CN210884118U - Cylinder battery detection production line and separating device - Google Patents

Abstract

The utility model belongs to the technical field of lithium cell manufacturing, especially, relate to a cylinder battery detects production line and separator, separator includes: a base; the supporting seat is arranged on the base in a sliding mode and used for bearing and placing the plurality of cylindrical batteries; the separating mechanism comprises an installation frame and a plurality of separating blocks, the separating blocks are movably arranged on the installation frame, and two adjacent separating blocks are linked; the first driving mechanism is connected with the mounting frame, the second driving mechanism is connected with the supporting seat, the second driving mechanism drives the supporting seat to move from the third position to the fourth position, the separating blocks are driven to be separated simultaneously, and then the separating blocks drive the corresponding cylindrical batteries to be separated, so that the cylindrical batteries which are closely arranged are separated on the supporting seat at equal intervals. The separating device is simple in overall structure, convenient and fast to operate, compact in structure and low in manufacturing cost.

Description

Cylinder battery detection production line and separating device

Technical Field

The utility model belongs to the technical field of lithium cell manufacturing, especially, relate to a cylinder battery centre gripping production line and separator.

Background

Lithium batteries have been widely used because of their high storage capacity, light weight, energy conservation and environmental protection. The lithium cell need carry out each item quality inspection after production is accomplished, and many inspection projects need to separate closely a plurality of cylindrical lithium cells of arranging equidistant, then the conveying, however current separation equipment structure is complicated, complex operation, and the cost of manufacture is high, and is difficult to separate a plurality of closely cylindrical lithium cells of arranging equidistant simultaneously.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a separator aims at solving the technical problem that the equipment structure is complicated, complex operation, cost of manufacture are high are separated to the cylinder battery among the prior art.

In order to achieve the above object, the utility model adopts the following technical scheme: a partitioning device for partitioning a plurality of cylindrical batteries, which are arranged closely, at equal intervals, the partitioning device comprising:

a base;

the supporting seat is arranged on the base in a sliding mode and can do reciprocating linear motion on the base along a first direction, and the supporting seat is used for bearing and placing a plurality of cylindrical batteries;

the separating mechanism comprises a mounting frame and a plurality of separating blocks, the mounting frame is arranged on the base in a sliding mode and can do reciprocating linear motion on the base along a second direction, the second direction is perpendicular to the first direction, the plurality of separating blocks are movably arranged on the mounting frame, and two adjacent separating blocks are linked;

the first driving mechanism is connected with the mounting rack to drive the mounting rack to do reciprocating linear motion along the second direction and drive the separating blocks to do reciprocating linear motion between a first position and a second position, and when the separating blocks are located at the first position, the second driving mechanism is connected with the supporting seat to drive the supporting seat to do reciprocating linear motion along the first direction so as to drive the supporting seat to move from a third position to a fourth position;

when the supporting seat is located at the third position, the plurality of cylindrical batteries are closely arranged, each separating block is located at the first position and abuts against the corresponding cylindrical battery on the supporting seat, the second driving mechanism drives the supporting seat to move from the third position to the fourth position, and drives each separating block to simultaneously separate, so that each separating block drives the corresponding cylindrical battery to separate, and the plurality of closely arranged cylindrical batteries are equally spaced on the supporting seat.

Furthermore, the separation mechanism further comprises a plurality of limiting blocks, one limiting block is movably inserted between two adjacent separation blocks, and each separation block is linked through the plurality of limiting blocks, so that the support base is driven to be separated from the third position to the fourth position, and then the corresponding cylindrical batteries are driven to be separated from the support base at equal intervals.

Furthermore, the side surface of each separating block, which is close to the supporting seat, is recessed to form an arc-shaped surface, and when the separating blocks abut against the corresponding cylindrical battery, the arc-shaped surfaces are attached to the circumferential side surface of one side of the cylindrical battery in a matching manner.

Furthermore, two adjacent limiting blocks are arranged in a staggered mode.

Furthermore, the limiting block is cylindrical, limiting rings are respectively arranged at two ends of the limiting block, sliding grooves are formed in the separating blocks along the first direction, limiting edges are arranged at one ends of the sliding grooves of the separating blocks, two ends of the limiting block are respectively inserted into the sliding grooves of the two adjacent separating blocks in a sliding mode, and when the separating blocks are completely separated, the limiting rings at two ends of the limiting block are respectively abutted to the limiting edges of the two adjacent separating blocks.

Furthermore, the separating mechanism further comprises two guide rods which are arranged on the mounting frame in parallel at intervals, the guide rods penetrate through the separating blocks, the separating blocks at the head end are fixed on the mounting frame, and the supporting seat abuts against the separating blocks at the tail end when located at the third position and can drive the separating blocks at the tail end to slide on the guide rods, so that the limiting blocks drive the rest separating blocks to slide on the guide rods.

Further, the supporting seat includes that backup pad, interval are located two limiting plates and connecting block in the backup pad, the backup pad with base sliding connection, two the limiting plate with the top surface of backup pad forms the transfer passage of width adaptation cylinder battery jointly, the one end of connecting block is fixed in the one end of backup pad, the other end of connecting block extends to in the mounting bracket and with terminal the branch is divided the piece and is connected fixedly.

Furthermore, a groove is formed in the concave top surface of the supporting plate, a magnetic block is arranged in the groove, and the top surface of the magnetic block is flush with or lower than the top surface of the supporting plate.

Another object of the utility model is to provide a cylinder battery detects production line, including above-mentioned separator.

Furthermore, the cylindrical battery detection production line also comprises a hopper, a battery thumb wheel, a blanking pushing mechanism, a posture correcting mechanism and a feeding pushing mechanism, the bottom of the hopper is provided with a mounting groove which is adapted to accommodate the battery thumb wheel, the battery thumb wheel is rotatably mounted in the mounting groove, the circumferential side wall of the battery thumb wheel is evenly provided with accommodating grooves which are matched with the cylindrical batteries at intervals, a notch communicated with the mounting groove is arranged at the position of the hopper close to the bottom so that the cylindrical battery in the accommodating groove can fall to the material pushing position of the blanking material pushing mechanism through the notch, the blanking pushing mechanism pushes the cylindrical battery positioned at the pushing position to the posture correcting mechanism, the posture correcting mechanism is used for correcting the cylindrical battery to be in an upright state and conveying the cylindrical battery to the pushing position of the feeding pushing mechanism, and the feeding and pushing mechanism is used for pushing the cylindrical batteries at the material pushing position to the supporting seat of the separating device.

The utility model has the advantages that: the utility model discloses a separator, the activity is provided with a plurality of minutes spacer blocks on the mounting bracket, links between each minute spacer block, and second actuating mechanism drives and separates the spacer block and removes on the mounting bracket, and each minute spacer block drives the cylindrical battery that corresponds on the supporting seat and removes, makes closely a plurality of cylindrical batteries of arranging equidistant ground separated on the supporting seat, separator overall structure simple, the simple operation, and compact structure, occupation space is little, and the cost of manufacture is low.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic structural diagram of a cylindrical battery detection production line provided in an embodiment of the present invention;

FIG. 2 is a first schematic view of a part of the structure of the cylindrical battery inspection line shown in FIG. 1;

FIG. 3 is a schematic top view of a separator in the cylindrical battery inspection line shown in FIG. 1;

FIG. 4 is a schematic top view of the partition of FIG. 3 in another state;

FIG. 5 is a schematic partially exploded view of the spacer shown in FIG. 3;

FIG. 6 is a schematic view of a portion of the partition of FIG. 1;

FIG. 7 is a schematic view of the structure of a spacer block in the spacer apparatus shown in FIG. 1;

FIG. 8 is a schematic view of a support base of the spacer shown in FIG. 3;

fig. 9 is a schematic view of a part of the structure of the cylindrical battery inspection line shown in fig. 1.

Wherein, in the figures, the respective reference numerals:

100-a base; 200-a support seat; 300-a separation mechanism; 400-a hopper; 500-battery thumb wheel; 600-a blanking and pushing mechanism; 700-posture correcting mechanism; 800-feeding and pushing mechanism; 900-cylindrical battery; 110 — a first drive mechanism; 120-a second drive mechanism; 130-a cylinder housing; 210-a support plate; 220-a first limiting plate; 230-a second limiting plate; 240-connecting block; 250-magnetic blocks; 310-a mounting frame; 320-a spacer block; 330-a limiting block; 321-a chute; 322-a retainer ring; 323-arc surface; 331-a limit ring; 340-a guide bar; 350-a fixing plate; 410-installation groove.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

As shown in fig. 1-3, the embodiment of the utility model provides a separator for a plurality of cylinder batteries 900 with closely arranging are separated equidistantly, and a plurality of cylinder batteries 900 after the separation are a style of calligraphy and arrange, and cylinder battery 900 can but not only be the cylinder lithium cell. The spacer includes a base 100, a support base 200, a spacer mechanism 300, a first driving mechanism 110, and a second driving mechanism 120. The supporting base 200 is slidably disposed on the base 100, the supporting base 200 can perform a linear reciprocating motion on the base 100 along a first direction (direction F1 in fig. 3), and the supporting base 200 is used for bearing and placing a plurality of cylindrical batteries 900. The partition mechanism 300 includes a mounting frame 310 and a plurality of partition blocks 320, the mounting frame 310 is slidably disposed on the base 100, the mounting frame 310 is capable of performing a reciprocating linear motion on the base 100 along a second direction (direction F2 in fig. 3), the second direction is perpendicular to the first direction, the plurality of partition blocks 320 are movably disposed on the mounting frame 310, and two adjacent partition blocks 320 are linked. The first driving mechanism 110 and the second driving mechanism 120 may both adopt an air cylinder, the second driving mechanism 120 may be covered with an air cylinder cover 130, or adopt a linear motor, the first driving mechanism 110 is connected with the mounting bracket 310 for driving the mounting bracket 310 to make a reciprocating linear motion along the second direction and driving each separating block 320 to make a reciprocating motion between the first position and the second position, the second driving mechanism 120 is connected with the supporting seat 200 for driving the supporting seat 200 to make a reciprocating linear motion along the first direction, and the second driving mechanism 120 may drive the supporting seat 200 to move from the third position to the fourth position. When the supporting seat 200 is located at the third position, the plurality of cylindrical batteries 900 are closely arranged on the supporting seat 200, and each separating block 320 is located at the first position and supports each corresponding cylindrical battery 900 against the supporting seat 200; the second driving mechanism 120 drives the supporting base 200 to move from the third position to the fourth position, and drives the separating blocks 320 to separate simultaneously, so that the separating blocks 320 drive the corresponding cylindrical batteries 900 to separate, and the plurality of tightly arranged cylindrical batteries 900 are equally spaced on the supporting base 200. That is, the second driving mechanism 120 can drive the separating blocks 320 to move on the mounting frame 310 when moving, so that the separating blocks 320 are close to or separated from each other, and thus the cylindrical batteries 900 can be driven to be separated at equal intervals, after the cylindrical batteries 900 are separated on the supporting seat 200, the separating blocks 320 are separated from the cylindrical batteries 900, so that the cylindrical batteries 900 can be taken away from the supporting seat 200.

According to the separating device provided by the embodiment, the mounting frame 310 is movably provided with the plurality of separating blocks 320, the separating blocks 320 are linked, the second driving mechanism 120 drives the separating blocks 320 to move on the mounting frame 310, and the separating blocks 320 drive the corresponding cylindrical batteries 900 on the supporting seat 200 to move, so that the plurality of cylindrical batteries 900 which are closely arranged are separated on the supporting seat 200 at equal intervals.

In an embodiment, as shown in fig. 3 and 4, the separating mechanism 300 further includes a plurality of limiting blocks 330, one limiting block 330 is movably inserted between two adjacent separating blocks 320, and each separating block 320 is linked by the plurality of limiting blocks 330, so that the movement of the separating block 320 at the end can drive the other separating blocks 320 to be dispersed or gathered. When the supporting base 200 moves from the third position to the fourth position, the supporting base 200 drives the corresponding cylindrical batteries 900 to be equally spaced by the separating blocks 320.

In an embodiment, as shown in fig. 3, 5 and 6, an arc-shaped surface 323 is formed by recessing a side surface of each of the separating blocks 320 close to the supporting seat 200, and when the separating blocks 320 abut against the corresponding cylindrical battery 900, the arc-shaped surface 323 abuts against a circumferential side surface of one side of the cylindrical battery 900. The curvature of the arc-shaped surface 323 on the separating block 320 is equal to the curvature of the outer peripheral wall of the cylindrical battery 900, when the separating block 320 abuts against the cylindrical battery 900, the arc-shaped surface 323 is tightly attached to one side of the cylindrical battery 900, and the width of the arc-shaped surface 323 is smaller than the diameter of the cylindrical battery 900.

In an embodiment, as shown in fig. 4 to 6, two adjacent limiting blocks 330 are disposed in a staggered manner, two rows of limiting blocks 330 may be disposed on the mounting frame 310, a plurality of limiting blocks 330 in each row are arranged in a straight line, each separating block 320 is divided into two groups, and a plurality of limiting blocks 330 in each group are arranged in a straight line. It is understood that the number of rows of the stopper 330 may be set to be greater than two, and the arrangement of the stopper 330 in the plurality of rows may increase the stability and the separation accuracy when the separation blocks 320 are separated.

In an embodiment, as shown in fig. 5 and 6, the limiting block 330 is cylindrical, two ends of the limiting block 330 are respectively provided with a limiting ring 331, and the limiting block 330 has a structure with a small middle and two large ends; each separating block 320 is provided with a sliding groove 321 along a first direction, a limiting edge is arranged at one end of the sliding groove 321 of each separating block 320, two ends of each limiting block 330 are respectively inserted into the sliding grooves 321 of two adjacent separating blocks 320 in a sliding manner, and when each separating block 320 is completely separated, the limiting rings 331 at two ends of each limiting block 330 respectively abut against the limiting edges on two adjacent separating blocks 320.

That is, two ends of the limiting block 330 in the length direction respectively protrude outwards to form a limiting ring 331, and the diameter of the limiting ring 331 is adapted to the sliding groove 321; the limit edges on the separating blocks 320 form annular retainer rings 322, when each separating block 320 is completely unfolded, the limit rings 331 at the two ends of the limit blocks 330 abut against the limit edges, and the size and specification of each limit block 330 are the same, so that each cylindrical battery 900 can be driven to realize equal-interval separation. The separation distance of the cylindrical battery 900 is determined by the length of the limiting block 330, and when the separation distance needs to be changed, the limiting block 330 with the corresponding length can be replaced.

The top surface of the separating block 320 is opened corresponding to the position of the sliding groove 321, the top surface of the separating block 320 is detachably provided with a fixing plate 350, the fixing plate 350 covers the opening at the top of the sliding groove 321, and the size of the mounting plate is matched with that of the separating block 320.

In an embodiment, as shown in fig. 2 to 4, the separating mechanism 300 further includes two guide rods 340 disposed on the mounting frame 310 in parallel at intervals, the guide rods 340 pass through the separating blocks 320, the separating block 320 at the head end is fixed on the mounting frame 310, and the supporting seat 200 abuts against the separating block 320 at the tail end and can drive the separating block 320 at the tail end to slide on the guide rods 340 when located at the third position, so as to drive the remaining separating blocks 320 to slide on the guide rods 340 through the limiting blocks 330.

The mounting frame 310 is generally U-shaped, two ends of the guide rods 340 are respectively fixed to two side plates of the mounting frame 310, and the two guide rods 340 are horizontally arranged.

In an embodiment, as shown in fig. 1 and 8, the supporting base 200 includes a supporting plate 210, two limiting plates spaced apart from the supporting plate 210, and a connecting block 240, the supporting plate 210 is slidably connected to the base 100, the two limiting plates and the top surface of the supporting plate 210 together form a conveying channel with a width adapted to the cylindrical battery 900, one end of the connecting block 240 is fixed to one end of the supporting plate 210, and the other end of the connecting block 240 extends into the mounting frame 310 and is connected and fixed to the terminal separating block 320.

As shown in fig. 3, 4 and 8, the two limiting plates are the first limiting plate 220 and the second limiting plate 230 respectively, the first limiting plate 220 is far away from the mounting frame 310, the second limiting plate 230 is close to the mounting frame 310, the height of the first limiting plate 220 is greater than that of the second limiting plate 230, the height of the first limiting plate 220 is less than that of the cylindrical battery 900, and when the cylindrical battery 900 is placed on the supporting seat 200, a part of the cylindrical battery 900 extends out relative to the first limiting plate 220. The length of the first limiting plate 220 is greater than that of the second limiting plate 230, when the plurality of cylindrical batteries 900 are closely arranged on the supporting plate 210, all the cylindrical batteries 900 are located between the first limiting plate 220 and the second limiting plate 230, and after the plurality of cylindrical batteries 900 are equally spaced, a part of the cylindrical batteries 900 are separated from the area between the first limiting plate 220 and the second limiting plate 230.

In one embodiment, as shown in fig. 3 and 8, a recess is formed in the top surface of the supporting plate 210, a magnetic block 250, such as a rectangular magnetic block 250, is disposed in the recess, and the top surface of the magnetic block 250 is flush with or lower than the top surface of the supporting plate 210. The shell of the cylindrical battery 900 is a steel shell, the magnetic block 250 is arranged to absorb the cylindrical battery 900, and when the separating block 320 leaves the cylindrical battery 900, the cylindrical battery 900 can be stably placed on the supporting seat 200, so that the phenomenon of toppling caused by vibration of a machine is avoided.

The embodiment of the utility model provides a cylinder battery 900 detects production line, including the separator of above-mentioned embodiment.

In one embodiment, as shown in fig. 1, 4 and 9, the detection line for cylindrical batteries 900 includes a material, a battery dial wheel 500, a blanking pushing mechanism 600, a posture correcting mechanism 700 and a feeding pushing mechanism 800. The hopper 400 is obliquely placed, the bottom of the hopper 400 is provided with a mounting groove 410 matched with the battery dial wheel 500, the battery dial wheel 500 is rotatably mounted in the mounting groove 410, the circumferential side wall of the battery dial wheel 500 is uniformly provided with accommodating grooves matched with the cylindrical batteries 900 at intervals, a position of the hopper 400 close to the bottom is provided with a notch communicated with the mounting groove 410 so that the cylindrical batteries 900 in the accommodating grooves fall to the material pushing position of the blanking material pushing mechanism 600 through the notch, the blanking material pushing mechanism 600 pushes the cylindrical batteries 900 located at the material pushing position to the posture correcting mechanism 700, the posture correcting mechanism 700 is used for correcting the cylindrical batteries 900 to be in an upright state and conveying the cylindrical batteries 900 to the material pushing position of the feeding material pushing mechanism 800, and the feeding material pushing mechanism 800 is used for pushing the cylindrical batteries 900 located at the material.

The following further describes the operation of the cylindrical battery 900:

the cylindrical batteries 900 are put into the hopper 400, the battery thumb wheel 500 rotates the cylindrical batteries 900 to the bottom of the hopper 400 one by one, the cylindrical batteries 900 fall from the notch at the bottom of the hopper 400 to the pushing position of the blanking pushing mechanism 600 one by one, the cylindrical batteries 900 which are positioned in the material pushing position are in the inclined and horizontal state, the pushing cylinder of the blanking pushing mechanism 600 drives the pushing head to push the cylindrical batteries 900 which are positioned in the material pushing position into the rotating cylinder of the posture correcting mechanism 700, the rotating cylinder rotates to correct the inclined and horizontal cylindrical batteries 900 to the vertical state and convey the cylindrical batteries 900 in the vertical state to the pushing position of the feeding mechanism, then the pushing cylinder of the feeding pushing mechanism 800 drives the pushing head to push the cylindrical batteries 900 which are positioned in the material pushing position onto the supporting seat 200, when the number of the cylindrical batteries 900 on the supporting seat 200 reaches a preset value, such as 10 cylindrical batteries 900, the cylinder of the first driving mechanism 110 drives the mounting frame 310 to move towards the supporting seat 200, until each separation block 320 on the mounting frame 310 abuts against the corresponding cylindrical battery 900, at this time, the cylindrical battery 900 is abutted between the separation block 320 and one limiting plate of the supporting seat 200, the action cylinder of the second driving mechanism 120 drives the separation block 320 to disperse until each cylindrical battery 900 is equally spaced on the supporting seat 200, after the equally spaced separation is completed, the cylinder of the first driving mechanism 110 drives the mounting frame 310 to move to one side far away from the supporting seat 200, then the manipulator grabs each equally spaced cylindrical battery 900 from the supporting seat 200 and places a battery detection position, and the cylinder of the first driving mechanism 110 and the action cylinder of the second driving mechanism 120 reset respectively, so that the operation of rapidly separating at one time is completed.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A partitioning device for partitioning a plurality of cylindrical batteries arranged closely at equal intervals, characterized in that: the partition device includes:

a base;

the supporting seat is arranged on the base in a sliding mode and can do reciprocating linear motion on the base along a first direction, and the supporting seat is used for bearing and placing a plurality of cylindrical batteries;

the separating mechanism comprises a mounting frame and a plurality of separating blocks, the mounting frame is arranged on the base in a sliding mode and can do reciprocating linear motion on the base along a second direction, the second direction is perpendicular to the first direction, the plurality of separating blocks are movably arranged on the mounting frame, and two adjacent separating blocks are linked;

the first driving mechanism is connected with the mounting rack to drive the mounting rack to do reciprocating linear motion along the second direction and drive the separating blocks to do reciprocating linear motion between a first position and a second position, and when the separating blocks are located at the first position, the second driving mechanism is connected with the supporting seat to drive the supporting seat to do reciprocating linear motion along the first direction so as to drive the supporting seat to move from a third position to a fourth position;

when the supporting seat is located at the third position, the plurality of cylindrical batteries are closely arranged, each separating block is located at the first position and abuts against the corresponding cylindrical battery on the supporting seat, the second driving mechanism drives the supporting seat to move from the third position to the fourth position, and drives each separating block to simultaneously separate, so that each separating block drives the corresponding cylindrical battery to separate, and the plurality of closely arranged cylindrical batteries are equally spaced on the supporting seat.

2. The partitioning device as set forth in claim 1, wherein: the separating mechanism further comprises a plurality of limiting blocks, one limiting block is movably inserted between every two adjacent separating blocks, and each separating block is linked through the limiting blocks, so that the supporting seat is driven to be separated when moving from the third position to the fourth position, and then the corresponding cylindrical batteries are driven to be separated on the supporting seat at equal intervals.

3. The partitioning device as set forth in claim 2, wherein: the side surface of each separating block, which is close to the supporting seat, is sunken to form an arc-shaped surface, and when the separating blocks abut against the corresponding cylindrical battery, the arc-shaped surfaces are attached to the circumferential side surface of one side of the cylindrical battery in a matching way.

4. The partitioning device as set forth in claim 2, wherein: two adjacent limiting blocks are arranged in a staggered mode.

5. The partitioning device as set forth in claim 2, wherein: the limiting block is cylindrical, limiting rings are arranged at two ends of the limiting block respectively, sliding grooves are formed in the separating blocks along the first direction, limiting edges are arranged at one ends of the sliding grooves of the separating blocks, two ends of the limiting block are inserted into the sliding grooves of the two adjacent separating blocks in a sliding mode respectively, and when the separating blocks are completely separated, the limiting rings at two ends of the limiting block abut against the limiting edges of the two adjacent separating blocks respectively.

6. The partitioning device as set forth in claim 5, wherein: the separating mechanism further comprises two guide rods which are arranged on the mounting frame in parallel at intervals, the guide rods penetrate through the separating blocks, the separating blocks at the head end are fixed on the mounting frame, the supporting seat abuts against the separating blocks at the tail end when located at the third position and can drive the separating blocks at the tail end to slide on the guide rods, and therefore the limiting blocks drive the rest separating blocks to slide on the guide rods.

7. The partitioning device as set forth in claim 6, wherein: the supporting seat comprises a supporting plate and two limiting plates and a connecting block which are arranged on the supporting plate at intervals, the supporting plate is connected with the base in a sliding mode, the limiting plates and the top surface of the supporting plate jointly form a conveying channel of a cylindrical battery with width adaptation, one end of the connecting block is fixed at one end of the supporting plate, and the other end of the connecting block extends into the mounting frame and is connected and fixed with the separating block.

8. The partitioning device as set forth in claim 7, wherein: the top surface of the supporting plate is sunken to form a groove, a magnetic block is arranged in the groove, and the top surface of the magnetic block is flush with or lower than the top surface of the supporting plate.

9. The utility model provides a cylinder battery detection production line which characterized in that: comprising a partition according to any one of claims 1 to 8.

10. The cylindrical battery inspection line of claim 9, wherein: the cylindrical battery detection production line also comprises a hopper, a battery shifting wheel, a blanking pushing mechanism, a posture correcting mechanism and a feeding pushing mechanism, the bottom of the hopper is provided with a mounting groove which is adapted to accommodate the battery thumb wheel, the battery thumb wheel is rotatably mounted in the mounting groove, the circumferential side wall of the battery thumb wheel is evenly provided with accommodating grooves which are matched with the cylindrical batteries at intervals, a notch communicated with the mounting groove is arranged at the position of the hopper close to the bottom so that the cylindrical battery in the accommodating groove can fall to the material pushing position of the blanking material pushing mechanism through the notch, the blanking pushing mechanism pushes the cylindrical battery positioned at the pushing position to the posture correcting mechanism, the posture correcting mechanism is used for correcting the cylindrical battery to be in an upright state and conveying the cylindrical battery to the pushing position of the feeding pushing mechanism, and the feeding and pushing mechanism is used for pushing the cylindrical batteries at the material pushing position to the supporting seat of the separating device.

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