CN219135646U - Diode automatic feeding device - Google Patents

Abstract

The utility model discloses an automatic diode feeding device, which relates to the field of junction box processing technology and comprises a bearing table, wherein the bearing table is provided with a material taking area for placing a diode box, and the automatic diode feeding device also comprises an ejection mechanism, and the ejection mechanism comprises an ejector rod and a driving assembly; the ejector rod is slidably arranged on the bearing table and is used for ejecting out the diode in the diode box; the driving assembly is connected with the ejector rod and is used for driving one end of the ejector rod away from the driving assembly to slide from one side of the material taking area to the other side of the material taking area; the utility model has the advantages of controlling the speed of ejecting the diode by the ejector rod, accurately and stably controlling the diode to take materials and improving the production efficiency of products.

Description

Diode automatic feeding device

Technical Field

The utility model relates to the technical field of junction box processing, in particular to an automatic diode feeding device.

Background

A junction box is a device for connecting and conducting electrical current. The junction box generally includes a box body, a copper substrate, and a diode disposed within the box body.

In the production of junction boxes, it is necessary to assemble the diodes into the box body. The diode is usually fed by means of conveyor belt transport and robot gripping. At present, a diode box is generally adopted for packaging, and when the diode box is loaded, the diode box with the diode is taken and placed on an inclined movable material taking plate, so that the diode box is obliquely placed, and the diode can slide away from the diode box under the action of self gravity, and the automatic loading action is completed.

In the production process, the material taking of the diode depends on the dead weight and the inclination angle of the material taking plate, so that the controllability and the stability are poor, and there is room for improvement.

Disclosure of Invention

The utility model aims to overcome the defect of poor controllability and stability of a diode in the prior art when the diode is taken, and provides an automatic diode feeding device.

The utility model solves the technical problems by the following technical scheme:

the diode automatic feeding device comprises a bearing table, wherein the bearing table is provided with a material taking area for placing a diode box, and the diode automatic feeding device further comprises an ejection mechanism, and the ejection mechanism comprises an ejector rod and a driving assembly; the ejector rod is slidably arranged on the bearing table and is used for ejecting out the diode in the diode box; the driving assembly is connected with the ejector rod and is used for driving one end, away from the driving assembly, of the ejector rod to slide from one side of the material taking area to the other side of the material taking area.

In the scheme, the diode boxes are placed in the material taking area, the driving assembly drives the ejector rods to be inserted into the diode boxes, one end of each ejector rod, which is far away from the driving assembly, moves from one side of the material taking area to the other side of the material taking area, and the diodes in the diode boxes are ejected one by one; after all diodes in the diode box are ejected, the driving assembly drives the ejector rod to withdraw from the diode box, the diode box does not need to be obliquely placed in the automatic diode feeding device, and the speed of ejecting the diodes by the ejector rod can be controlled by controlling the driving assembly, so that the purpose of stable control is achieved.

Preferably, at least two ejector rods are arranged in parallel.

In the scheme, the ejector rods are provided with at least two action points, so that the ejector rods have at least two action points when ejecting the diode, and the diode is not easy to deviate in the ejection process, thereby being beneficial to the ejector rods to stably eject the diode from the diode box.

Preferably, the driving assembly comprises a motor and a transfer belt, the motor is fixedly arranged relative to the bearing table, and the transfer belt is arranged outside the motor and can move under the driving of the motor.

In the scheme, the driving assembly comprises a motor and a transfer belt, the transfer belt is arranged outside the motor, one end of the ejector rod is fixed on the transfer belt, and the motor drives the transfer belt to move and can stably drive the ejector rod to advance or retreat along the material taking area, so that the ejector rod is inserted into the diode box to eject the diode or the ejector rod is withdrawn from the diode box; the speed of the ejector rod ejection diode can be adjusted by adjusting the rotating speed of the motor so as to adapt to different production beats.

Preferably, the automatic diode feeding device further comprises a pressing mechanism, wherein the pressing mechanism is arranged at the end part of the material taking area and used for pressing the diode box in the material taking area.

In this scheme, compress tightly the diode box in getting the material region through hold-down mechanism, avoid the ejector pin to take place the skew with the diode box when ejecting the diode for the ejector pin takes place to interfere with the diode box, perhaps the ejector pin can't be ejecting the diode in the diode box.

Preferably, the compressing mechanism comprises a compressing cylinder, the compressing cylinder is fixed above the bearing table, a piston rod shaft of the compressing cylinder faces the bearing table, and a gap for placing the diode box is formed between the compressing cylinder and the bearing table.

In the scheme, the compressing mechanism comprises a compressing cylinder, a cylinder body of the compressing cylinder is fixed on the bearing table, and a piston rod shaft of the compressing cylinder faces the bearing table; after the diode box is placed in a gap between the pressing cylinder and the bearing table, a piston rod shaft of the pressing cylinder moves towards the bearing table to press the diode box on the bearing table.

Preferably, the automatic diode feeding device further comprises a box body stacking frame, wherein the box body stacking frame is located outside the material taking area and fixed on the bearing table, and the box body stacking frame is used for stacking diode boxes.

In the scheme, the box body stacking frame is arranged at the part, outside the material taking area, of the bearing table, and the diode boxes with the diodes are stacked on the box body stacking frame so as to facilitate taking and placing of new diode boxes into the material taking area for taking the diodes.

Preferably, the box body stacking frame comprises two oppositely arranged side plates, two opposite sides of the side plates are respectively provided with a limit groove, and the limit grooves are used for limiting the diode boxes in the horizontal direction.

In this scheme, the diode box is vertically piled up between two curb plates, and the both ends of diode box are spacing in the spacing groove of two curb plates respectively for the diode box of piling up is difficult for taking place the displacement in horizontal direction, thereby makes the diode box of piling up difficult emergence to empty.

Preferably, a box outlet for allowing a single diode box to come in and go out is formed in the bottom of the box stacking frame, the automatic diode feeding device further comprises a pushing mechanism, the pushing mechanism comprises a first pushing block and a flat pushing assembly, and the flat pushing assembly is used for pushing the first pushing block to slide horizontally and pushing the diode box out of the box outlet to the material taking area.

In the scheme, the horizontal pushing component is connected with the first pushing block and pushes the first pushing block to slide horizontally, so that the first pushing block pushes the lowest layer diode box in the stacked diode boxes out of a box outlet at the bottom of the box body stacking frame to a material taking area, and the diode boxes are fed; when the flat pushing component pushes the first pushing block to withdraw from the stacking frame, the box body above the stacking frame falls to the upper part of the bearing table due to the dead weight, so that the diode box is pushed to the material taking area next time.

Preferably, the pushing mechanism further comprises a second pushing block, the second pushing block is arranged on the flat pushing assembly, and the flat pushing assembly drives the second pushing block to horizontally slide so as to push the diode box on the material taking area open.

In the scheme, a second pushing block is further arranged on the horizontal pushing assembly, and the horizontal pushing assembly pushes the first pushing block and the second pushing block to synchronously move; when all diodes in the diode boxes in the material taking area are ejected by the ejector rods, the ejector rods exit the diode boxes, the flat pushing assembly pushes the first pushing block and the second pushing block to horizontally slide, the second pushing block pushes the empty diode boxes on the material taking area away from the material taking area, and the first pushing block pushes new diodes into the material taking area; therefore, the flat pushing assembly can realize the evacuation of the empty diode box and the feeding of the new diode box by pushing the flat pushing assembly once, so that the operation steps are simplified, and the production efficiency is improved.

Preferably, the bearing table is provided with a strip abdication hole, the pushing mechanism is positioned below the bearing table, the first pushing block and the second pushing block are both positioned in the strip abdication hole and can slide along the length direction of the strip abdication hole,

the pushing mechanism further comprises a jacking component, wherein the jacking component is arranged on the flat pushing component and can push the first pushing block and the second pushing block to protrude out of the upper edge of the strip abdicating hole.

In the scheme, the pushing mechanism is positioned below the bearing table, and the first pushing block and the second pushing block are positioned in the strip abdication hole; when the first pushing block and the second pushing block are required to push the diode box, the jacking component jacks up the first pushing block and the second pushing block, so that the first pushing block and the second pushing block protrude out of the upper edge of the strip abdication hole, and the first pushing block and/or the second pushing block can be in contact with the diode box and push the diode box; when empty diode boxes are pushed away from the material taking area and new diode boxes are pushed into the material taking area, the jacking component drives the first pushing block and the second pushing block to move downwards, so that the first pushing block and the second pushing block are retracted into the strip yielding holes, and the phenomenon that the first pushing block interferes with the diode boxes at the box body stacking frame and/or the second pushing block interferes with the new diode boxes on the material taking area when the flat pushing component drives the first pushing block and the second pushing block to move horizontally to retract to the initial position is avoided.

The utility model has the positive progress effects that:

the automatic diode feeding device comprises a bearing table and an ejection mechanism, wherein when a diode is taken, a diode box is placed in a taking area of the bearing table, a driving assembly drives a push rod to be inserted into the diode box, and one end of the push rod, which is far away from the driving assembly, moves from one side of the taking area to the other side of the taking area, so that the diodes in the diode box are ejected one by one; after all the diodes in the diode box are ejected, the driving assembly drives the ejector rod to withdraw from the diode box; therefore, when the diode is taken out, the diode box does not need to be placed obliquely, the speed of ejecting the diode by the ejector rod can be controlled by controlling the driving assembly, the diode can be accurately and stably controlled to be taken out, and the production efficiency of products is improved.

Drawings

Fig. 1 is a schematic structural view of a diode case according to a preferred embodiment of the present utility model.

Fig. 2 is a schematic perspective view of an automatic diode feeding device according to a preferred embodiment of the present utility model.

Fig. 3 is a schematic top view of an automatic diode feeding device according to a preferred embodiment of the present utility model.

Fig. 4 is a schematic perspective view of a driving assembly according to a preferred embodiment of the present utility model.

Fig. 5 is a schematic perspective view of a pressing mechanism and a cassette stacking rack according to a preferred embodiment of the present utility model.

Fig. 6 is a schematic perspective view of a side plate according to a preferred embodiment of the present utility model.

Fig. 7 is a schematic perspective view of a pushing mechanism according to a preferred embodiment of the present utility model.

Reference numerals illustrate:

diode automatic feeding device 100

Load-bearing table 110

Take-out area 111

Support plate 112

Leg 113

Diode holder 114

Placement groove 115

Strip relief hole 116

Ejection mechanism 120

Ejector rod 121

Drive assembly 122

Electric motor 1221

Transfer belt 1222

Pressing mechanism 130

Compacting cylinder 131

Support riser 132

Fixing groove 133

Box stacking rack 140

Side plate 141

Limiting groove 142

Box outlet 143

Pushing mechanism 150

Support frame 151

Flat push assembly 152

Flat pushing cylinder 1521

Guide rail 1522

Slide plate 1523

Jacking assembly 153

Jacking cylinder 1531

Jacking plate 1532

First pusher block 154

Second pusher block 155

Diode box 200

Diode 210

Detailed Description

The utility model is further illustrated by means of examples which follow, without thereby restricting the scope of the utility model thereto.

The embodiment discloses an automatic diode feeding device 100, referring to fig. 1 and 2, the automatic diode feeding device 100 is used for taking out a diode 210 in a diode box 200. The diode case 200 has a long strip shape, and a plurality of diodes 210 are sequentially arranged in a row along the length direction of the diode case 200 are accommodated in the diode case 200. In other embodiments, the diodes 210 in the diode box 200 may be arranged in two or more rows.

Referring to fig. 2 and 3, the automatic diode feeding device 100 includes a carrying table 110, an ejection mechanism 120, a pressing mechanism 130, a box stacking frame 140, and a pushing mechanism 150. The carrying platform 110 is provided with a material taking area 111 for placing the diode box 200; the ejection mechanism 120 is disposed at one side of the carrying platform 110 and corresponds to the material taking area 111, and is used for ejecting the diode 210 in the diode box 200 in the material taking area 111; the pressing mechanism 130 is disposed above the material taking area 111, and is used for pressing the diode box 200 of the diode 210 to be taken out onto the carrying platform 110; the box stacking frame 140 is disposed at a position on the carrying platform 110 outside the material taking area 111, and is used for stacking the diode boxes 200; the pushing mechanism 150 is disposed on the carrying platform 110 for pushing the empty diode box 200 away from the material taking area 111 and/or pushing a new diode box 200 from the box stacking rack 140 into the material taking area 111.

The carrier 110 includes a support plate 112, a plurality of legs 113, and a diode placement frame 114. The legs 113 are connected below the support plate 112 to carry the support plate 112. The material taking region 111 is located on the upper side plate 141 of the support plate 112, and is a rectangular region having the same shape as the diode case 200. The diode placement frame 114 is disposed at an upper side of the support plate 112 and outside one short side of the material taking region 111 for placing the diode box 200 ejected from the diode box 200.

The diode placing rack 114 is a rectangular flat plate, and the upper side plate 141 is provided with a placing groove 115 for placing the diode 210. One end of the diode holder 114 is fixed to the support plate 112, and the other end is cantilevered out of the support plate 112, thereby reducing the area of the support plate 112 and reducing the occupied space of the support plate 112.

Referring to fig. 2 and 3, the ejector mechanism 120 is disposed on a side of the support plate 112 remote from the diode mount 114. The ejector mechanism 120 includes an ejector rod 121 and a drive assembly 122. The driving assembly 122 is connected with the ejector rod 121 to drive the ejector rod 121 to slide.

Wherein, in conjunction with fig. 4, the drive assembly 122 includes a motor 1221 and a transfer belt 1222. The transfer belt 1222 is sleeved outside the motor 1221 through a pulley, and the jack 121 is fixed on the transfer belt 1222. The motor 1221 rotates to move the transfer belt 1222, thereby driving the jack 121 to slide along the length direction of the transfer belt 1222.

One end of the push rod 121 is fixed to the transfer belt 1222, and the other end is suspended above the support plate 112. The carrier bar 121 is disposed parallel to the moving direction of the transfer belt 1222. When the transfer belt 1222 is in operation, one end of the ejector rod 121 far away from the sliding seat can slide from one short side of the material taking area 111 to the other short side of the material taking area 111, so as to eject the diodes 210 in the diode boxes 200 in the material taking area 111 onto the diode placement frame 114 one by one.

In this embodiment, the number of the ejector pins 121 is two, and the two ejector pins 121 are arranged in parallel at intervals, so that when the diode 210 is ejected, two action points are formed between the ejector pins 121 and the diode 210, and the ejected diode 210 is prevented from tilting and deflecting. In other embodiments, the number of the ejector pins 121 may be other suitable values.

Referring to fig. 5, the pressing mechanism 130 includes a pressing cylinder 131 and a supporting riser 132. The support risers 132 are disposed outside the short sides of the take-off area 111 and immediately adjacent to the take-off area 111. The hold-down cylinder 131 is located directly above the opposed short sides of the take-off region 111. The cylinder body of the compressing cylinder 131 is fixedly arranged on the side plate 141 surface of the supporting vertical plate 132, which is close to the material taking area 111, and the piston rod of the compressing cylinder 131 is arranged downwards, namely, the piston rod of the compressing cylinder 131 points to the material taking area 111. A gap exists between an end of the piston rod of the compaction cylinder 131, which is far away from the cylinder body of the compaction cylinder 131, and the material taking region 111 so that the diode box 200 is placed in the material taking region 111. When the piston rod of the pressing cylinder 131 moves downwards, the piston rod is pressed above the diode box 200, so that the diode box 200 is pressed in the material taking area 111, and the diode box 200 is prevented from moving; when all of the diodes 210 in the diode box 200 are taken out, the piston rod of the pressing cylinder 131 moves upward to release the diode box 200, so that the empty diode box 200 can be removed from the take-out area 111.

A fixing groove 133 is provided on a side of the piston rod of the pressing cylinder 131 facing the material taking area 111. The fixing groove 133 is adapted to the diode box 200. The diode case 200 can be inserted into the fixing groove 133 and is limited in the fixing groove 133.

Wherein, the side wall of the fixing groove 133 is inclined such that the slot opening area of the fixing groove 133 is greater than the slot bottom area of the fixing groove 133, so that the slot wall of the fixing groove 133 plays a guiding role in the process of inserting the diode box 200, so that the diode box 200 is inserted into the fixing groove 133.

In this embodiment, the bottom of the supporting riser 132 is hollowed out to allow the ejector pins 121 to penetrate into the material taking area 111 and/or the diode 210 to leave the diode box 200 and enter the diode placement frame 114.

In this embodiment, the two short sides of the material taking area 111 are provided with the supporting risers 132 and the pressing cylinders 131, so that the pressing mechanism 130 can press the diode box 200 at both ends of the diode box 200, so that the diode box 200 is placed more stably. In other embodiments, the number of support risers 132 and hold down cylinders 131 may be other suitable values, and the support risers 132 and hold down cylinders 131 may be positioned in other suitable locations.

Referring to fig. 5, the case stacking frame 140 includes two side plates 141, the two side plates 141 being disposed in parallel at intervals, and a space for stacking the diode case 200 is formed between the two side plates 141. A new diode box 200 may be stacked between the two side plates 141 for access.

In this embodiment, the two side plates 141 are provided with a limiting groove 142 on opposite sides. The notches of the two limiting grooves 142 are opposite, and two ends of the diode box 200 can be respectively inserted into the two limiting grooves 142, so that the limiting grooves 142 limit the diode boxes 200 in the horizontal direction, and the stacked diode boxes 200 are not easy to topple.

Referring to fig. 5 and 6, the limiting groove 142 penetrates through the upper and lower ends of the side plates 141 to facilitate the placement of the diode 210 between the two side plates 141 from above the side plates 141. The bottoms of the two side plates 141 are provided with box outlet 143 communicated with the limiting groove 142, and the diode box 200 can slide out of the box body stacking frame 140 from the box outlet 143 at the bottom of the side plate 141.

Specifically, in this embodiment, the box outlet 143 is disposed on a side of the side plate 141 near the material taking area 111. The distance between the upper and lower edges of the outlet 143 is greater than one time the thickness of the diode box 200 and less than two times the thickness of the diode box 200, thereby facilitating the sliding of a single diode box 200 out of the outlet 143.

Referring to fig. 2, 3 and 7, the pusher mechanism 150 includes a support frame 151, a flat push assembly 152, a jacking assembly 153, a first pusher block 154 and a second pusher block 155. The supporting frame 151 is fixedly arranged at the lower side of the supporting plate 112, and the horizontal pushing assembly 152 and the jacking assembly 153 are arranged in the supporting frame 151 and are used for driving the first pushing block 154 and the second pushing block 155 to move.

The support plate 112 is provided with the strip abdication hole 116 with the extending direction perpendicular to the long side of the material taking area 111, the jacking component 153 can jack the first pushing block 154 to protrude out of the upper side edge of the strip abdication hole 116, the flat pushing component 152 can push the jacking component 153, the first pushing block 154 and the second pushing block 155 to slide along the length direction of the strip abdication hole 116, so that the first pushing block 154 can push the diode box 200 at the bottom of the box body stacking frame 140 to the material taking area 111, and the second pushing block 155 pushes the empty diode box 200 in the material taking area 111 away from the material taking area 111.

The flat push assembly 152 includes a flat push cylinder 1521, a guide rail 1522, and a slide plate 1523. The horizontal pushing cylinder 1521 and the guide rail 1522 are parallel to each other and fixed to the support frame 151. The length direction of the guide rail 1522 is perpendicular to the long side of the take-out region 111. The sliding plate 1523 is disposed on the guiding rail 1522 and cooperates with the guiding rail 1522, and a piston rod of the horizontal pushing cylinder 1521 is connected to the sliding plate 1523 to drive the sliding plate 1523 to slide along the guiding rail 1522.

The jacking assembly 153 includes a jacking cylinder 1531 and a jacking plate 1532. The cylinder body of the jacking cylinder 1531 is fixedly disposed on the slide plate 1523, the piston rod of the jacking cylinder 1531 is disposed upward, and the jacking plate 1532 is fixed to the upper end of the piston rod of the jacking cylinder 1531. The first pusher block 154 and the second pusher block 155 are each disposed on a jacking plate 1532.

Thus, when the first and second pushing blocks 154 and 155 are required to push the diode box 200, the jacking assembly 153 jacks up the first and second pushing blocks 154 and 155 so that the first and second pushing blocks 154 and 155 protrude from the upper edges of the elongated relief holes 116, so that the first and/or second pushing blocks 154 and 155 can contact the diode box 200 and push the diode box 200; when an empty diode box 200 is pushed away from the material taking area 111 and a new diode box 200 is pushed into the material taking area 111, the jacking component 153 drives the first pushing block 154 and the second pushing block 155 to move downwards, so that the first pushing block 154 and the second pushing block 155 retract into the strip yielding hole 116, and when the flat pushing component 152 drives the first pushing block 154 and the second pushing block 155 to move horizontally to retract to the initial position, the first pushing block 154 interferes with the diode box 200 at the box body stacking rack 140 and/or the second pushing block 155 interferes with the new diode box 200 on the material taking area 111.

One use method of the automatic diode feeding device 100 in this embodiment is as follows:

when the diode automatic feeding device 100 is used for feeding the diode 210, new diode boxes 200 are stacked in the box stacking frame 140, the jacking component 153 jacks up the first pushing block 154 and the second pushing block 155, so that the first pushing block 154 and the second pushing block 155 are arranged above the strip yielding hole 116 in a protruding mode, the flat pushing component 152 drives the first pushing block 154 and the second pushing block 155 to move horizontally, the second pushing block 155 pushes the empty diode boxes 200 in the material taking area 111 away from the material taking area 111, and the first pushing block 154 moves horizontally to push the diode boxes 200 into the material taking area 111. The jacking assembly 153 drives the first pushing block 154 and the second pushing block 155 to move downwards so that the first pushing block 154 and the second pushing block 155 retract into the strip yielding hole 116, and the flat pushing assembly 152 translates away from the material taking area 111 to drive the first pushing block 154 and the second pushing block 155 to return to the initial positions.

At this time, the piston rod of the pressing cylinder 131 moves downward to press the diode boxes 200 in the material taking area 111, and the driving assembly 122 drives the ejector rods 121 to slide along the length direction of the diode boxes 200, so as to eject the diodes 210 in the diode boxes 200 onto the diode placing racks 114 one by one.

While specific embodiments of the utility model have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and the scope of the utility model is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the principles and spirit of the utility model, but such changes and modifications fall within the scope of the utility model.

Claims (10)

1. The automatic diode feeding device is characterized by comprising a bearing table, wherein the bearing table is provided with a material taking area for placing a diode box, and the automatic diode feeding device further comprises an ejection mechanism, and the ejection mechanism comprises an ejector rod and a driving assembly; the ejector rod is slidably arranged on the bearing table and is used for ejecting out the diode in the diode box; the driving assembly is connected with the ejector rod and is used for driving one end, away from the driving assembly, of the ejector rod to slide from one side of the material taking area to the other side of the material taking area.

2. The automatic diode feeding device according to claim 1, wherein at least two ejector pins are arranged in parallel.

3. The diode automatic feeding device of claim 1, wherein the driving assembly comprises a motor and a transfer belt, the motor is fixedly arranged relative to the bearing table, the transfer belt is arranged outside the motor and can move under the driving of the motor, and the ejector rod is fixed on the transfer belt.

4. The diode automatic feeding device of claim 1, further comprising a hold-down mechanism disposed at an end of the take-out area, the hold-down mechanism configured to hold down a diode cartridge in the take-out area.

5. The automatic diode feeding device according to claim 4, wherein the pressing mechanism comprises a pressing cylinder, the pressing cylinder is fixed above the bearing table, a piston rod of the pressing cylinder faces the bearing table, and a gap for placing a diode box is formed between the pressing cylinder and the bearing table.

6. The diode automatic feeding device of claim 1, further comprising a box stacking rack located outside the material taking area and fixed on the carrying table, wherein the box stacking rack is used for stacking diode boxes.

7. The automatic diode feeding device of claim 6, wherein the box stacking frame comprises two opposite side plates, and two opposite sides of the two side plates are respectively provided with a limit groove, and the limit grooves are used for limiting the diode box in the horizontal direction.

8. The diode automatic feeding device of claim 6, wherein a box outlet for allowing a single diode box to go in and out is formed in the bottom of the box stacking frame, and the diode automatic feeding device further comprises a pushing mechanism, wherein the pushing mechanism comprises a first pushing block and a flat pushing assembly, and the flat pushing assembly is used for pushing the first pushing block to slide horizontally and pushing the diode box out of the box outlet to the material taking area.

9. The diode automatic feeding device of claim 8, wherein the pushing mechanism further comprises a second pushing block disposed on the flat pushing assembly, the flat pushing assembly driving the second pushing block to slide horizontally to push the diode box out of the take-out area.

10. The automatic diode feeding device of claim 9, wherein the bearing table is provided with a strip abdicating hole, the pushing mechanism is positioned below the bearing table, the first pushing block and the second pushing block are both positioned in the strip abdicating hole and can slide along the length direction of the strip abdicating hole,

the pushing mechanism further comprises a jacking component, wherein the jacking component is arranged on the flat pushing component and can push the first pushing block and the second pushing block to protrude out of the upper edge of the strip abdicating hole.

Images