CN213445091U - High-efficient loading attachment of polymer electricity core - Google Patents

Abstract

The utility model discloses a high-efficient loading attachment of polymer electricity core, including frame, setting moving mechanism in the frame and setting up the material sucking disc mechanism of inhaling on moving mechanism, be equipped with pan feeding district, ejection of compact district and recovery area in the frame. One side of the feeding area and one side of the discharging area, which are close to the moving mechanism, are respectively provided with a vertically arranged jacking mechanism, and a sliding plate of the jacking mechanism is provided with a bearing plate vertically arranged on the sliding plate. The charging tray for loading the battery cell is arranged on the bearing plate of the jacking mechanism in the feeding area, and the empty tray is arranged on the bearing plate of the jacking mechanism in the recovery area. The two sides of the feeding area and the lower part of the discharging area are provided with a guide mechanism, the guide mechanism comprises two guide plates which are oppositely arranged, a charging tray for loading the battery cell is clamped between the two guide plates of the guide mechanism of the feeding area, and an empty tray is clamped between the two guide plates of the guide mechanism of the recovery area. The utility model discloses can effectively solve the empty dish and retrieve the problem that the material loading efficiency is low that leads to.

Description

High-efficient loading attachment of polymer electricity core

Technical Field

The utility model relates to a technical field of automation equipment, in particular to high-efficient loading attachment of polymer electricity core.

Background

Along with the increasing scientific and technological development and humanization of intelligent creation in China, the demand on automatic production equipment is increasing. In the battery production field, generally adopt artifical material loading, because the battery is mass production, the cost of labor who consumes is high, and inefficiency, more and more can not satisfy the rhythm of enterprise to high-efficient production.

In order to further improve the production efficiency of the battery, the industry also develops corresponding automatic feeding equipment according to the mode of cell feeding, for example, an automatic cell feeding machine disclosed in chinese publication No. CN206705246U, which includes a frame, and the frame is provided with a jacking device, a moving device, a material sucking manipulator and a sucker manipulator. During production, a plurality of material discs which are stacked together and are fully loaded with the battery cells are manually arranged on the jacking device, the moving device drives the mechanical material suction manipulator to move to suck materials and move the sucked battery cells to the next procedure, and then the sucker manipulator recovers the empty discs to an empty area of the rack for workers to recover.

Above-mentioned material loading mode in order to pile up the charging tray can provide production efficiency greatly, but also have some problems simultaneously, for example, when carrying out empty tray recovery, because the distance that the sucking disc manipulator can stretch out downwards is effective, therefore, the charging tray at initial stage all is direct free fall in the frame, to the certain damage of charging tray, although there is corresponding baffle to lead in falling the region, can free fall for guaranteeing the charging tray, the interval between the baffle generally can be greater than the width of charging tray, this leads to the charging tray to take place the slope easily when falling and can not effectively pile up together with last charging tray, the not arrangement that the charging tray piled up, inconvenient staff retrieves, and then influence whole automatic feeding device's material loading efficiency.

SUMMERY OF THE UTILITY MODEL

Problem to prior art existence, the utility model aims at providing a high-efficient loading attachment of polymer electricity core aims at solving the empty dish and retrieves the problem that the material loading efficiency is low that leads to.

In order to achieve the above object, the utility model provides a high-efficient loading attachment of polymer electricity core, be in including frame, setting moving mechanism and setting in the frame are in last material sucking disc mechanism of inhaling of moving mechanism, be equipped with pan feeding district, ejection of compact district and recovery area in the frame. The side, close to the moving mechanism, of the feeding area and the side, close to the moving mechanism, of the discharging area are respectively provided with a vertically arranged jacking mechanism, and a sliding plate of the jacking mechanism is provided with a bearing plate vertically arranged on the sliding plate; a charging tray for loading the battery cell is arranged on the bearing plate of the jacking mechanism of the charging area, and an empty tray is arranged on the bearing plate of the jacking mechanism of the recovery area;

the device is characterized in that guide mechanisms are arranged on two sides of the feeding area and below the discharging area, each guide mechanism comprises two guide plates which are oppositely arranged, a charging tray for loading electric cores is clamped between the two guide plates of the guide mechanism of the feeding area, and an empty tray is clamped between the two guide plates of the guide mechanism of the recovery area.

Optionally, the feeding area is provided with a feeding belt line, the recovery area is provided with a recovery belt line, and a feeding end of the feeding belt line and a discharging end of the recovery belt line extend outwards of the rack;

and the discharging area is provided with a discharging belt line.

Optionally, the guide mechanism further comprises a fixed support located below the rack, a flat plate is arranged on the fixed support, a guide rail group arranged along the interval direction of the two guide plates is arranged on the flat plate, and the two guide plates are fixed on sliding blocks at two ends of the guide rail group through supporting frames respectively;

and a screw adjusting component for adjusting the two guide plates to move oppositely or back to back is arranged at the bottom of the flat plate.

Optionally, the screw adjusting assembly comprises a forward screw and a reverse screw which are coaxially connected, connecting blocks in threaded fit with the forward screw and the reverse screw are respectively arranged on the forward screw and the reverse screw, and the guide plate is fixed on the connecting block corresponding to the guide plate through a support frame;

one end of the forward screw rod is provided with an adjusting wheel, and a handle is arranged on the adjusting wheel.

Optionally, the feeding side of the guide plate is provided with an inclined guide surface bent outwards.

The utility model discloses a set up respectively in pan feeding district and recovery area and be used for bearing charging tray climbing mechanism, during the material loading, there is the climbing mechanism in pan feeding district to lift on with the charging tray for inhaling material sucking disc mechanism and get the material, when retrieving, lift on its loading board by the climbing mechanism in recovery area and get in order to receive empty dish, like this, at material loading and recovery in-process, only need inhale material sucking disc mechanism and descend certain height slightly and just can realize material loading and empty dish and get and put, improve the efficiency that the efficiency of material loading and empty dish got and put greatly.

And because the jacking mechanism of the recovery area can lift the bearing plate to directly receive the empty tray, the empty tray is prevented from inclining due to the falling height of the empty tray, and when the jacking mechanism of the recovery area receives an empty tray, the empty tray automatically descends by the height of the empty tray, so that the empty tray can be effectively and continuously received, and the empty tray can be kept in a good stacking state.

And two guide plates are respectively arranged on two sides of the feeding area and the discharging area so as to further ensure the neatness of the charging tray stacked in the feeding area and the discharging area, and avoid the phenomenon that the stacked charging tray is collided by other mechanisms to incline so as to influence the feeding and the empty tray recovery.

Drawings

Fig. 1 is an overall schematic view of an embodiment of the efficient feeding device for polymer cells according to the present invention;

fig. 2 is a schematic structural diagram of a guiding mechanism in an embodiment of the efficient feeding device for polymer cells of the present invention;

fig. 3 is a schematic view illustrating a connection between a screw adjusting assembly and a guide plate in an embodiment of the efficient feeding device for polymer cells of the present invention;

fig. 4 is a schematic structural diagram of a screw adjusting assembly in an embodiment of the efficient feeding device for polymer cells according to the present invention;

fig. 5 is a schematic structural diagram of a jacking mechanism in an embodiment of the high-efficiency feeding device for polymer cells of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to the attached drawing 1, an embodiment of the present invention provides a high-efficiency feeding device for a polymer battery cell, which includes a frame 1, a moving mechanism 2 disposed on the frame 1, and a material sucking and sucking disc mechanism 3 disposed on the moving mechanism 2. The frame 1 is provided with a feeding area, a discharging area and a recovery area. One side of the feeding area and one side of the discharging area close to the moving mechanism 2 are respectively provided with a vertically arranged jacking mechanism (41, 42), as shown in fig. 5, a sliding plate 411 of the jacking mechanism 41 is provided with a bearing plate 412 vertically arranged on the sliding plate 411, and the jacking mechanism 42 and the jacking mechanism 41 are the same mechanism, which is not repeated herein. The tray 7 for loading the battery cell is placed on the bearing plate 412 of the jacking mechanism 41, and the empty tray is placed on the bearing plate of the jacking mechanism 42.

The two sides of the feeding area and the lower part of the discharging area are provided with a guiding mechanism (51, 52), as shown in fig. 2, the guiding mechanism 51 comprises two guiding plates 511 which are oppositely arranged, the tray 7 for loading the battery cells is clamped between the two guiding plates 511 of the guiding mechanism 51, and the empty tray is clamped between the two guiding plates of the guiding mechanism 52 of the recovery area.

During loading, a worker inserts the stacked and battery-loaded tray 7 between the two guiding plates 511 from the feeding side of the two guiding plates 511, and places the tray on the loading plate 412 of the lifting mechanism 41. Then the moving mechanism 2 drives the material sucking disc mechanism 3 to move to the upper part of the material tray 7, and the electric core in the material tray 7 is taken out and moved to a discharging area.

When the material sucking and sucking mechanism 3 takes away all the electric cores in the material tray 7, the material sucking and sucking mechanism 3 transfers the empty tray to the recovery area, and the jacking mechanism 42 drives the bearing plate to lift up to receive the empty tray. When the material sucking and sucking disc mechanism 3 takes away the empty disc at the top of the feeding area, the jacking mechanism 41 lifts the material disc 7 carried by the material sucking and sucking disc mechanism 3 by the height of one material disc 7, so that the material sucking and sucking disc mechanism 3 can take materials and take discs conveniently; each time the lifting mechanism 42 receives an empty tray, it automatically lowers the height of one tray 7 to receive a new empty tray, and when a certain number of empty trays are received, the worker can take out the stacked empty trays from the recovery area.

The utility model discloses a set up climbing mechanism (41, 42) that are used for bearing charging tray 7 respectively in pan feeding district and recovery area, during the material loading, lift on charging tray 7 by climbing mechanism 41 in pan feeding district for supplying to inhale material sucking disc mechanism 3 and get the material, when retrieving, lift on its loading board by climbing mechanism 42 in recovery area for receiving empty dish, like this, in material loading and recovery process, only need inhale material sucking disc mechanism 3 and descend certain height slightly and just can realize material loading and empty dish and get and put, improve the efficiency of material loading and the efficiency that empty dish got and put greatly.

And, because the climbing mechanism 42 of the recovery area can lift the bearing plate to receive the empty tray directly, avoid the height that the empty tray falls to cause the empty tray to incline, and every time the climbing mechanism 42 of the recovery area receives an empty tray, descend an empty tray height automatically, in order to receive the empty tray that lasts effectively from this, and make the empty tray keep good pile-up state.

And, two sides in pan feeding district and ejection of compact district are equipped with two respectively and lead positive plate 511 to further guarantee to pile up the charging tray 7 regularity in pan feeding district and ejection of compact district, and can avoid piling up charging tray 7 to be collided by other mechanisms and take place the slope and influence pay-off and empty dish and retrieve.

Optionally, as shown in fig. 1, in the present embodiment, an inlet belt line 61 is disposed in the inlet area, a recovery belt line 62 is disposed in the recovery area, and an inlet end of the inlet belt line 61 and an outlet end of the recovery belt line 62 extend outward of the rack 1. The discharging area is provided with a discharging belt line 63.

During loading, the tray 7 stacked and loaded with the electric cores can be conveyed to the loading plate 411 of the jacking mechanism 41 through the feeding belt line 61. During discharging, the battery core taken out from the charging tray 7 is sent to the next station by the discharging belt line 63. At the time of collection, the stacked trays 7 are sent out by the collection belt line 62. Through setting up pan feeding belt line 61 and ejection of compact belt line 62 to this makes the staff can carry out the material loading or empty dish and retrieve outside automatic feeding's the operating region, improves the security that the staff material loading was gone up and was retrieved empty dish greatly.

Optionally, as shown in fig. 2-3, the guiding mechanism 51 further includes a fixing bracket 512 located below the frame 1, a flat plate 513 is disposed on the fixing bracket 512, a guide rail group 5131 disposed along the interval direction of the two guiding plates 511 is disposed on the flat plate 513, and the two guiding plates 511 are respectively fixed on the sliding blocks at two ends of the guide rail group 5131 through supporting frames. The bottom of the flat plate 513 is provided with a screw adjusting assembly 514 for adjusting the relative or opposite movement of the two guide plates 511.

Specifically, as shown in fig. 3-4, in this embodiment, the screw adjustment assembly 514 includes a forward screw 5141 and a reverse screw 5142 that are coaxially connected, each of the forward screw 5141 and the reverse screw 5142 is provided with a connection block 5111 that is threadedly engaged with the forward screw 5141 and the reverse screw 5142, and the connection block 5111 passes through the flat plate 513 and is connected to the support frame below the pilot plate 5111. Through the arrangement of the screw adjusting assembly 514, when the forward screw 5141 is driven to rotate, the reverse screw 5142 can be synchronously driven to rotate, and due to the fact that the thread of the reverse screw 5142 is opposite to the thread of the forward screw 5141, the respective connecting blocks 5111 can be driven to move towards or away from each other, so that the positive guide plates 511 connected with the connecting blocks 5111 are driven to move towards or away from each other, the distance between the two positive guide plates 511 is adjusted, and the charging tray 7 with different widths is adapted.

To facilitate adjustment, an adjustment wheel 5143 is provided at one end of the forward screw 5141, and a handle 5144 is provided on the adjustment wheel 5143. Therefore, the adjusting wheel 5143 can be rotated by holding the handle 5144 to drive the forward screw 5141 and the reverse screw 5142 to rotate so as to adjust the distance between the two guide plates 511, and the operation is convenient.

Optionally, as shown in fig. 2, in the present embodiment, the feeding side of the guiding plate 511 is provided with an inclined guiding surface 511a bent outward, so as to increase the opening distance between the feeding sides of the two guiding plates 511, and improve the feeding convenience of the stacking plates.

The above is only the preferred embodiment of the present invention, not used in the present invention, and any slight modifications, equivalent replacements and improvements made by the technical entity of the present invention to the above embodiments should be included in the protection scope of the technical solution of the present invention.

Claims (5)

1. The efficient feeding device for the polymer battery cell comprises a rack, a moving mechanism arranged on the rack and a material sucking and sucking disc mechanism arranged on the moving mechanism, wherein a feeding area, a discharging area and a recovery area are arranged on the rack; a charging tray for loading the battery cell is arranged on the bearing plate of the jacking mechanism of the charging area, and an empty tray is arranged on the bearing plate of the jacking mechanism of the recovery area;

the device is characterized in that guide mechanisms are arranged on two sides of the feeding area and below the discharging area, each guide mechanism comprises two guide plates which are oppositely arranged, a charging tray for loading electric cores is clamped between the two guide plates of the guide mechanism of the feeding area, and an empty tray is clamped between the two guide plates of the guide mechanism of the recovery area.

2. The efficient feeding device of polymer battery cells of claim 1, wherein the feeding zone is provided with a feeding belt line, the recycling zone is provided with a recycling belt line, and a feeding end of the feeding belt line and a discharging end of the recycling belt line extend outwards from the machine frame;

and the discharging area is provided with a discharging belt line.

3. The efficient feeding device of polymer electric cores of claim 2, wherein the guiding mechanism further comprises a fixing support located below the rack, a flat plate is arranged on the fixing support, a guide rail group is arranged on the flat plate along a spacing direction of the two guiding plates, and the two guiding plates are respectively fixed on sliding blocks at two ends of the guide rail group through a support frame;

and a screw adjusting component for adjusting the two guide plates to move oppositely or back to back is arranged at the bottom of the flat plate.

4. The efficient feeding device of polymer battery cells of claim 3, wherein the screw adjusting assembly comprises a forward screw and a reverse screw which are coaxially connected, the forward screw and the reverse screw are respectively provided with a connecting block which is in threaded fit with the forward screw and the reverse screw, and the positive guide plate is fixed on the connecting block corresponding to the positive guide plate through a supporting frame;

one end of the forward screw rod is provided with an adjusting wheel, and a handle is arranged on the adjusting wheel.

5. The efficient feeding device of polymer battery cells of any one of claims 1 to 4, wherein the feeding side of the guiding plate is provided with an outward-bent inclined guiding surface.

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