CN213727943U - Full-automatic aluminum electrolytic capacitor power connection testing device - Google Patents

Abstract

The utility model discloses a full-automatic aluminium electrolytic capacitor connects electric testing arrangement, it is equipped with the conveyer belt to rotate on its base, is equipped with a plurality of support cups on the conveyer belt. The top of the base is sequentially provided with a feeding chute, an electrode correcting mechanism, a power connection mechanism and a sorting mechanism along the transmission direction of the conveyor belt. The feeding chute is positioned above the conveyor belt, and the discharge end of the feeding chute faces the support cup. The aluminum electrolytic capacitor slides into the support cup through the feeding chute, and the conveyor belt drives the support cup and the aluminum electrolytic capacitor to sequentially flow through the lower parts of the electrode correcting mechanism, the power connection mechanism and the sorting mechanism. The base is also provided with a control computer, and the electrode correcting mechanism, the power connection mechanism and the sorting mechanism are all in signal connection with the control computer. The utility model has the advantages that: the device can realize automatic power connection test after the positive and negative electrodes of the aluminum electrolytic capacitor are restored, and the aluminum electrolytic capacitor is not easy to fall down in the supporting cup, thereby greatly reducing the shutdown failure rate. The automation degree is high, and the testing efficiency is greatly improved.

Description

Full-automatic aluminum electrolytic capacitor power connection testing device

Technical Field

The utility model relates to a capacitor testing arrangement's technical field, in particular to full-automatic aluminium electrolytic capacitor connects electric testing arrangement.

Background

The aluminum electrolytic capacitor has an electrolyte material for storing charges inside, has positive and negative polarities, is similar to a battery, and cannot be connected reversely. The aluminum electrolytic capacitor needs to be subjected to an electric connection test in the production process so as to select a qualified aluminum electrolytic capacitor. Most of the existing aluminum electrolytic capacitors are manually placed on a test seat one by one for testing when being subjected to power connection testing, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

To the problem that prior art exists, the utility model aims at providing a full-automatic aluminium electrolytic capacitor connects electric testing arrangement, aims at solving the current problem that adopts the manual work to carry out the test efficiency ratio lowly one by one a pair of aluminium electrolytic capacitor.

In order to achieve the above object, the utility model provides a full-automatic aluminium electrolytic capacitor connects electric testing arrangement, include: the base is rotatably provided with a conveying belt, and the conveying belt is provided with a plurality of support cups. The top of the base is sequentially provided with a feeding chute, an electrode correcting mechanism, a power connection mechanism and a sorting mechanism along the transmission direction of the conveyor belt. The feeding chute is positioned above the conveyor belt, and the discharge end of the feeding chute faces the support cup. The aluminum electrolytic capacitor slides into the support cup through the feeding chute, and the conveyor belt drives the support cup and the aluminum electrolytic capacitor to sequentially flow through the lower parts of the electrode correcting mechanism, the power connection mechanism and the sorting mechanism. The base is also provided with a control computer, and the electrode correcting mechanism, the power connection mechanism and the sorting mechanism are all in signal connection with the control computer.

Preferably, the conveyor belt is a steel belt, and the plurality of support cups are fixed on the steel belt.

Preferably, the feeding chute is fixed on the base by two brackets.

Preferably, the electrode-righting mechanism comprises: the device comprises a first portal frame, a camera, a correcting cylinder, a correcting motor and a correcting plate. The first portal frame is fixed on the base and stretches across the conveyor belt. The camera is arranged on the top of the first portal frame. The correcting cylinder and the correcting motor are both arranged at the top of the first gantry frame, and a piston rod of the correcting cylinder and an output shaft of the correcting motor face the conveyor belt. The return plate is rotatably arranged at the bottom of a piston rod of the return cylinder, and an output shaft of the return motor is in transmission connection with the return plate through a gear. The camera, the correcting cylinder and the correcting motor are all in signal connection with the control computer.

Preferably, the bottom of the correcting plate is provided with a circular arc chamfer.

Preferably, the power connection mechanism comprises: the second portal frame, connect electric cylinder and connect the torch. The second portal frame is fixed on the base and stretches across the conveyor belt. The electricity connection cylinder is arranged at the top of the second portal frame, and a piston rod of the electricity connection cylinder faces the conveyor belt. The electric torch is arranged at the bottom of the piston rod of the electric connection cylinder towards the conveyor belt, and the electric connection cylinder and the electric torch are connected with the control computer through signals.

Preferably, the sorting mechanism comprises: rodless cylinder, sorting cylinder and clamping jaw. The rodless cylinder is fixed on the second portal frame, and a sliding block of the rodless cylinder faces the conveyor belt. The sorting cylinder is fixed on the sliding block of the rodless cylinder, and the piston rod of the sorting cylinder faces the conveyor belt. The clamping jaw is fixed at the bottom of a piston rod of the sorting cylinder. The rodless cylinder, the sorting cylinder and the clamping jaw are connected with a control computer through signals.

Compared with the prior art, the beneficial effects of the utility model reside in that: the device can realize automatic power connection test after the positive and negative electrodes of the aluminum electrolytic capacitor are restored, and the aluminum electrolytic capacitor is not easy to fall down in the supporting cup, thereby greatly reducing the shutdown failure rate. The automation degree is high, and the testing efficiency is greatly improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic view of an overall structure of an embodiment of the present invention;

fig. 2 is a schematic view of another overall structure of an embodiment of the present invention;

fig. 3 is a schematic view of the principle of the aluminum electrolytic capacitor electrode righting by the righting plate in one embodiment of the present invention;

the purpose of the present invention is to provide a novel and improved method and apparatus for operating a computer.

Detailed Description

The utility model provides a full-automatic aluminium electrolytic capacitor connects electric testing arrangement.

Referring to fig. 1-3, fig. 1 is a schematic diagram of an overall structure of an embodiment of the present invention, fig. 2 is a schematic diagram of another overall structure of an embodiment of the present invention, and fig. 3 is a schematic diagram of a principle of restoring a restoring plate to an electrode of an aluminum electrolytic capacitor according to an embodiment of the present invention.

As shown in fig. 1-2, in the embodiment of the present invention, the full-automatic electrical connection testing apparatus for aluminum electrolytic capacitors includes: the base 100, the base 100 is provided with a conveyor belt 200 in a rotating manner, and the conveyor belt 200 is provided with a plurality of cups 210 (the number of the cups 210 in the figure is only used for illustration, the whole number is not shown on the conveyor belt 200, and it should be understood that the cups 210 are provided on the whole circumference of the conveyor belt 200).

Specifically, in this embodiment, the conveyor belt 200 is a steel belt, and the plurality of cups 210 are fixed to the steel belt. The retainer cup 210 may be conveniently fixed by using a steel band.

The top of the base 100 is sequentially provided with a feeding chute 300, an electrode return mechanism 400, an electricity connection mechanism 500 and a sorting mechanism 600 along the conveying direction of the conveyor belt 200.

The feeding chute 300 is fixed to the base 100 by two brackets 310 having different heights, the feeding chute 300 is positioned above the conveyor belt 200, and the discharging end of the feeding chute 300 faces the saucer 210. The aluminum electrolytic capacitor 700 is slid into the loading chute 300 by an external robot or an external conveyor belt or manually, and finally slid into the tray 210 from the discharge end of the loading chute 300.

After the aluminum electrolytic capacitor 700 is slid into the cup holder 210, the conveyor 200 drives the cup holder 210 and the aluminum electrolytic capacitor 700 to flow in sequence from the lower side of the electrode return mechanism 400, the power connection mechanism 500, and the sorting mechanism 600.

The base 100 is further provided with a control computer 110, the electrode reforming mechanism 400, the power connection mechanism 500 and the sorting mechanism 600 are in signal connection with the control computer 110, and when the aluminum electrolytic capacitor 700 moves to the lower side of the electrode reforming mechanism 400 along with the cup holder 210, the control computer 110 controls the electrode reforming mechanism 400 to reform positive and negative electrodes of the aluminum electrolytic capacitor 700, so that the positive and negative electrodes of the aluminum electrolytic capacitor 700 rotate to the power connection test position. When the aluminum electrolytic capacitor 700 after electrode reforming moves to the lower side of the power connection mechanism 500 along with the cup holder 210, the control computer 110 controls the power connection mechanism 500 to perform power connection test on the aluminum electrolytic capacitor 700, judges whether the test result is qualified, feeds the test result back to the control computer 110, and the control computer 110 receives and displays the test result. When the aluminum electrolytic capacitor 700 after the electrical connection test moves to the lower side of the sorting mechanism 600 along with the cup holder 210, the control computer 110 controls the sorting mechanism 600 to sort the qualified products into the external qualified product boxes (not shown), and sort the defective products into the external defective product boxes (not shown).

The electrode-righting mechanism 400 includes: a first gantry 410, a camera 420, a reforming cylinder 430, a reforming motor 440, and a reforming plate 450. The first gantry 410 is fixed to the base 100, and the first gantry 410 spans the conveyor belt 200. The camera 420 is disposed on top of the first gantry 410. The correcting cylinder 430 and the correcting motor 440 are both arranged at the top of the first portal frame 410, and the piston rod of the correcting cylinder 430 and the output shaft of the correcting motor 440 are both towards the conveyor belt 200. The correcting plate 450 is rotatably arranged at the bottom of the piston rod of the correcting cylinder 430, and an output shaft of the correcting motor 440 is in transmission connection with the correcting plate 450 through a gear 441. The camera 420, the correcting cylinder 430 and the correcting motor 440 are all in signal connection with the control computer 110.

When the aluminum electrolytic capacitor 700 moves below the camera 420 together with the cup holder 210, the camera 420 photographs and records the positions of the positive and negative electrodes of the aluminum electrolytic capacitor 700, and feeds back the recorded position information to the control computer 110. The aluminum electrolytic capacitor 700 continues to move to the position under the return plate 450 along with the cup holder 210, when the positions of the positive and negative electrodes of the aluminum electrolytic capacitor 700 recorded by the camera 420 are not at the power connection test position, the control computer 110 controls the return cylinder 430 to drive the return plate 450 to move downwards to the position between the positive and negative electrodes of the aluminum electrolytic capacitor 700 shown in fig. 3, and the control computer 110 controls the return motor 440 to drive the return plate 450 to rotate according to the position information, so that the positive and negative electrodes of the aluminum electrolytic capacitor 700 rotate to the power connection test position shown in fig. 3.

Specifically, in the present embodiment, in order to prevent the aligning plate 450 from pressing against the tops of the positive and negative electrodes of the aluminum electrolytic capacitor 700 when moving downward between the positive and negative electrodes of the aluminum electrolytic capacitor 700, the bottom of the aligning plate 450 is provided with an arc chamfer 451.

The power connection mechanism 500 includes: a second gantry 510, a power connection cylinder 520 and a power connection canister 530. The second gantry 510 is fixed to the base 100, and the second gantry 510 spans the conveyor belt 200. The electrifying cylinder 520 is arranged at the top of the second gantry 510, and the piston rod of the electrifying cylinder 520 faces the conveyor belt 200. The electric torch 530 is arranged at the bottom of the piston rod of the electric cylinder 520 facing the conveyor belt 200, and the electric cylinder 520 and the electric torch 530 are in signal connection with the control computer 110.

When the aluminum electrolytic capacitor 700 after electrode alignment moves to the position right below the electric torch 530 along with the cup holder 210, the control computer 110 controls the electric torch 520 to drive the electric torch 530 to move downwards to the positive and negative electric connection holes in the electric torch 530 to be respectively in contact with the positive and negative electrodes of the aluminum electrolytic capacitor 700 for conduction, so that the electric connection test is realized, and the electric connection test result is fed back to the control computer 110.

The sorting mechanism 600 includes: rodless cylinder 610, sort cylinder 620 and gripper 630. The rodless cylinder 610 is fixed to the second gantry 510 with the slider of the rodless cylinder 610 facing the conveyor belt 200. The sorting cylinder 620 is fixed to the slider of the rodless cylinder 610, and the piston rod of the sorting cylinder 620 faces the conveyor belt 200. The gripping jaw 630 is fixed to the bottom of the piston rod of the sorting cylinder 620. The rodless cylinder 610, the sorting cylinder 620 and the clamping jaw 630 are in signal connection with the control computer 110.

When the aluminum electrolytic capacitor 700 after the power connection test moves to the lower part of the rodless cylinder 610 along with the cup holder 210, the control computer 110 firstly controls the rodless cylinder 610 to drive the sorting cylinder 620 and the clamping jaw 630 to move together to the right above the aluminum electrolytic capacitor 700, then controls the sorting cylinder 620 to move downwards to the upper end of the aluminum electrolytic capacitor 700 to be placed in the clamping jaw 630, then controls the clamping jaw 630 to clamp, then controls the sorting cylinder 620 to move upwards to the aluminum electrolytic capacitor 700 to be separated from the cup holder 210, and then controls the rodless cylinder 610 to drive the sorting cylinder 620 and the clamping jaw 630 to move together to a qualified product box (not shown in the figure) or a defective product box (not shown in the figure) at two sides of the base 100 according to the power connection test result, and releases the clamping jaw 630, so that the aluminum electrolytic capacitor 700 falls into the qualified product box or the defective product box, and the automatic sorting is completed. For clarity and simplicity of the drawing, the clamping jaw 630 is shown for illustration only, and it should be understood that the clamping jaw 630 may be a conventional cylinder-type clamping jaw, or other conventional clamping jaws.

Compared with the prior art, the beneficial effects of the utility model reside in that: the device can realize automatic power connection test after the positive and negative electrodes of the aluminum electrolytic capacitor 700 are restored, and the aluminum electrolytic capacitor 700 is not easy to fall down in the holding cup 210, thereby greatly reducing the shutdown failure rate. The automation degree is high, and the testing efficiency is greatly improved.

The above only be the preferred embodiment of the utility model discloses a not consequently restriction the utility model discloses a patent range, all are in the utility model discloses a conceive, utilize the equivalent structure transform of what the content was done in the description and the attached drawing, or direct/indirect application all is included in other relevant technical field the utility model discloses a patent protection within range.

Claims (7)

1. A full-automatic aluminum electrolytic capacitor connects electric testing arrangement which characterized in that includes: the conveying belt is arranged on the base in a rotating mode, and a plurality of support cups are arranged on the conveying belt; the top of the base is sequentially provided with a feeding chute, an electrode correcting mechanism, a power connection mechanism and a sorting mechanism along the transmission direction of the conveyor belt; the feeding chute is positioned above the conveyor belt, and the discharge end of the feeding chute faces the support cup; the aluminum electrolytic capacitor slides into the support cup through the feeding chute, the conveyor belt drives the support cup and the aluminum electrolytic capacitor to sequentially flow through the electrode correcting mechanism, the power connection mechanism and the sorting mechanism together, the base is further provided with a control computer, and the electrode correcting mechanism, the power connection mechanism and the sorting mechanism are in signal connection with the control computer.

2. The full-automatic electrical connection testing device for the aluminum electrolytic capacitor as recited in claim 1, wherein the conveyor belt is a steel belt, and the plurality of the support cups are fixed on the steel belt.

3. The full-automatic electrical connection testing device for aluminum electrolytic capacitors as claimed in claim 1, wherein the feeding chute is fixed on the base by two brackets.

4. The full-automatic electrical connection testing device for aluminum electrolytic capacitors according to claim 1, wherein the electrode righting mechanism comprises: the system comprises a first portal frame, a camera, a correcting cylinder, a correcting motor and a correcting plate; the first portal frame is fixed on the base and spans across the conveyor belt; the camera is arranged at the top of the first portal frame; the correcting cylinder and the correcting motor are both arranged at the top of the first gantry, and a piston rod of the correcting cylinder and an output shaft of the correcting motor face the conveyor belt; the correcting plate is rotatably arranged at the bottom of a piston rod of the correcting cylinder, and an output shaft of the correcting motor is in transmission connection with the correcting plate through a gear; the camera, the correcting cylinder and the correcting motor are in signal connection with the control computer.

5. The full-automatic aluminum electrolytic capacitor power connection testing device as recited in claim 4, wherein the bottom of the righting plate is provided with a circular arc chamfer.

6. The full-automatic aluminum electrolytic capacitor power connection testing device according to claim 1, wherein the power connection mechanism comprises: the second portal frame, the power connection cylinder and the power connection flashlight are arranged on the first portal frame; the second portal frame is fixed on the base and spans across the conveyor belt; the power connection cylinder is arranged at the top of the second portal frame, and a piston rod of the power connection cylinder faces the conveyor belt; the electric connection cylinder and the electric connection torch are connected with the control computer through signals.

7. The full-automatic electrical connection testing device for aluminum electrolytic capacitors according to claim 6, wherein the sorting mechanism comprises: a rodless cylinder, a sorting cylinder and a clamping jaw; the rodless cylinder is fixed on the second portal frame, and a sliding block of the rodless cylinder faces the conveyor belt; the sorting cylinder is fixed on a sliding block of the rodless cylinder, and a piston rod of the sorting cylinder faces the conveyor belt; the clamping jaw is fixed at the bottom of a piston rod of the sorting cylinder; the rodless cylinder, the sorting cylinder and the clamping jaw are in signal connection with the control computer.

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