material placing modules 210, a second horizontal moving structure 430 is disposed at the bottom of the pushing rod 410, the second horizontal moving structure 430 can drive the pushing rod 410 to horizontally move, so as to drive the pushing blocks 420 to horizontally move on the material placing grooves 220, when the capacitors 600 are placed on the material placing modules 210 of the material placing modules 200 one by one, the direction of the poles 610 of the capacitors 600 is aligned with the detection modules 300, and then the first horizontal moving mechanism 350 is started to push the detection modules 300 to approach the material placing modules 200, so that the poles 610 of the capacitors 600 extend between the first detection tools 311 and the second detection tools 312, because the position of the capacitor 600 above the placement block 210 may deviate, that is, the position of some of the capacitor 600 may be relatively forward with respect to the placement block 210, and some of the capacitor 600 may be relatively backward, so that the lengths of the electrode posts 610 of the capacitor 600 extending into the space between the first detection jig 311 and the second detection jig 312 are inconsistent, if the position of the capacitor 600 may be relatively backward with respect to the placement block 210, the length angle of the electrode posts 610 of the capacitor 600 extending into the space between the first detection jig 311 and the second detection jig 312 may be caused, so that an uncertain hidden danger may be caused to the power-on detection, when the capacitor 600 is placed on the placement block 210, the electrode posts 610 of the capacitor 600 extend into the space between the first detection jig 311 and the second detection jig 312, at this time, the second horizontal moving device is started to push the pushing rod 410 to move toward the detection module 300, thereby, the pushing block 420 pushes the capacitor 600 on the placing block 210 to move towards the detection module 300, and the length of the pole 610 of the capacitor 600 extending between the first detection jig 311 and the second detection jig 312 is kept constant, so that the detection accuracy is further improved.

The first lifting mechanism 240 includes a first lifting cylinder 241 disposed at the bottom of the workbench 100, a first connecting block 242 is fixed at the driving end of the first lifting cylinder 241, the first connecting blocks 242 are respectively connected at two ends of the first connecting rod 230, when the first lifting cylinder 241 is started, the first connecting block 242 is driven to move up and down, so as to drive the first connecting rod 230 to move up and down, the second lifting mechanism 340 includes a second lifting cylinder 341 on the upper portion of the workbench 100, a second connecting block 342 is fixed at the driving end of the second lifting cylinder 341, the second connecting blocks 342 are respectively connected at two ends of the second connecting rod 330, and when the second lifting cylinder 341 is started, the second connecting block 342 is driven to move up and down, so as to drive the second connecting rod 330 to move up and down.

The first horizontal moving mechanism 350 includes a first horizontal pushing cylinder 351 disposed at the bottom of the workbench 100, a first connection plate 352 is connected to a driving end of the first horizontal pushing cylinder 351, the first connection plate 352 is L-shaped, the first connection plate 352 is fixedly connected to the bottom of the detecting unit 310, a sliding block 353 is disposed at the bottom of the first connection plate 352, a sliding rail 354 matching with the sliding block 353 is disposed on the workbench 100, the sliding block 353 can slide along the sliding rail 354, when the distance between the detecting module 300 and the placing module 200 needs to be adjusted, the first horizontal pushing cylinder 351 is started to drive the sliding block 353 at the bottom of the first connection plate 352 to horizontally move along the sliding rail 354, so as to drive the detecting module 300 to horizontally move, thereby achieving the purpose of adjusting the distance between the detecting module 200, the second horizontal moving structure 430 includes a second horizontal pushing cylinder 431 and a third connection plate 432 disposed at the bottom of the workbench 100, and the driving end of the second horizontal pushing cylinder 431 is connected to the pushing rod 410 through the third connection plate 432, when the second horizontal pushing cylinder 431 is started, the pushing rod 420 can be driven to horizontally move along the sliding rod 354, so as to drive the pushing rod 420 to horizontally move.

As a preferred solution of this embodiment, as shown in fig. 4 to 6, a sorting module 500 may be further disposed on one side of the detecting module 300, where the sorting module 500 includes a sorting conveyor 510 disposed on the other side of the detecting module 300, so that the sorting conveyor 510 and the placement module 200 are disposed on different sides of the detecting module 300, respectively, so that sorting is performed along one direction after the detection of the capacitor 600 is completed, efficiency is improved, a guide rail 520 is transversely disposed above the sorting conveyor 510, a sorting and conveying mechanism 530 is disposed on the guide rail 520, and after the detection module 300 completes the detection of the capacitor 600 on the opposite block 210, the detected block 210 is recorded and uploaded to the detecting control device 320 in a one-to-one manner, and the detecting control device 320 sends an electrical signal to drive the sorting and conveying mechanism 530 to convey the detected block 600 to the sorting conveyor 510, preferably, the sorting conveyor 510 is divided into a plurality of sorting slots 511 for placing the capacitors 600 with defects caused by different problems. The preferred embodiment can enable the capacitor 600 to realize automation in the process of sorting defective products from detection, and the defective product positioning accuracy is better than that of the prior art because the detection mode of the capacitor 600 in the preferred embodiment is one-to-one detection.

The sorting and carrying mechanism 530 comprises a connecting seat 531 arranged on the guide rail 520, the connecting seat 531 can slide along the guide rail 520, a second connecting plate 532 is arranged at the bottom of the connection, a third lifting cylinder 533 is arranged on the second connecting plate 532, the driving end of the third lifting cylinder 533 faces downwards and is fixedly provided with a bracket 534, a plurality of suckers 535 are arranged on the bracket 534, after the detection of the capacitor 600 is completed, the connecting seat 531 firstly moves to the upper side of the detection module 300 along the guide rail 520, the third lifting cylinder 533 is started to drive the bracket 534 to descend to a proper height, the suckers 535 are utilized to absorb defective products of the capacitor 600, then the connecting seat 531 moves to the upper side of the sorting conveyor 510 along the guide rail 520, the third lifting cylinder 533 is started to drive the bracket 534 to descend to a proper height, and the suckers 535 are utilized to place the defective products of the capacitor 600 on the sorting conveyor 510 to complete sorting.

As a preferable solution, a fourth lifting cylinder 536 is further disposed at the bottom of the connection seat 531, the driving end of the third lifting cylinder 533 is downward, a third connection rod 537 is disposed at the end of the third lifting cylinder 533, a plurality of connection frames 538 are disposed on the third connection rod 537, the arrangement direction of the connection frames 538 corresponds to the same position of the material placing block 210 one by one, suction cups 535 are disposed at the bottom of the connection frames 538, after the sorting module 500 sorts out defective products of the capacitor 600 on the material placing block 210, the capacitor 600 staying on the material placing block 210 is the capacitor 600 passing through detection, and the capacitor 600 needs to be carried to the next station for further processing, at this time, the fourth lifting cylinder 536 needs to be started to drive the third connection rod 537 to move downward, the suction cups 535 on the connection frames 538 contact and the capacitor 600 for adsorption, then the fourth lifting cylinder 536 is started to drive the third connection rod 537 to lift up, and then the capacitor 600 moves to the next station through the connection seat 531.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (10)

1. The utility model provides a capacitor automatic detection equipment's accredited testing organization, its characterized in that, including setting up liftable material module (200) on workstation (100), material module (200) are put including a plurality of independent material piece (210) of putting, material piece (210) present interval arrangement setting material module (200) one end is provided with detection module (300), detection module (300) including detection controlling means (320) and a plurality of independent horizontal migration's detecting element (310), detection element (310) present interval arrangement setting, the position of detecting element (310) and the position one-to-one of material piece (210) of putting, detection element (310) are continuous with detection controlling means (320) electricity respectively.

2. The testing mechanism of automatic capacitance detection equipment according to claim 1, wherein the material placing blocks (210) are connected in series by first connecting rods (230), first lifting mechanisms (240) are arranged at two ends of the first connecting rods (230), and the first lifting mechanisms (240) drive the first connecting rods (230) to perform lifting movement.

3. The testing mechanism of automatic capacitance detection equipment according to claim 2, wherein the detection unit (310) comprises a first detection jig (311) and a second detection jig (312) arranged above the first detection jig (311), wire connection holes (313) are formed in the first detection jig (311) and the second detection jig (312), the plurality of independent detection units (310) are respectively and electrically connected with the detection control device (320) one by one through the wire connection holes (313), the second detection jigs (312) are mutually connected in series through second connecting rods (330), second lifting mechanisms (340) are arranged at two ends of the second connecting rods (330), the second lifting mechanisms (340) drive the second connecting rods (330) to perform lifting motion, and first horizontal movement mechanisms (350) are arranged at the bottoms of the detection units (310).

4. A testing mechanism of automatic capacitance detection equipment according to claim 3, wherein a pushing mechanism (400) is arranged at the other end of the material placing module (200), the pushing mechanism (400) comprises a pushing rod (410) and pushing blocks (420) arranged at the bottom of the pushing rod (410), the arrangement direction of the pushing rod (410) is parallel to the arrangement direction of the material placing blocks (210), the pushing blocks (420) are arranged at the upper part of the material placing blocks (210) and are in one-to-one correspondence to the positions of the material placing blocks (210), and a second horizontal moving structure (430) is arranged at the bottom of the pushing rod (410).

5. A testing mechanism of an automatic capacitance detecting device according to claim 3, wherein the first lifting mechanism (240) comprises a first lifting cylinder (241) arranged at the bottom of the workbench (100), a first connecting block (242) is fixed on the driving end of the first lifting cylinder (241), the first connecting block (242) is respectively connected with two ends of the first connecting rod (230), the second lifting mechanism (340) comprises a second lifting cylinder (341) arranged at the upper part of the workbench (100), a second connecting block (342) is fixed on the driving end of the second lifting cylinder (341), and the second connecting block (342) is respectively connected with two ends of the second connecting rod (330).

6. The mechanism for automatically detecting capacitance of claim 4, wherein the first horizontal moving mechanism (350) comprises a first horizontal pushing cylinder (351) arranged at the bottom of the workbench (100), a first connecting plate (352) is connected to the driving end of the first horizontal pushing cylinder (351), the first connecting plate (352) is in an L shape, the first connecting plate (352) is fixedly connected to the bottom of the detecting unit (310), a sliding block (353) is arranged at the bottom of the first connecting plate (352), a sliding rail (354) matched with the sliding block (353) is arranged on the workbench (100), the second horizontal moving mechanism (430) comprises a second horizontal pushing cylinder (431) arranged at the bottom of the workbench (100), and the driving end of the second horizontal pushing cylinder (431) is connected to the pushing rod (410).

7. The test mechanism of an automatic capacitance detection device according to claim 1, wherein a sorting module (500) is arranged on one side of the detection module (300), the sorting module (500) comprises a sorting conveyor belt (510) arranged on the other side of the detection module (300), a guide rail (520) is transversely arranged above the sorting conveyor belt (510), and a sorting carrying mechanism (530) is arranged on the guide rail (520).

8. The capacitive automatic detection device testing mechanism of claim 7, wherein the sorting conveyor (510) is divided into a number of sorting slots (511).

9. The automatic capacitance detection device testing mechanism according to claim 7, wherein the sorting and carrying mechanism (530) comprises a connecting seat (531) arranged on a guide rail (520), a second connecting plate (532) is arranged at the bottom of the connecting seat (531), a third lifting cylinder (533) is mounted on the second connecting plate (532), a support (534) is fixed with a driving end of the third lifting cylinder (533) facing downwards, and a plurality of suckers (535) are arranged on the support (534).

10. The mechanism for automatically detecting the capacitance of the device according to claim 9, wherein a fourth lifting cylinder (536) is further arranged at the bottom of the connecting seat (531), a third connecting rod (537) is arranged at the tail end and downwards at the driving end of the third lifting cylinder (533), a plurality of connecting frames (538) arranged at intervals are arranged on the third connecting rod (537), the arranging directions of the connecting frames (538) are the same as those of the material placing blocks (210) and correspond to the positions of the material placing blocks one by one, and suckers (535) are arranged at the bottom of the connecting frames (538).