CN211276032U - Rolling groove device for nickel-metal hydride battery shell - Google Patents

Abstract

The utility model discloses a channeling device for nickel-hydrogen battery case, it includes: the material conveying mechanism is used for conveying the nickel-metal hydride battery shell; the material transferring mechanism comprises a material pushing mechanism and a rotating mechanism, the material pushing mechanism and the rotating mechanism are respectively arranged on two sides in front of the material conveying mechanism, and the material pushing mechanism is matched with the rotating mechanism and rotates the nickel-hydrogen battery shell conveyed by the material conveying mechanism; the roll-groove mechanism is arranged in front of the material transferring mechanism and used for roll-groove the nickel-metal hydride battery shell; and the material conveying mechanism, the material pushing mechanism, the rotating mechanism and the roller groove mechanism are respectively electrically connected with the control box. By adopting the design, the whole process of the rolling groove device is automatic, the labor cost is saved, and the efficiency of rolling the groove of the battery is greatly improved.

Description

Rolling groove device for nickel-metal hydride battery shell

Technical Field

The utility model relates to a nickel-metal hydride battery field especially relates to a channeling device for nickel-metal hydride battery shell.

Background

The rolling groove is arranged in the nickel-metal hydride battery shell and is mainly used for packaging the nickel-metal hydride battery and ensuring that the inner core of the nickel-metal hydride battery cannot come out, so that the rolling groove device for the nickel-metal hydride battery shell is an important machining device and influences the quality of the battery. The traditional channeling device has low production efficiency and can not meet the requirement of rapid production.

Accordingly, there is a need to design a roll groove device for a nickel-metal hydride battery case that solves one or more of the above problems.

SUMMERY OF THE UTILITY MODEL

In order to solve one or more problems existing in the prior art, the utility model provides a channeling device for nickel-hydrogen battery shell.

The utility model discloses a reach the technical scheme that above-mentioned purpose adopted and be: a channeling device for a nickel-metal hydride battery case, the channeling device comprising:

the material conveying mechanism is used for conveying the nickel-metal hydride battery shell;

the material transferring mechanism comprises a material pushing mechanism and a rotating mechanism, the material pushing mechanism and the rotating mechanism are respectively arranged on two sides in front of the material conveying mechanism, and the material pushing mechanism is matched with the rotating mechanism and rotates the nickel-hydrogen battery shell conveyed by the material conveying mechanism;

the roll-groove mechanism is arranged in front of the material transferring mechanism and used for roll-groove the nickel-metal hydride battery shell; and

the control box, defeated material mechanism the pushing equipment, slewing mechanism with the slot rolling mechanism respectively with control box electric connection.

In some embodiments, the feeding mechanism comprises:

the conveying channel is provided with a feeding hole, a discharging hole and an accommodating cavity, and the feeding hole and the discharging hole are respectively communicated with the accommodating cavity;

the coiling assembly comprises a coiling wheel and a coiling motor, the coiling wheel is arranged in the accommodating cavity, the coiling motor is arranged outside the accommodating cavity, and the coiling wheel is in transmission connection with the coiling motor; and

the conveying assembly comprises a conveying cylinder and a conveying seat, the conveying seat is fixedly connected with the conveying cylinder, and the conveying seat is arranged below the discharge port and used for receiving a nickel-metal hydride battery shell discharged from the discharge port and conveying the nickel-metal hydride battery shell to the material transferring mechanism.

In some embodiments, the side wall of the winding wheel is provided with a plurality of arc-shaped grooves, and the arc-shaped grooves are matched with the nickel-hydrogen battery shell.

In some embodiments, the carousel is "L" shaped.

In some embodiments, the pushing mechanism includes a pushing cylinder and a pushing seat, the pushing cylinder is fixedly connected to the pushing seat, and the pushing seat is matched with the conveying seat.

In some embodiments, a material pushing rod is arranged on the material pushing seat, a material pushing groove is arranged on the material pushing rod, and the material pushing groove is matched with the nickel-hydrogen battery shell.

In some embodiments, the rotating mechanism comprises a rotating motor and a rotating roller, and the rotating roller is in transmission connection with the rotating motor.

In some embodiments, the rotating roller is provided with a rotating groove, and the rotating groove is matched with the nickel-hydrogen battery shell.

In some embodiments, the channeling mechanism comprises a channeling cylinder and a channeling seat fixedly connected with the channeling cylinder.

In some embodiments, the rolling groove seat is provided with a rolling groove cutter, and the rolling groove cutter is rotatably connected with the rolling groove seat.

The utility model has the advantages that: compared with the prior art, the utility model discloses a: the material conveying mechanism is used for conveying the nickel-metal hydride battery shell; the material transferring mechanism comprises a material pushing mechanism and a rotating mechanism, the material pushing mechanism and the rotating mechanism are respectively arranged on two sides in front of the material conveying mechanism, and the material pushing mechanism is matched with the rotating mechanism and rotates the nickel-hydrogen battery shell conveyed by the material conveying mechanism; the roll-groove mechanism is arranged in front of the material transferring mechanism and used for roll-groove the nickel-metal hydride battery shell; and the material conveying mechanism, the material pushing mechanism, the rotating mechanism and the roller groove mechanism are respectively electrically connected with the control box. By adopting the design, the whole process of the rolling groove device is automatic, the labor cost is saved, and the efficiency of rolling the groove of the battery is greatly improved.

Drawings

FIG. 1 is a schematic structural diagram of a preferred embodiment of the present invention;

FIG. 2 is a schematic view of another perspective of the preferred embodiment of the present invention;

FIG. 3 is a schematic view of a feeding mechanism according to a preferred embodiment of the present invention;

FIG. 4 is a schematic cross-sectional view of a feeding mechanism according to a preferred embodiment of the present invention;

FIG. 5 is a schematic view of a pushing mechanism according to a preferred embodiment of the present invention;

fig. 6 is a schematic structural diagram of a rotating mechanism according to a preferred embodiment of the present invention.

In the figure:

10. a material conveying mechanism; 11. a feed inlet; 12. a discharge port; 13. a winding wheel; 14. a transfer base;

20. a material pushing mechanism; 21. a material pushing rod;

30. a rotating mechanism; 31. a rotating roller;

40. a roll groove mechanism; 41. and (4) a groove rolling cutter.

Detailed Description

In order to make the above objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

As shown in fig. 1 to 6, the present invention provides a roll-groove device for a nickel-metal hydride battery case, which is characterized in that the roll-groove device comprises:

the conveying mechanism 10 is used for conveying the nickel-metal hydride battery shell by the conveying mechanism 10;

the material transferring mechanism comprises a material pushing mechanism 20 and a rotating mechanism 30, the material pushing mechanism 20 and the rotating mechanism 30 are respectively arranged on two sides of the front of the material conveying mechanism 10, and the material pushing mechanism 20 is matched with the rotating mechanism 30 and rotates the nickel-metal hydride battery shell conveyed by the material conveying mechanism 10;

the roll-groove mechanism 40 is arranged in front of the material transferring mechanism, and is used for roll-groove the nickel-metal hydride battery shell; and

the material conveying mechanism 10, the material pushing mechanism 20, the rotating mechanism 30 and the rolling groove mechanism 40 are respectively and electrically connected with the control box.

Specifically, the whole production flow of this embodiment includes: the nickel-metal hydride battery shell to be rolled is placed into the feeding hole 11 of the material conveying mechanism 10 through a person or a machine, the nickel-metal hydride battery shell enters the accommodating cavity from the feeding hole 11, is clamped into the arc-shaped groove just facing the feeding hole 11, rotates to the outlet along with the rolling wheel 13, falls off from the outlet, falls onto the conveying seat 14 below, and the conveying cylinder pushes the conveying seat 14 to move forwards to a position between the material pushing mechanism 20 and the rotating mechanism 30. Then the material pushing cylinder pushes the material pushing seat to move towards the rotating mechanism 30, when the material pushing seat moves, the material pushing rod 21 pushes one end of the nickel-hydrogen battery shell to move towards the rotating roller 31, at the moment, one end of the nickel-hydrogen battery shell is inserted into the material pushing groove, and the other end of the nickel-hydrogen battery shell is inserted into the rotating roller 31. Meanwhile, the transfer base 14 returns to the original position along with the transfer cylinder, receives the nickel-hydrogen battery case dropped from the discharge port 12, and waits for the completion of the roll groove of the previous case. When the pushing rod 21 pushes the other end of the nickel-metal hydride battery shell into the rotating groove of the rotating roller 31, the rotating motor rotates, so that the rotating roller 31 rotates, and when the rotating roller 31 rotates, the rotating roller 31 drives the nickel-metal hydride battery shell to rotate. While the nickel-metal hydride battery case rotates, the roll-groove cylinder moves toward the nickel-metal hydride battery case against the roll-groove cutter 41 and rolls the case. After the rolling groove is finished, the rolling groove cylinder drives the rolling groove cutter 41 to return to the original position, the material pushing cylinder drives the material pushing seat to return to the original position, and the shell of the rolling groove falls to a material receiving area below the shell. And the transfer seat 14 sends the next shell to the position between the pushing mechanism 20 and the rotating mechanism 30 under the action of the transfer cylinder, and the next cycle is started. The time required by the whole slot rolling process is not more than one second, the speed is extremely high, and the production efficiency is greatly improved.

It should be noted that the ejection time and retraction time of the conveying cylinder, the pushing cylinder and the rolling slot cylinder are preset by the control box, and the rotation time of the coiling motor and the rotating motor is also preset. Therefore, each minute and each second can be utilized to the maximum extent, and the production efficiency is improved. As for the specific structure or circuit design of the control box, no improvement is made in this embodiment, and the operation of the control box for controlling the cylinder and the motor is already a very common technology, which is the prior art, and the related information can be easily obtained by those skilled in the art, so this embodiment will not be described in detail.

In some embodiments, the feeding mechanism 10 comprises:

the conveying channel is provided with a feeding hole 11, a discharging hole 12 and an accommodating cavity, and the feeding hole 11 and the discharging hole 12 are respectively communicated with the accommodating cavity;

the coiling assembly comprises a coiling wheel 13 and a coiling motor, the coiling wheel 13 is arranged in the accommodating cavity, the coiling motor is arranged outside the accommodating cavity, and the coiling wheel 13 is in transmission connection with the coiling motor; and

and the conveying assembly comprises a conveying cylinder and a conveying seat 14, the conveying seat 14 is fixedly connected with the conveying cylinder, and the conveying seat 14 is arranged below the discharge port 12 and used for receiving the nickel-metal hydride battery shell discharged from the discharge port 12 and conveying the nickel-metal hydride battery shell to the material transferring mechanism.

Specifically, the feed inlet 11 is arranged above the accommodating cavity, and the discharge outlet 12 is arranged below the accommodating cavity. The coil motor passes through the shell of the conveying channel and is in transmission connection with a coil wheel 13 positioned in the accommodating cavity. The casing enters from the inlet opening 11 and passes through the action of the roller 13, so that the casing falls directly from the outlet opening 12 onto the underlying transfer shoe 14 without changing direction. The function of the roller 13 is important here, so that it is avoided that the housing changes its direction from the inlet opening 11 to the outlet opening 12, which affects the subsequent operation. Meanwhile, the width of the feed inlet 11 and the discharge outlet 12 is preferably set to match with the shell, so that the position of the shell when the shell is placed on the conveying seat 14 is kept unchanged basically, and the pushing mechanism 20 is convenient to push the shell.

The feed openings 11 may also be provided in two, respectively in opposite directions. Because this embodiment channelling speed is very fast, and whole process is less than a second, therefore the speed of material loading may not be enough at some times, feeds from two feed inlets 11 this moment, can guarantee that whole production process can not stop.

When the housing comes out of the discharge port 12, the lower surface of the transfer base 14 is just below the discharge port 12. After the shell falls down, the conveying seat 14 conveys the shell to the material transferring mechanism, and the high surface of the conveying seat 14 just supports against the outlet of the discharge hole 12 at the moment, so that the shell above the conveying seat is prevented from falling down. It should be noted that the width of the conveying seat 14 is smaller than the length of the casing, and when the casing falls onto the conveying seat 14, one end of the casing facing the pushing mechanism 20 is located outside the conveying seat 14, so that the pushing mechanism 20 can push the casing towards the rotating mechanism 30.

In some embodiments, the side wall of the winding wheel 13 is provided with a plurality of arc-shaped grooves, and the arc-shaped grooves are matched with the nickel-hydrogen battery shell.

Specifically, the arcuate slots are uniformly circumferentially arrayed on the spool 13. The winding wheel 13 can make the housing move orderly without changing direction. Without this reel 13, for example, the casing may move down first or last during the movement, resulting in a situation in which the casing is not easily pushed by the pusher mechanism 20 when it is dropped onto the transfer seat 14.

In some embodiments, the transfer block 14 is "L" shaped.

Specifically, the conveying base 14 is like a step, a plane lower by a little is called a low plane and is used for receiving the casing, and a plane higher by a little is called a high plane and is used for blocking the outlet of the discharge hole 12, so that the rest of the casing is prevented from coming out of the discharge hole 12 when the conveying base 14 conveys the casing to the material transferring mechanism. In order to avoid the housing from rolling off the transfer base 14, a layer of friction-increasing anti-slip material may be provided on the transfer base 14, or an arc-shaped groove may be provided slightly on the lower surface.

In some embodiments, the pushing mechanism 20 includes a pushing cylinder and a pushing seat, the pushing cylinder and the pushing seat are fixedly connected, and the pushing seat is matched with the conveying seat 14.

In some embodiments, a material pushing rod 21 is arranged on the material pushing seat, and a material pushing groove is arranged on the material pushing rod 21 and is matched with the nickel-hydrogen battery shell.

Specifically, after the transporting base 14 transports the housing to the set position, the pushing rod 21 pushes the housing toward the rotating roller 31, so that the open end of the housing is inserted into the rotating groove and the end of the housing is inserted into the pushing groove. Wherein the material pushing groove is a circular groove, and the rotating groove is an annular groove. The diameter of the material pushing groove is as large as that of the shell.

In some embodiments, the rotating mechanism 30 includes a rotating motor and a rotating roller 31, and the rotating roller 31 is in transmission connection with the rotating motor.

In some embodiments, the rotating roller 31 is provided with a rotating groove, and the rotating groove is matched with the nickel-hydrogen battery shell.

Specifically, in order to facilitate the rotation of the rotating roller 31 to drive the housing, the side wall of the rotating groove close to the axis of the rotating roller 31 is slightly convex, that is, when the housing is just inserted into the rotating groove, the diameter of the side wall of the rotating groove close to the axis is not larger than that of the housing, and when the housing continues to enter towards the inside of the rotating groove, the housing is obstructed, because the diameter of the side wall of the rotating groove close to the axis is slightly larger than that of the housing at the moment, but under the thrust action of the material pushing rod 21, the housing is inserted into the bottom of the rotating groove. At this time, the rotating roller 31 rotates to rotate the housing.

In some embodiments, the roll-groove mechanism 40 includes a roll-groove cylinder and a roll-groove seat fixedly connected to the roll-groove cylinder.

In some embodiments, the rolling slot seat is provided with a rolling slot cutter 41, and the rolling slot cutter 41 is rotatably connected with the rolling slot seat.

Specifically, the hobbing cutter 41 is the prior art, and the structure of the existing hobbing cutter 41 can be referred to. Of course, the cylinders or motors can be fixed on the ground or on a frame, which is common knowledge, and therefore the fixing mode is not described in this embodiment.

To sum up, the utility model comprises a material conveying mechanism 10, wherein the material conveying mechanism 10 is used for conveying nickel-hydrogen battery shells; the material transferring mechanism comprises a material pushing mechanism 20 and a rotating mechanism 30, the material pushing mechanism 20 and the rotating mechanism 30 are respectively arranged on two sides of the front of the material conveying mechanism 10, and the material pushing mechanism 20 is matched with the rotating mechanism 30 and rotates the nickel-metal hydride battery shell conveyed by the material conveying mechanism 10; the roll-groove mechanism 40 is arranged in front of the material transferring mechanism, and is used for roll-groove the nickel-metal hydride battery shell; and the material conveying mechanism 10, the material pushing mechanism 20, the rotating mechanism 30 and the slot rolling mechanism 40 are respectively and electrically connected with the control box. By adopting the design, the whole process of the rolling groove device is automatic, the labor cost is saved, and the efficiency of rolling the groove of the battery is greatly improved.

The above-described embodiments are merely illustrative of one or more embodiments of the present invention, and the description thereof is more specific and detailed, but the scope of the invention is not limited thereto. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A channeling device for a nickel-metal hydride battery case, the channeling device comprising:

the material conveying mechanism is used for conveying the nickel-metal hydride battery shell;

the material transferring mechanism comprises a material pushing mechanism and a rotating mechanism, the material pushing mechanism and the rotating mechanism are respectively arranged on two sides in front of the material conveying mechanism, and the material pushing mechanism is matched with the rotating mechanism and rotates the nickel-hydrogen battery shell conveyed by the material conveying mechanism;

the roll-groove mechanism is arranged in front of the material transferring mechanism and used for roll-groove the nickel-metal hydride battery shell; and

the control box, defeated material mechanism the pushing equipment, slewing mechanism with the slot rolling mechanism respectively with control box electric connection.

2. The roll-groove apparatus for nickel-metal hydride battery cases as claimed in claim 1, wherein the feeding mechanism comprises:

the conveying channel is provided with a feeding hole, a discharging hole and an accommodating cavity, and the feeding hole and the discharging hole are respectively communicated with the accommodating cavity;

the coiling assembly comprises a coiling wheel and a coiling motor, the coiling wheel is arranged in the accommodating cavity, the coiling motor is arranged outside the accommodating cavity, and the coiling wheel is in transmission connection with the coiling motor; and

the conveying assembly comprises a conveying cylinder and a conveying seat, the conveying seat is fixedly connected with the conveying cylinder, and the conveying seat is arranged below the discharge port and used for receiving a nickel-metal hydride battery shell discharged from the discharge port and conveying the nickel-metal hydride battery shell to the material transferring mechanism.

3. The slot rolling device for the nickel-metal hydride battery shell as claimed in claim 2, wherein the side wall of the winding wheel is provided with a plurality of arc-shaped slots, and the arc-shaped slots are matched with the nickel-metal hydride battery shell.

4. The roll groove device for the nickel-metal hydride battery case as claimed in claim 3, wherein the transfer seat is "L" shaped.

5. The roll-groove device for the nickel-metal hydride battery shell as claimed in claim 4, wherein the pushing mechanism comprises a pushing cylinder and a pushing seat, the pushing cylinder is fixedly connected with the pushing seat, and the pushing seat is matched with the conveying seat.

6. The roll-groove device for nickel-metal hydride battery shells as claimed in claim 5, wherein the pushing base is provided with a pushing rod, the pushing rod is provided with a pushing groove, and the pushing groove is matched with the nickel-metal hydride battery shells.

7. The channeling device for a nickel-metal hydride battery case as claimed in claim 6, wherein the rotating mechanism comprises a rotating motor and a rotating roller, and the rotating roller is in transmission connection with the rotating motor.

8. The roll groove device for the nickel-metal hydride battery case as claimed in claim 7, wherein the rotating roller is provided with a rotating groove, and the rotating groove is matched with the nickel-metal hydride battery case.

9. The roll-groove device for the nickel-metal hydride battery shell as claimed in claim 8, wherein the roll-groove mechanism comprises a roll-groove cylinder and a roll-groove seat, and the roll-groove seat is fixedly connected with the roll-groove cylinder.

10. The roll-groove device for the nickel-metal hydride battery shell as claimed in claim 9, wherein a roll-groove cutter is arranged on the roll-groove seat, and the roll-groove cutter is rotatably connected with the roll-groove seat.

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