CN211810461U - Battery case direction dividing device - Google Patents

Abstract

The battery shell branching device comprises a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism. The battery shell branching device comprises a driving source, a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice of the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism, and a driving source for driving the battery shell to move forwards is arranged on the base plate. The utility model has the advantages of simple structure, divide fast, divide to accurate, the cost is lower. The utility model belongs to the technical field of the battery case is made.

Description

Battery case direction dividing device

Technical Field

The utility model belongs to the technical field of the battery case is made, especially, relate to a battery case branch device.

Background

After the battery case is manufactured, the battery case needs to be boxed and packaged for transportation, sale and subsequent manufacturing. The manufactured battery shell is cylindrical, the bottom end of the battery shell is sealed, and the top end of the battery shell is opened. When boxing the battery case, generally need be with battery case open-ended one end towards the bottom of the case, battery case open-ended one end up, neatly vanning like this, on one hand save space and neatly pleasing to the eye, on the other hand also be favorable to the obvious defective products of naked eye short-term test battery case when vanning and acceptance. However, the battery cases are packed in the box in such an orderly manner, which completely depends on manual work at present, and the battery cases need to be packed after being oriented manually, so that the degree of automation of the operation is low, the operation is troublesome, and the cost is high.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a battery case branch device, it has simple structure, divide fast, divide to accurate, advantage such as the cost is lower.

The battery shell branching device comprises a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism.

Further, the inclination angle of the substrate is 40 to 60 degrees.

The battery shell branching device comprises a driving source, a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice of the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism, and a driving source for driving the battery shell to move forwards is arranged on the base plate.

Furthermore, the driving source is a driving cylinder, the driving cylinder is arranged on the substrate, a shell pushing plate is arranged between the two magnetic mechanisms, and the driving cylinder is connected with the shell pushing plate.

Further, magnetic mechanism includes magnetic path, stopper and pushes away the magnetism cylinder, and the stopper is installed on the base plate, pushes away the outside that the magnetism cylinder located the stopper, pushes away the magnetism cylinder and connects with the magnetic path, and the inboard of stopper is arranged in to the magnetic path.

Furthermore, the lower end of the limiting block is provided with a groove; the magnetic blocks comprise a transverse magnetic block and a vertical magnetic block which are vertically connected; the transverse magnetic block extends into the groove, the vertical magnetic block is arranged on the outer side of the groove, and the height of the vertical magnetic block is larger than that of the groove.

Further, the gate mechanism comprises a gate, a gate frame and a gate cylinder, the gate frame is installed at the tail end of the magnetic mechanism, the gate cylinder is installed on the gate frame, and the gate cylinder is connected with the gate.

The device further comprises an independent channel mechanism, wherein the independent channel mechanism comprises an independent plate, side plates and a sliding plate, the side plates are symmetrically arranged on two sides of the independent plate, and the positions of the side plates correspond to those of the magnetic mechanism; a sliding plate is arranged between the two side plates.

Furthermore, the number of the sliding plates is two, and the two sliding plates are respectively arranged on two sides of a central line between the two side plates; two transverse grooves are formed in two sides of a center line between the two side plates, and the sliding plate is installed in the transverse groove in one side of the center line in a sliding mode through the clamping columns.

The utility model has the advantages that: the utility model discloses a set up symmetrical magnetic mechanism on the base plate, through between two magnetic mechanisms on pushing the battery case into the base plate, the push-and-pull of rethread magnetic mechanism, because the battery case receives different pulling force size at both ends, thereby make the bottom towards different battery cases be caught by the magnetic mechanism of different sides, realize the branch direction to the battery case, consequently the utility model discloses realize that the battery case divides to process simple, success rate is high, efficient; secondly, the base plate is arranged obliquely, so that a power source is not needed, energy can be saved, and cost can be reduced; the utility model discloses set up gate mechanism at the end of base plate, through gate mechanism's lift, can block the battery case, divide and release backward again, avoid follow-up battery case not yet to get into next process, battery case on the base plate just divides to get into, and then avoids the production process to produce the disorder, consequently the utility model discloses it is more stable to divide to the process.

Drawings

Fig. 1 is a schematic structural diagram of a first viewing angle according to a first embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a second viewing angle according to the first embodiment of the present invention.

The device comprises a substrate 1, a magnetic mechanism 2, a gate mechanism 3, an independent channel mechanism 4, a magnetic pushing cylinder 5, a gate 6, a side plate 7, an independent plate 8, a sliding plate 9, a transverse groove 10, a magnetic block 11, a transverse magnetic block 12, a groove 13, a limiting block 14, a vertical magnetic block 15, a gate cylinder 16 and a gate frame 17.

Detailed Description

The present invention will be further specifically described with reference to the accompanying drawings.

The first embodiment is as follows:

the cell shell direction dividing device comprises a base plate, a magnetic mechanism and a gate mechanism. The substrate is disposed obliquely, that is, the height of the upper end of the substrate is higher than the height of the lower end of the substrate. The two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism.

In this embodiment, the inclination angle of the substrate is 40 to 60 degrees, so that the battery slides downwards by utilizing the inclined component of gravity when the battery is on the substrate, and therefore, a power source is not needed, and energy is saved.

The magnetic mechanism comprises a magnetic block, a limiting block and a magnetic pushing cylinder. The limiting block is rectangular, a groove is formed in the lower end of the limiting block, and the groove is a cuboid groove. The limiting block is arranged on the substrate, and a channel through which the magnetic block passes is formed between the groove of the limiting block and the substrate. The magnetic blocks comprise a transverse magnetic block and a vertical magnetic block; the horizontal magnetic block and the vertical magnetic block are vertically connected. The height of the vertical magnetic block is greater than that of the groove; the height of the transverse magnetic block is lower than that of the groove. The transverse magnetic block extends into the groove, and the vertical magnetic block is arranged on the outer side of the groove; the vertical magnetic block is clamped on the outer side of the limiting block through the groove, and the transverse magnetic block penetrates through the groove and can slide in the transverse direction of the substrate. The magnetic pushing cylinder is arranged on the outer side of the limiting block, and a piston rod of the magnetic pushing cylinder is connected with the vertical magnetic block of the magnetic block. The magnetic block can be pulled to move in the transverse direction of the substrate by pushing and pulling the magnetic pushing cylinder.

In the present embodiment, the magnetic force mechanisms include a left-side magnetic force mechanism and a right-side magnetic force mechanism. The left magnetic mechanism and the right magnetic mechanism are arranged on the substrate in a bilateral symmetry manner. The left magnetic mechanism and the right magnetic mechanism have the same structure, and only the transverse magnetic block of the magnetic block has different length.

The gate mechanism includes a gate, a gate frame, and a gate cylinder. The gate frame is arranged at the tail end of the magnetic mechanism, and the width of the gate frame is larger than that between the limiting blocks at the two sides. The gate cylinder is installed on the top of the gate frame. And a piston rod of the gate cylinder is connected with the gate. The gate cylinder pushes the gate to ascend or descend. When the gate descends, the lower end between the two limiting blocks is blocked by the gate, so that the battery shell between the two entering magnetic mechanisms is blocked, and the magnetic mechanisms can conveniently suck the battery shell. When the gate rises, the channel between the limiting blocks is conveniently opened, so that the divided battery shell is discharged from between the two magnetic mechanisms, and the battery shell enters the downstream.

In this embodiment, an independent channel mechanism is further included. The independent channel mechanism is arranged at the downstream of the substrate and the magnetic mechanism. Specifically, the independent channel mechanism includes an independent plate, a side plate, and a sliding plate. The independent plate is obliquely arranged and independently keeps the same inclination angle and direction as the substrate. The upper end of the independent plate is connected with the base plate. The both sides of independent board set up the symmetry and set up the curb plate, and curb plate and stopper butt joint also meet with the stopper in the upper end of curb plate. Two sliding plates are arranged between the two side plates. The center line between the two side plates is used as a boundary line, and both sides of the boundary line are provided with transverse grooves. Each side of the boundary is provided with two parallel transverse grooves. The transverse grooves on both sides of the boundary are staggered with each other. The bottom of the sliding plate is provided with two clamping columns, two clamping columns are arranged below one sliding plate, and the distance between the clamping columns is the same as the distance between the two transverse grooves on one side of the boundary. The card post is embedded into corresponding horizontal inslot, and the slide is done the slip of horizontal direction in the horizontal inslot through the card post to change the width between slide and the curb plate. During the in-service use, according to the length of battery case, adjust the distance between slide and the curb plate to make the battery case of this side roll into in the independent passageway that corresponds on the independent board when rolling downstream, carry on spacingly through slide and curb plate to the battery case, avoid the rolling orbit of battery case to appear the deviation, and the upset has already divided good to the battery.

The utility model discloses a working process: the gate mechanism firstly puts down the gate, the lower end of the gate is propped against the substrate, and the gate forms a barrier for a channel between the two limit blocks; according to the length of the battery case, the positions of the transverse magnetic blocks of the magnetic blocks are adjusted, so that the distance between the transverse magnetic blocks on the two sides is more than twice the length of the battery case, the battery case is convenient to move backwards, and the distance between the two magnetic mechanisms can accommodate two rows of battery cases facing different directions; pushing a row of battery cases from the upper end of the substrate (namely, an inlet between the two magnetic mechanisms), and rolling the battery cases between the two limiting blocks along the inclined substrate until all the battery cases roll into the substrate; at the moment, the bottom ends of the battery cases face to the limiting blocks on different sides, the magnetic blocks on two sides of the battery cases are pushed to gradually approach the battery cases on the base plate, and the magnetic force on the two sides of one battery case is different due to the fact that the two sides of the battery case form magnetic attraction on the battery cases, the bottom ends of the battery cases are sealed, the top ends of the battery cases are opened, the magnetic force on the two sides of one battery case is different, according to physics knowledge, the magnetic attraction area of the bottom ends of the battery cases is large, the magnetic force on the bottom ends of the battery cases is larger, the magnetic force on the top ends of the battery cases is smaller than that on the bottom ends of the battery cases, the bottom ends of; along with the proceeding of the direction division, the battery cases with the bottom ends facing to the left side can form a row of battery cases sucked by the magnetic mechanism on the left side, the battery cases with the bottom ends facing to the right side can form a row of battery cases sucked by the magnetic mechanism on the right side, and then the magnetic blocks are pulled outwards through the magnetic pushing cylinders on the two sides, so that the two rows of battery cases which are well divided can be better and independently opened; then, adjusting the sliding plate of the independent channel mechanism to ensure that the distance between the sliding block and the side plate is the same as the width of the corresponding battery case of the upper substrate; and then, lifting a gate of the gate mechanism, enabling the gate to leave the substrate, rolling the divided battery shell downwards into the independent channel mechanism, and then entering a downstream boxing process through the independent channel mechanism.

Example two:

in the present embodiment, only the base plate is not disposed obliquely, and the movement of the battery case is driven by applying the driving source. Otherwise, all the parts are the same as the first embodiment, and the description of the same parts is omitted.

The battery shell branching device comprises a driving source, a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice of the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism, and a driving source for driving the battery shell to move forwards is arranged on the base plate.

In this embodiment, the driving source is a driving cylinder, the driving cylinder is disposed on the substrate, a shell pushing plate is disposed between the two magnetic mechanisms, and the driving cylinder is connected with the shell pushing plate.

When the battery case is operated, the battery case is pushed to roll on the substrate by the driving source, and when the battery case completely rolls between the two magnetic mechanisms on the substrate, the direction of the battery case is divided by the magnetic mechanisms.

The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited to the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be equivalent replacement modes, and all are included in the scope of the present invention.

Claims (9)

1. Battery case branching device, its characterized in that: comprises a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism.

2. The battery case switching device of claim 1, wherein: the inclination angle of the substrate is 40 to 60 degrees.

3. Battery case branching device, its characterized in that: the device comprises a driving source, a substrate, a magnetic mechanism and a gate mechanism; the two magnetic mechanisms are symmetrically arranged on the substrate, and the distance between the two magnetic mechanisms is more than twice of the length of the battery shell; the gate mechanism is arranged at the tail end of the magnetic mechanism, and a driving source for driving the battery shell to move forwards is arranged on the base plate.

4. The battery case diverter according to claim 3, wherein: the driving source is a driving cylinder, the driving cylinder is arranged on the substrate, a shell pushing plate is arranged between the two magnetic mechanisms, and the driving cylinder is connected with the shell pushing plate.

5. The battery case diverter according to any one of claims 1-4, wherein: the magnetic mechanism comprises a magnetic block, a limiting block and a magnetic pushing cylinder, the limiting block is installed on the substrate, the magnetic pushing cylinder is arranged on the outer side of the limiting block and connected with the magnetic block, and the magnetic block is arranged on the inner side of the limiting block.

6. The battery case switching device of claim 5, wherein: the lower end of the limiting block is provided with a groove; the magnetic blocks comprise a transverse magnetic block and a vertical magnetic block which are vertically connected; the transverse magnetic block extends into the groove, the vertical magnetic block is arranged on the outer side of the groove, and the height of the vertical magnetic block is larger than that of the groove.

7. The battery case diverter device according to any one of claims 1-4, wherein: the gate mechanism comprises a gate, a gate frame and a gate cylinder, the gate frame is arranged at the tail end of the magnetic mechanism, the gate cylinder is arranged on the gate frame, and the gate cylinder is connected with the gate.

8. The battery case diverter device according to any one of claims 1-4, wherein: the magnetic force mechanism is characterized by further comprising an independent channel mechanism, wherein the independent channel mechanism comprises an independent plate, side plates and a sliding plate, the side plates are symmetrically arranged on two sides of the independent plate, and the side plates correspond to the magnetic force mechanism in position; a sliding plate is arranged between the two side plates.

9. The battery case diverter according to claim 8, wherein: the two sliding plates are respectively arranged on two sides of a central line between the two side plates; two transverse grooves are formed in two sides of a center line between the two side plates, and the sliding plate is installed in the transverse groove in one side of the center line in a sliding mode through the clamping columns.

Images