CN212069585U - Capacitor material receiving testing device - Google Patents

Abstract

The application provides a material testing arrangement is received to electric capacity, move material mechanism including riser, accredited testing organization, feed mechanism and upset, the upset moves material mechanism and presss from both sides, supports the slide that the upset was pressed from both sides, slides the slideway board that supports the slide, the drive upset presss from both sides along the slideway board and removes the push cylinder of waste material position, support the roating seat of slideway board one end and drive roating seat pivoted rotary mechanism. According to the capacitor receiving test device, the overturning clamp is supported on the sliding plate, the sliding plate is slidably mounted on the sliding plate, the sliding plate is rotatably mounted on the vertical plate through the rotating seat, the rotating mechanism is arranged to drive the rotating seat to rotate, so that the overturning clamp is driven to rotate, and the tested capacitor is overturned and placed in the receiving position; and install the push cylinder on the roating seat, when needs detected scrapping electric capacity, push cylinder can promote the upset to press from both sides and keep away from the riser and remove the electric capacity of losing behind the waste material position to realize scrapping electric capacity letter sorting, avoid occupying space in the sorting device.

Description

Capacitor material receiving testing device

Technical Field

This application belongs to electric capacity test technical field, and more specifically says, relates to a material testing arrangement is received to electric capacity.

Background

The ox horn capacitor is called as ox horn capacitor because it protrudes two pins like ox horn, and it is also called as welding pin type electrolytic capacitor, and is called as snap-in electrolytic capacitors. After the ox horn capacitor is manufactured, various performance tests are required, such as an appearance test, a capacitance value test, a voltage withstanding test, a maximum leakage current test, a loss angle test, a capacitance value error test, a temperature coefficient test, a failure rate test, a working temperature range test and the like. After the capacitors are inserted into the bent frames for static test, the capacitors need to be taken out, the single capacitor is subjected to performance tests such as failure, internal resistance and the like, and then the capacitors are placed into a recovery sorting device for sorting. However, the structure still transfers the rejected capacitors which cannot be recovered and repaired to the sorting device, and occupies space on the sorting device.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the application is to provide a capacitance collecting test device to when solving the capacitance test device that exists among the correlation technique and receiving material, scrap electric capacity and can occupy the problem in sorting device upper space.

In order to achieve the above purpose, the embodiment of the present application adopts the following technical solutions: the utility model provides a material testing arrangement is received to electric capacity, includes the riser, be used for carrying out the accredited testing organization that tests to single electric capacity, be used for transferring electric capacity the upset of electric capacity after the test is placed in receiving the material level the upset moves the material mechanism, accredited testing organization with feed mechanism all supports in on the riser, the upset moves the material mechanism including the upset that is used for centre gripping electric capacity press from both sides, support the slide that the upset pressed from both sides, slide support the slide of slide, drive the upset press from both sides along the push cylinder that the slide moved to the waste material level, support the roating seat of slide one end and drive roating seat pivoted rotary mechanism, the slide with push cylinder links to each other, the roating seat install in on the riser, rotary mechanism supports in on the riser, push cylinder install in on the roating seat.

In one embodiment, the capacitor receiving testing device further comprises a discharging groove for guiding the capacitor to slide down and a supporting rod for supporting the discharging groove, the supporting rod is mounted on the vertical plate, and the discharging groove is arranged below the sliding track plate.

In one embodiment, the rotating mechanism comprises a rotating gear connected with the rotating base, a toothed belt driving the rotating gear to rotate and a tensioning gear matched with the rotating gear and supporting the toothed belt; the capacitor material receiving testing device further comprises a linear mover driving the toothed belt to move transversely, the linear mover is mounted on the vertical plate, and the tensioning gears are rotatably mounted on the vertical plate.

In one embodiment, the pushing cylinder is supported on the rotating gear, the pushing cylinder is located on one surface of the vertical plate, which is far away from the overturning clamp, and an arc-shaped hole for a piston of the pushing cylinder to pass through is formed in the vertical plate.

In one embodiment, the linear mover comprises a transverse screw rod arranged transversely, a transverse nut mounted on the transverse screw rod, and a transverse motor driving the transverse screw rod to rotate, wherein both ends of the transverse screw rod are rotatably supported on the vertical plate, the transverse motor is mounted on the vertical plate, and the transverse nut is fixedly connected with the toothed belt.

In one embodiment, the feeding mechanism comprises a feeding clamp for clamping a capacitor, a feeding seat for supporting the feeding clamp, a sliding block for supporting the feeding seat, a sliding rail for guiding the sliding block to move horizontally, and a connecting rod for connecting the feeding seat and the linear mover, wherein the sliding rail is mounted on the vertical plate, the sliding block is mounted on the sliding rail, and the feeding seat is mounted on the sliding block.

In one embodiment, the testing mechanism comprises a supporting block, conductive clamps respectively arranged on two sides of the supporting block, a clamp opener for driving the two conductive clamps to open and close, a support for supporting the clamp opener, and a lifting mechanism for driving the support to lift, wherein the supporting block is arranged on the support, and the lifting mechanism is arranged on the vertical plate.

In one embodiment, the clip opener comprises two ejector rods for respectively ejecting the two conductive clips, two moving blocks for supporting the two ejector rods, and a clip opening cylinder for driving the two moving blocks to open and close, the clip opening cylinder is mounted on the support, and the support block is located between the two moving blocks.

In one embodiment, the capacitor receiving testing device further comprises a laser coding mechanism, the laser coding mechanism comprises a laser coder for printing an identification code on the tested capacitor, a control clamp for clamping the capacitor and a mounting seat for supporting the control clamp, the mounting seat is supported on the vertical plate, the control clamp is positioned between the testing mechanism and the overturning clamp, and the feeding mechanism spans the testing mechanism and the control clamp.

In one embodiment, the laser coding mechanism further comprises a lifting slider supporting the mounting base, a sliding rail vertically mounted on the vertical plate, a connecting block connected with the mounting base, and a lifter driving the connecting block to lift, wherein the lifter is mounted on the vertical plate.

One or more technical solutions in the embodiments of the present application have at least one of the following technical effects:

according to the capacitor receiving test device provided by the embodiment of the application, the overturning clamp is supported on the sliding plate, the sliding plate is slidably mounted on the sliding plate, the sliding plate is rotatably mounted on the vertical plate through the rotating seat, the rotating mechanism is arranged to drive the rotating seat to rotate, so that the overturning clamp is driven to rotate, and the tested capacitor is overturned and placed in the receiving position; and install the push cylinder on the roating seat, when needs detected scrapping electric capacity, push cylinder can promote the upset to press from both sides and keep away from the riser and remove the electric capacity of losing behind the waste material position to realize scrapping electric capacity letter sorting, avoid occupying space in the sorting device.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or exemplary technical descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a capacitor receiving test device provided in an embodiment of the present application.

Fig. 2 is a schematic partial structure diagram of a capacitor receiving test device provided in the embodiment of the present application.

Fig. 3 is a first structural schematic diagram of the combination of the feeding mechanism, the overturning material moving mechanism and the linear mover in fig. 1.

Fig. 4 is a schematic structural diagram two of the combination of the feeding mechanism, the overturning material moving mechanism and the linear mover in fig. 1.

Fig. 5 is a schematic structural diagram of the testing mechanism in fig. 1.

Fig. 6 is a schematic structural diagram of the laser coding mechanism in fig. 1.

Wherein, in the drawings, the reference numerals are mainly as follows:

100-a capacitor receiving test device;

111-vertical plate; 1111-arc-shaped holes; 112-a blanking groove; 113-a strut;

12-a turning and material moving mechanism; 121-overturning clips; 122-a sled; 123-a slide plate; 124-a rotating seat; 125-push cylinder; 126-a rotation mechanism; 1261-rotating gear; 1262-toothed belt; 1263-tensioning gear;

13-a linear mover; 131-a transverse screw rod; 132-a traverse nut; 133-traverse motor; 134-a belt drive assembly;

14-a feeding mechanism; 141-a feeding clamp; 142-a feeding seat; 143-a sliding block; 144-a sliding rail; 145-connecting rod;

15-a testing mechanism; 151-support block; 152-a conductive clip; 153-clip opener; 1531-a mandrel; 1532-moving block; 1533-unclamping cylinder; 154-a support; 155-linkage; 156-a lifting mechanism; 157-a slider; 158-vertical rail;

16-a laser coding mechanism; 161-laser code printer; 162-control clip; 163-a mount; 164-a connecting block; 165-a lifter; 166-a slide rail; 167-lifting slide block;

91-capacitance.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

Reference throughout this specification to "one embodiment," "some embodiments," or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the present application. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," or the like, in various places throughout this specification are not necessarily all referring to the same embodiment, but rather "one or more but not all embodiments" unless specifically stated otherwise. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

For convenience of description, three coordinate axes which are mutually vertical in space are defined as an X axis, a Y axis and a Z axis respectively, and meanwhile, the direction along the X axis is longitudinal, the direction along the Y axis is transverse, and the direction along the Z axis is vertical; the X axis and the Y axis are two coordinate axes which are vertical to each other on the same horizontal plane, and the Z axis is a coordinate axis in the vertical direction; the X axis, the Y axis and the Z axis are positioned in space and are mutually vertical, and three planes are respectively an XY plane, a YZ plane and an XZ plane, wherein the XY plane is a horizontal plane, the XZ plane and the YZ plane are vertical planes, and the XZ plane is vertical to the YZ plane. Three axes in space are an X axis, a Y axis and a Z axis, and the three-axis movement in space refers to the movement along three axes which are vertical to each other in space, in particular to the movement along the X axis, the Y axis and the Z axis in space; the planar motion is a motion in the XY plane.

Referring to fig. 1 and fig. 2, a capacitor receiving test device 100 provided in the present application will now be described. The capacitor receiving testing device 100 comprises a vertical plate 111, a testing mechanism 15, a feeding mechanism 14 and an overturning and moving mechanism 12, wherein the overturning and moving mechanism 12, the testing mechanism 15 and the feeding mechanism 14 are all supported on the vertical plate 111; the test mechanism 15 is used to test a single capacitor 91. The feeding mechanism 14 is used for transferring the capacitor 91, and the capacitor 91 can be placed in the testing mechanism 15 through the feeding mechanism 14. The overturning and material moving mechanism 12 is used for overturning and placing the tested capacitor 91 at a material receiving position so as to receive materials by the sorting device.

Referring to fig. 3 and 4, the material turning and moving mechanism 12 includes a turning clamp 121, a sliding plate 122, a sliding plate 123, a pushing cylinder 125, a rotating base 124 and a rotating mechanism 126; the flip clip 121 is used to clip the capacitor 91 so as to flip the capacitor 91. The slide plate 122 is connected to the flip clip 121 to support the flip clip 121. The slide plate 122 is slidably mounted on the slide plate 123 such that the slide plate 122 and the flip clip 121 can slide along the slide plate 123. One end of the chute board 123 is connected to the rotary base 124, the chute board 123 is supported by the rotary base 124, and the rotary base 124 is rotatably mounted on the vertical plate 111, so as to drive the chute board 123, the sliding plate 122 and the turning clamp 121 to rotate. The rotating mechanism 126 is supported on the vertical plate 111, and the rotating mechanism 126 is used for driving the rotating base 124 to rotate, so as to drive the turning clamp 121 to rotate. The slide plate 122 is connected to the push cylinder 125 so that the push cylinder 125 pushes the slide plate 122 and the flipping clip 121 to slide along the slide plate 123. The pushing cylinder 125 is installed on the rotary base 124 to support the pushing cylinder 125, and the pushing cylinder 125 drives the overturning clamp 121 to move to the waste position along the sliding plate 123, so as to discard the scrapped capacitor 91.

According to the capacitor material receiving testing device 100 provided by the embodiment of the application, the overturning clamp 121 is supported on the sliding plate 122, the sliding plate 122 is slidably mounted on the sliding plate 123, the sliding plate 123 is rotatably mounted on the vertical plate 111 through the rotating seat 124, and the rotating mechanism 126 is arranged to drive the rotating seat 124 to rotate, so that the overturning clamp 121 is driven to rotate, and the tested capacitor 91 is overturned and placed in the material receiving position; and install push cylinder 125 on roating seat 124, when needing to detect scrapped electric capacity 91, push cylinder 125 can promote upset clamp 121 and keep away from riser 111 and move and lose electric capacity 91 behind the waste material position to realize scrapped electric capacity 91 letter sorting, avoid occupying space in the sorting device.

In one embodiment, referring to fig. 3 and 4, the inversion clamp 121 is a pneumatic clamp. The flip clip 121 may also use a motor clip, a robot, etc. in some embodiments.

In an embodiment, referring to fig. 3 and 4, the capacitor receiving testing device 100 further includes a discharging slot 112 for guiding the capacitor 91 to slide down and a supporting rod 113 for supporting the discharging slot 112, the supporting rod 113 is mounted on the vertical plate 111, and the discharging slot 112 is disposed below the sliding plate 123. When the testing mechanism 15 tests the rejected capacitor 91, the pushing cylinder 125 pushes the overturning clamp 121 to the waste position, so that the capacitor 91 can be thrown into the blanking slot 112 for collection.

In one embodiment, referring to fig. 3 and 4, the rotating mechanism 126 includes a rotating gear 1261 connected to the rotating base 124, a toothed belt 1262 for rotating the rotating gear 1261, and a tensioning gear 1263 for supporting the toothed belt 1262 in cooperation with the rotating gear 1261. The capacitor receiving test device 100 further comprises a linear shifter 13 driving the toothed belt 1262 to move transversely, and the linear shifter 13 is mounted on the vertical plate 111. Each tensioning gear 1263 is rotatably mounted on the vertical plate 111; the linear mover 13 moves the toothed belt 1262 to rotate the rotary gear 1261, and thus the rotary base 124. In some embodiments, the motor may be directly used to drive the rotation seat 124 to rotate. Of course, an air cylinder may be used to drive the rotary base 124 to rotate. In still other embodiments, a rack gear may be used to drive the gear rotation. In still other embodiments, a motor may be used to drive a tensioner to move toothed belt 1262.

In one embodiment, referring to fig. 1 and fig. 2, the pushing cylinder 125 is supported on the rotating gear 1261, the pushing cylinder 125 is located on a surface of the vertical plate 111 away from the flipping clamp 121, and the vertical plate 111 is provided with an arc-shaped hole 1111 for a piston of the pushing cylinder 125 to pass through. The pushing cylinder 125 is disposed on the side of the vertical plate 111 away from the turning clamp 121, so that the number of parts on one side of the turning clamp 121 can be reduced, the layout is convenient, and the weight of two ends of the rotating base 124 is more balanced. Of course, in some embodiments, the push cylinder 125 may be mounted on the chute plate 123. An arc hole 1111 is opened on the vertical plate 111 so as to drive the pushing cylinder 125 to rotate when the rotating gear 1261 rotates.

In one embodiment, referring to fig. 3 and 4, the linear mover 13 includes a transverse screw 131 disposed transversely, a traverse nut 132 mounted on the transverse screw 131, and a traverse motor 133 driving the transverse screw 131 to rotate, two ends of the transverse screw 131 are rotatably supported on the vertical plate 111, the traverse motor 133 is mounted on the vertical plate 111, and the traverse nut 132 is fixedly connected to the toothed belt 1262. By using the feed screw nut mechanism, the movement of the traverse nut 132 can be precisely controlled, and the turning clamp 121 is driven to turn. In some embodiments, the linear mover 13 may use a linear motor, a rack and pinion mechanism, or the like.

In one embodiment, the linear mover 13 further includes a belt driving assembly 134 connecting the traverse motor 133 and the traverse screw 131 to facilitate the position layout of the traverse motor 133, reduce the installation accuracy requirement, and facilitate the assembly.

In one embodiment, the feeding mechanism 14 includes a feeding clamp 141, a feeding seat 142, a sliding block 143, a sliding rail 144 and a connecting rod 145, the feeding clamp 141 is used for clamping the capacitor 91, the sliding rail 144 is installed on the vertical plate 111, the sliding block 143 is installed on the sliding rail 144, the connecting rod 145 connects the feeding seat 142 and the linear mover 13, the feeding seat 142 is connected with the sliding block 143, so that the feeding clamp 141 is supported by the sliding block 143 and the feeding clamp 141 is guided to move along the sliding rail 144; when the linear mover 13 drives the connecting rod 145 to move horizontally, the feeding base 142 and the sliding block 143 are driven to move horizontally, and the feeding clamp 141 is driven to move horizontally, so that the capacitor 91 is transferred after the capacitor 91 is clamped by the feeding clamp 141. In addition, the linear shifter 13 can drive the feeding clamp 141 to horizontally move transversely and simultaneously drive the overturning clamp 121 to synchronously overturn, so that the efficiency is improved, the structure is simplified, and the cost is reduced. Of course, in some embodiments, a linear moving mechanism may be separately provided to drive the feeding clamp 141 to move horizontally. In some embodiments, the feed mechanism 14 may also be a robotic arm.

In one embodiment, referring to fig. 3 and 4, the feeding clamp 141 is a pneumatic clamp. In some embodiments, the flip clip 121 may also use a motor clip or the like.

In one embodiment, referring to fig. 1, 2 and 5, the testing mechanism 15 includes a supporting block 151, conductive clips 152 respectively installed on two sides of the supporting block 151, a clip opener 153 for driving the two conductive clips 152 to open and close, a support 154 for supporting the clip opener 153, and a lifting mechanism 156 for driving the support 154 to lift, wherein the supporting block 151 is installed on the support 154, and the lifting mechanism 156 is installed on the vertical plate 111. During testing, the capacitor 91 may be supported by the supporting block 151, and the two conductive clips 152 may clamp the two pins of the capacitor 91 for testing. The clip opener 153 is provided to open each conductive clip 152, so that the pins of the capacitor 91 can be conveniently inserted into each conductive clip 152, and the capacitor 91 can be conveniently taken out from the supporting block 151. The lifting mechanism 156 is provided, when the loading mechanism 14 transfers the capacitor 91 to the upper side of the supporting block 151, the lifting mechanism 156 drives the supporting block 151 to ascend, so as to insert two pins of the capacitor 91 into the two conductive clips 152.

In one embodiment, referring to fig. 1, 2 and 5, the clip opener 153 includes a top rod 1531 for pushing the two conductive clips 152, a moving block 1532 for supporting the two top rods 1531, and a clip opening cylinder 1533 for driving the two moving blocks 1532 to open and close, the clip opening cylinder 1533 is mounted on the support 154, and the support block 151 is located between the two moving blocks 1532. The clamp opening cylinder 1533 drives the two moving blocks 1532 to move closer to and away from each other, and drives the two push rods 1531 to push the two conductive clamps 152. Of course, in some embodiments, the clip opener 153 may also use two air cylinders to push the two conductive clips 152 respectively.

In one embodiment, referring to fig. 1, 2 and 5, each of the top rods 1531 may be an elastic telescopic rod to play an elastic buffering role to protect the conductive clip 152.

In one embodiment, referring to fig. 1, fig. 2 and fig. 5, the testing mechanism 15 further includes a sliding block 157 fixedly connected to the support 154 and a vertical rail 158 vertically installed on the vertical plate 111, wherein the sliding block 157 is installed on the vertical rail 158 to guide the support 154 to smoothly ascend and descend.

In one embodiment, referring to fig. 1, 2 and 5, the testing mechanism 15 further includes a linkage 155, the linkage 155 is connected to the support 154, and the lifting mechanism 156 is connected to the linkage 155 to facilitate connecting the support 154 to the lifting mechanism 156.

In one embodiment, the lift mechanism 156 is a lead screw and nut mechanism. In some embodiments, the lifting mechanism 156 may also be a linear motor or the like.

In one embodiment, the testing mechanism 15 may be positioned adjacent to the flip clip 121 such that the flip clip 121 may directly remove the capacitor 91 from the testing mechanism 15.

In one embodiment, referring to fig. 1, fig. 2 and fig. 6, the capacitor receiving testing apparatus 100 further includes a laser coding mechanism 16, and the laser coding mechanism 16 is configured to print an identification code such as a two-dimensional code or a barcode on the tested capacitor 91 for registration and identification. The laser coding mechanism 16 comprises a laser coder 161, a control clamp 162 and a mounting seat 163; the laser code printer 161 is used to print an identification code to the tested capacitor 91. The control clip 162 is mounted on the mounting seat 163, the mounting seat 163 is supported on the vertical plate 111 to support the control clip 162 on the vertical plate 111, and the control clip 162 is used for clamping the capacitor 91, so that the laser code printer 161 codes the capacitor 91 on the control clip 162. The control clip 162 is positioned between the test mechanism 15 and the flip clip 121 so that the flip clip 121 can remove the capacitor 91 directly from the control clip 162 after coding. The feeding mechanism 14 crosses over the testing mechanism 15 and the control clamp 162, so that the feeding mechanism 14 can move the capacitor 91 to the testing mechanism 15, and then move the capacitor 91 to the control clamp 162 after the test is completed.

In one embodiment, referring to fig. 1, fig. 2 and fig. 6, the laser coding mechanism 16 further includes a lifting slider 167 supporting the mounting base 163, a sliding rail 166 vertically installed on the vertical plate 111, a connecting block 164 connected to the mounting base 163, and a lifter 165 driving the connecting block 164 to lift, where the lifter 165 is installed on the vertical plate 111. The lifter 165 is arranged to guide the control clamp 162 to lift and lower, so that when the loading mechanism 14 moves the capacitor 91 to the control clamp 162, the control clamp 162 is convenient to clamp the capacitor 91; and when the control clip 162 clamps the capacitor 91, the capacitor 91 can be moved close to the laser code printer 161 to facilitate the code printing of the laser code printer 161. Meanwhile, the control clip 162 can be conveniently used for moving the capacitor 91 to the overturning clip 121, so that the overturning clip 121 can clamp the capacitor 91. A slide rail 166 and a lifting slider 167 are provided to guide the control clip 162 to be smoothly lifted.

In one embodiment, the elevator 165 may be a lead screw and nut mechanism. In some embodiments, the lifting mechanism 156 may also be a linear motor or the like.

In the capacitor receiving test device 100 of the embodiment of the application, the capacitor 91 is clamped by the feeding clamp 141 of the feeding mechanism 14, the linear mover 13 drives the feeding clamp 141 to transversely move to the position above the supporting block 151 of the test device, the lifting mechanism 156 drives the supporting block 151 to ascend, and the clamp opener 153 opens the conductive clamp 152 on the supporting block 151, so that the pins of the capacitor 91 are inserted into the corresponding conductive clamps 152 to clamp the pins of the capacitor 91, and the capacitor 91 is tested; after the test is finished, the charging clamp 141 clamps the capacitor 91 and transfers the capacitor 91 to the control clamp 162, the lifter 165 drives the control clamp 162 to be close to the laser code printer 161 so as to facilitate code printing of the laser code printer 161, the coded capacitor 91 moves to the overturning clamp 121, the overturning clamp 121 clamps the capacitor 91, the linear shifter 13 drives the toothed belt 1262 to move, the toothed belt 1261 and the rotary seat 124 are driven to rotate, and meanwhile the overturning clamp 121 is driven to overturn; if the capacitor 91 needs to be scrapped, the pushing cylinder 125 pushes the sliding plate 122 to move along the sliding plate 123, so as to drive the overturning clamp 121 to move to a waste material position, and the capacitor 91 is placed in the blanking slot 112 for collection; if the capacitor 91 needs to be sorted, and the overturning clamp 121 overturns, the capacitor 91 reaches the receiving position so as to be sorted by the receiving or sorting device. This electric capacity receives material testing arrangement 100 can realize scrapping electric capacity 91 screening, avoids occupying space among the sorting device, and small, efficient.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. Electric capacity receives material testing arrangement (100), including riser (111), be used for carrying out the accredited testing organization (15) that test to single electric capacity (91), be used for transferring electric capacity (91) feed mechanism (14) and be used for with after the test electric capacity (91) upset is placed in the upset of receiving the material level and is moved material mechanism (12), accredited testing organization (15) with feed mechanism (14) all support in on riser (111), its characterized in that: the overturning and material moving mechanism (12) comprises an overturning clamp (121) used for clamping a capacitor (91), a sliding plate (122) supporting the overturning clamp (121), a sliding plate (123) supporting the sliding plate (122) in a sliding manner, a pushing cylinder (125) driving the overturning clamp (121) to move to a waste material position along the sliding plate (123), a rotating seat (124) supporting one end of the sliding plate (123) and a rotating mechanism (126) driving the rotating seat (124) to rotate, wherein the sliding plate (122) is connected with the pushing cylinder (125), the rotating seat (124) is installed on the vertical plate (111), the rotating mechanism (126) is supported on the vertical plate (111), and the pushing cylinder (125) is installed on the rotating seat (124).

2. The material receiving testing device (100) for capacitors as claimed in claim 1, wherein: the capacitor receiving testing device (100) further comprises a discharging groove (112) used for guiding the capacitor (91) to slide down and a supporting rod (113) supporting the discharging groove (112), wherein the supporting rod (113) is installed on the vertical plate (111), and the discharging groove (112) is arranged below the sliding track plate (123).

3. The material receiving testing device (100) for capacitors as claimed in claim 1, wherein: the rotating mechanism (126) comprises a rotating gear (1261) connected with the rotating base (124), a toothed belt (1262) driving the rotating gear (1261) to rotate, and a tensioning gear (1263) matched with the rotating gear (1261) and supporting the toothed belt (1262); the capacitor material receiving testing device (100) further comprises a linear shifter (13) driving the toothed belt (1262) to transversely move, the linear shifter (13) is installed on the vertical plate (111), and the tensioning gears (1263) are rotatably installed on the vertical plate (111).

4. The capacitor material receiving testing device (100) as claimed in claim 3, wherein: the push cylinder (125) is supported on the rotating gear (1261), the push cylinder (125) is located on one surface of the vertical plate (111) departing from the turnover clamp (121), and an arc-shaped hole (1111) for a piston of the push cylinder (125) to pass through is formed in the vertical plate (111).

5. The capacitor material receiving testing device (100) as claimed in claim 3, wherein: the linear mover (13) comprises a transverse screw rod (131) arranged transversely, a traverse nut (132) arranged on the transverse screw rod (131), and a traverse motor (133) driving the transverse screw rod (131) to rotate, two ends of the transverse screw rod (131) are rotatably supported on the vertical plate (111), the traverse motor (133) is arranged on the vertical plate (111), and the traverse nut (132) is fixedly connected with the toothed belt (1262).

6. The capacitor material receiving testing device (100) as claimed in claim 3, wherein: the feeding mechanism (14) comprises a feeding clamp (141) used for clamping a capacitor (91), a feeding seat (142) supporting the feeding clamp (141), a sliding block (143) supporting the feeding seat (142), a sliding rail (144) guiding the sliding block (143) to move horizontally and a connecting rod (145) connecting the feeding seat (142) and the linear mover (13), wherein the sliding rail (144) is installed on the vertical plate (111), the sliding block (143) is installed on the sliding rail (144), and the feeding seat (142) is installed on the sliding block (143).

7. The capacitive material receiving test device (100) according to any one of claims 1 to 6, wherein: the testing mechanism (15) comprises a supporting block (151), conductive clamps (152) respectively arranged on two sides of the supporting block (151), a clamp opener (153) for driving the two conductive clamps (152) to open and close, a support (154) for supporting the clamp opener (153) and a lifting mechanism (156) for driving the support (154) to lift, wherein the supporting block (151) is arranged on the support (154), and the lifting mechanism (156) is arranged on the vertical plate (111).

8. The material receiving testing device (100) for capacitors as claimed in claim 7, wherein: the clip opener (153) comprises ejector rods (1531) for respectively ejecting the two conductive clips (152), moving blocks (1532) for supporting the two ejector rods (1531), and a clip opening cylinder (1533) for driving the two moving blocks (1532) to open and close, the clip opening cylinder (1533) is mounted on the support (154), and the support block (151) is located between the two moving blocks (1532).

9. The capacitive material receiving test device (100) according to any one of claims 1 to 6, wherein: electric capacity is received material testing arrangement (100) and is still included laser coding mechanism (16), laser coding mechanism (16) is including being used for after the test electric capacity (91) print the laser coder (161) of identification code, be used for the control clamp (162) of centre gripping electric capacity (91) and support mount pad (163) that control clamp (162) pressed from both sides, mount pad (163) support in on riser (111), control clamp (162) are located test mechanism (15) with the upset presss from both sides between (121), just loading mechanism (14) span test mechanism (15) with control clamp (162).

10. The material receiving testing device (100) for capacitors as claimed in claim 9, wherein: the laser coding mechanism (16) further comprises a lifting slide block (167) supporting the mounting base (163), a slide rail (166) vertically mounted on the vertical plate (111), a connecting block (164) connected with the mounting base (163) and a lifter (165) driving the connecting block (164) to lift, and the lifter (165) is mounted on the vertical plate (111).

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