CN117571757A - Quick CT detection device of binary channels lamination lithium cell - Google Patents

Abstract

The invention discloses a double-channel laminated lithium battery rapid CT detection device which comprises a support frame, a swivel, two battery platforms and a driving assembly, wherein the swivel is rotatably arranged on one side of the support frame; through setting up the detection hole on the swivel, two lamination battery hold positions and two first rotary platform of cooperation for but detection hole both sides synchronous feeding, detection component can carry out synchronous detection to a plurality of positions of two lamination batteries, thereby improves the work efficiency that lamination battery detected.

Description

Quick CT detection device of binary channels lamination lithium cell

Technical Field

The invention relates to the technical field of laminated battery detection, in particular to a double-channel laminated lithium battery rapid CT detection device.

Background

In the laminated lithium battery detection, in the traditional 2D detection mode, through the static single-angle oblique imaging detection mode, the angle pole pieces of the laminated battery are poor in form consistency, the pole pieces almost overlap in different degrees, misjudgment is easily caused on images, and the detection accuracy is low; in order to improve the accuracy of laminated battery detection, a mode of CT detection is adopted in the market, but because the CT detection mode needs to be imaged from a certain angle and a plurality of images need to be acquired, and the existing CT detection equipment is generally arranged on a conveying line, only a single laminated battery can be detected, and therefore the detection work efficiency is low.

In view of this, the prior art is still to be improved and developed.

Disclosure of Invention

In view of the above-mentioned shortcomings of the prior art, the present invention aims to provide a dual-channel laminated lithium battery rapid CT detection device, which aims to solve the problems that the existing CT detection mode needs to image from a certain angle and needs to acquire a plurality of images, and the existing CT detection equipment is generally arranged on a line and can only detect a single laminated battery, thereby resulting in low detection work efficiency.

The technical scheme adopted for solving the technical problems is as follows:

a binary channels lamination lithium cell CT detection device fast, its characterized in that includes:

a support frame;

the rotating ring is rotatably arranged on one side of the supporting frame, and a detection hole is coaxially formed in the rotating ring;

the two battery platforms are respectively arranged on one side, close to the swivel, of the support frame and one side, far away from the swivel, of the support frame, first rotating platforms are arranged at opposite ends of the two battery platforms, laminated battery accommodating positions are respectively arranged at the tops of the two first rotating platforms, and the first rotating platforms can rotate relative to the battery platforms so as to rotate the four corners of the laminated batteries into the detection holes;

the detection assembly is arranged in the detection hole and is used for CT detection of the laminated battery;

the driving assembly is arranged on the supporting frame and connected with the swivel so as to drive the swivel to rotate.

Further, the laminated battery accommodation site includes:

the support plate is arranged on the top wall of the first rotary platform, and a plurality of positioning blocks are arranged on the side wall of the support plate in a surrounding mode;

the fixing component is arranged on the supporting plate and used for fixing the laminated battery.

Further, the fixing assembly includes:

the mounting block is arranged on the top wall of the supporting plate;

the fixed groove plate is rotatably arranged on the mounting block, one end of the fixed groove plate is provided with a first rotating wheel, and the other end of the fixed groove plate is provided with a second rotating wheel;

the torsion spring rotates and sets up in on the installation piece, torsional spring one end roof is held the installation piece lateral wall, the other end roof is held fixed frid lateral wall, so that the second of fixed frid rotates the wheel extrusion and is at lamination battery surface.

Further, a chamfer is arranged at the top of the positioning block.

Further, the detection assembly includes:

the light pipe emitter is arranged inside the detection hole;

the flat plate is arranged on one side of the detection hole far away from the light pipe emitter; the light pipe emitter is arranged opposite to the flat plate and is matched with the flat plate.

Further, the driving assembly includes:

the first motor is arranged on the top wall of the support frame, and a driving gear is coaxially arranged on an output shaft of the first motor;

the toothed ring is arranged on the outer surface of the swivel and meshed with the driving gear.

Further, the battery platform is far away from first rotary platform one end is provided with the second rotary platform, second rotary platform top is provided with lamination battery and holds the position, battery platform bottom is provided with the third rotary platform, so that battery platform rotates.

Further, a first linear module is arranged at the bottom of the first rotary platform.

Further, the bottom of the third rotary cylinder is provided with a second linear module, the bottom of the second linear module is provided with a frame body, and the frame body is arranged on the ground.

Further, the first rotary platform, the second rotary platform and the third rotary platform are all rotary cylinders.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, a swivel is rotatably arranged on one side of a support frame, a detection hole is coaxially formed in the swivel, a detection assembly is arranged in the detection hole and used for CT detection of laminated batteries, two battery platforms are arranged on one side, close to the swivel, of the support frame and one side, away from the swivel, of the support frame, first rotating platforms are arranged at opposite ends of the two battery platforms, laminated battery accommodating positions are arranged at the tops of the two first rotating platforms and are used for fixing laminated batteries, the first rotating platforms can rotate relative to the battery platforms so as to rotate four corners of the batteries into the detection hole, and meanwhile, a driving assembly is arranged on the support frame and connected with the swivel and drives the swivel to rotate, so that multi-angle shooting of the detection assembly is realized; through setting up the detection hole on the swivel, two lamination battery hold positions and two first rotary platform of cooperation for but detection hole both sides synchronous feeding, detection component can carry out synchronous detection to a plurality of positions of two lamination batteries, thereby improves the work efficiency that lamination battery detected.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention.

FIG. 2 is a schematic diagram of a detecting assembly according to the present invention.

Fig. 3 is a schematic view of a battery platform according to the present invention.

Fig. 4 is a schematic view of the structure of the support plate of the present invention.

FIG. 5 is a schematic view of a fixing assembly according to the present invention.

The numerical labels in the figures are represented as: 1. a support frame; 2. a swivel; 21. a detection hole; 3. a detection assembly; 31. a light pipe emitter; 32. a flat plate; 4. a battery platform; 5. a first rotary platform; 6. a laminated battery receiving location; 61. a support plate; 62. a positioning block; 63. a fixing assembly; 631. a mounting block; 632. fixing the groove plate; 633. a torsion spring; 634. a first rotating wheel; 635. a second rotating wheel; 7. a drive assembly; 71. a first motor; 72. a toothed ring; 8. a second rotary platform; 81. a third rotary stage; 82. a first linear module; 83. a second linear module; 84. a frame body.

Detailed Description

In order to make the objects, technical solutions and effects of the present invention clearer and more specific, the present invention will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

In view of the shortcomings of the prior art, the present embodiment provides a dual-channel laminated lithium battery rapid CT detection device, and specific reference may be made to the following:

as shown in fig. 1 and fig. 3, a fast CT detection device for double-channel laminated lithium batteries includes a support frame 1, a swivel 2, two battery platforms 4 and a driving component 7, the support frame 1 is a frame 84 formed by welding sectional materials, and can be arranged on the ground, the swivel 2 is rotatably arranged on one side of the support frame 1, a detection hole 21 is coaxially arranged in the swivel 2, a detection component 3 is arranged in the detection hole 21, the detection component 3 is used for CT detection of laminated batteries, two battery platforms 4 are arranged on one side, close to the swivel 2, of the support frame 1 and one side, away from the swivel 2, of the two battery platforms 4, opposite ends of the two battery platforms 4 are provided with a first rotary platform 5, laminated battery accommodation positions 6 are respectively arranged at the tops of the first rotary platforms 5 and are used for fixing laminated batteries, the two first rotary platforms 5 can rotate relative to the battery platforms 4 so as to rotate the four corners of the two laminated batteries into the detection hole 21, the detection component 3 is arranged in the middle position of the two first rotary platforms 5, the detection component 3 can simultaneously detect the two batteries, the support frame 1 is provided with a driving component 7, and the driving component 7 and the swivel 2 are connected with the driving component 7 so as to realize the detection of the multi-angle rotation of the laminated batteries through the driving component 2.

Specifically, auxiliary conveying mechanisms can be arranged on two sides of the support frame 1, the support frame 1 and the battery platforms 4 on two sides can be located between two conveying lines, laminated batteries on the two conveying lines are placed in the laminated battery accommodating positions 6 through the auxiliary conveying mechanisms, the two laminated batteries are synchronously rotated through the first rotating platform 5, so that corners of the two laminated batteries are diagonally arranged, then the driving assembly 7 drives the detecting assembly 3 to rotate to a certain angle, and two angular positions of the two laminated batteries are detected to judge whether faults occur inside the laminated batteries.

As shown in fig. 3 and fig. 4, the laminated battery accommodating position 6 includes a support plate 61 and a fixing component 63, the support plate 61 is disposed at the top wall of the first rotary platform 5, a plurality of positioning blocks 62 are disposed around the side wall of the support plate 61, the fixing component 63 is disposed on the support plate 61, and the laminated battery can be fixed by the fixing component 63, so that the laminated battery is prevented from being deviated, and the error is detected by the detecting component 3.

Further, the positioning blocks 62 are disposed at four side wall positions of the supporting plate 61, and a chamfer is disposed at a top position of the positioning block 62, so that the laminated battery is conveniently placed on the supporting plate 61.

Further, as shown in fig. 5, the fixing assembly 63 includes a mounting block 631, a fixing groove plate 632 and a torsion spring 633, the mounting block 631 is disposed on a top wall of the supporting plate 61 and is located on one side of the laminated battery on the supporting plate 61, the fixing groove plate 632 is rotatably disposed on the top of the mounting block 631, one end of the fixing groove plate 632 is provided with a first rotating wheel 634, the other end is provided with a second rotating wheel 635, the first rotating wheel 634 and the second rotating wheel 635 are both made of rubber materials, the mounting block 631 is rotatably provided with the torsion spring 633, the torsion spring 633 is located on a shaft rotationally connected with the fixing groove plate 632, and is coaxially disposed, one end of the torsion spring 633 is propped against a side wall of the mounting block 631 far away from the laminated battery, and the other end is propped against a side wall of the fixing groove plate 632 close to the mounting block 631, so that the second rotating wheel 635 of the fixing groove plate 632 is pressed on the surface of the laminated battery to fix the laminated battery, thereby preventing the laminated battery from being separated from the surface of the supporting plate 61; meanwhile, the first rotating wheel 634 can be pressed, so that the fixed groove plate 632 rotates around the positioning block 62, and the laminated battery can be separated from the fixed part, so that the auxiliary conveying mechanism can be conveniently used for taking away or placing the laminated battery.

As shown in fig. 2, the detecting assembly 3 includes a light pipe emitter 31 and a flat plate 32, the light pipe emitter 31 is disposed inside the detecting hole 21 and is located at the center of the thickness of the detecting hole 21, the light pipe emitter 31 is used for emitting X-rays, the flat plate 32 is disposed inside the swivel 2 and is located at one side far away from the light pipe emitter 31, the light pipe emitter 31 and the flat plate 32 are disposed opposite to each other and cooperate with each other, the light pipe emitter 31 emits X-rays to irradiate two corners of two lamination batteries, and simultaneously images on the flat plate 32, the flat plate 32 is used for receiving optical signals, generating pictures and sending the pictures to a terminal, the swivel 2 can rotate on one side of the support frame 1 under the action of the driving assembly 7, so that the light pipe emitter 31 and the flat plate 32 synchronously rotate to a certain angle, and the lamination batteries can be detected.

Further, the driving assembly 7 comprises a first motor 71 and a toothed ring 72, the first motor 71 is arranged at the top wall of the supporting frame 1, a driving gear is coaxially arranged on an output shaft of the first motor 71, the toothed ring 72 is sleeved on the outer surface of the rotating ring 2, the toothed ring 72 and the toothed ring are matched with each other, and external teeth of the toothed ring 72 are meshed with teeth of the driving gear so as to rotate through the first motor 71, so that the toothed ring 72 and the rotating ring 2 are driven to rotate.

As shown in fig. 3, a second rotating platform 8 is arranged at one end of the battery platform 4 far away from the first rotating platform 5, a laminated battery accommodating position 6 is arranged at the top of the second rotating platform 8, and a third rotating platform 81 is arranged at the top of the battery platform 4 so as to enable the battery platform 4 to rotate, and meanwhile, the first rotating platform 5 and the second rotating platform 8 are enabled to exchange positions, namely, the detected laminated battery is replaced;

specifically, the laminated batteries are put on the supporting plates 61 on the tops of the two first rotating platforms 5 through an external auxiliary conveying mechanism, then the two third rotating platforms 81 are controlled to rotate, so that the laminated batteries on the first rotating platforms 5 are close to the detection holes 21, then the four corners of the two laminated batteries are sequentially rotated to detection positions through the rotation of the first rotating platforms 5, and detection is performed; during detection, the auxiliary conveying mechanism is used for placing the next laminated battery to be detected on the supporting plate 61 of the second rotary platform 8, after the laminated battery on the first rotary platform 5 is detected, the third rotary platform 81 reversely rotates to enable the first rotary platform 5 to exchange positions with the second rotary platform 8, the second rotary platform 8 rotates, four corners of the laminated battery on the second rotary platform 8 sequentially rotate into the detection holes 21 to be detected, at the moment, the laminated battery on the first rotary platform 5 is taken away through the external auxiliary conveying mechanism, then the next laminated battery to be detected is placed, the working procedures are repeated, and the detection assembly 3 can continuously detect the laminated battery; through the cooperation of the device, the waiting time of the detection assembly after the lamination batteries are detected can be effectively reduced, so that the detection efficiency is improved.

Further, the bottom of the first rotary platform 5 is provided with a first linear module 82, the first rotary platform 5 is located at the sliding block position of the first linear module 82, and the first rotary platform 5 can move transversely through the first linear module 82 so as to be close to the detection position of the detection hole 21 and the fetching and delivering position of the auxiliary conveying mechanism.

Further, the bottom of the third rotary platform 81 is provided with a second linear module 83, the bottom of the second linear module 83 is provided with a frame 84, the frame 84 is arranged on the ground, the second linear module 83 is perpendicular to the first linear module 82 and used for adjusting the position of the battery platform 4, the auxiliary conveying mechanism is convenient to take and convey laminated batteries, and the laminated batteries are conveyed to the detection position through the second linear module 83.

Further, the first rotary platform 5, the second rotary platform 8 and the third rotary platform 81 are all rotary cylinders, and the first rotary platform 5, the second rotary platform 8 and the third rotary platform 81 may be rotary electric cylinders or electric rotary platforms.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the disclosed embodiments. This invention is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

Claims (10)

1. A binary channels lamination lithium cell CT detection device fast, its characterized in that includes:

a support frame;

the rotating ring is rotatably arranged on one side of the supporting frame, and a detection hole is coaxially formed in the rotating ring;

the two battery platforms are respectively arranged on one side, close to the swivel, of the support frame and one side, far away from the swivel, of the support frame, first rotating platforms are arranged at opposite ends of the two battery platforms, laminated battery accommodating positions are respectively arranged at the tops of the two first rotating platforms, and the first rotating platforms can rotate relative to the battery platforms so as to rotate the four corners of the laminated batteries into the detection holes;

the detection assembly is arranged in the detection hole and is used for CT detection of the laminated battery;

the driving assembly is arranged on the supporting frame and connected with the swivel so as to drive the swivel to rotate.

2. The dual channel laminated lithium battery rapid CT detector of claim 1, wherein the laminated battery receiving location comprises:

the support plate is arranged on the top wall of the first rotary platform, and a plurality of positioning blocks are arranged on the side wall of the support plate in a surrounding mode;

the fixing component is arranged on the supporting plate and used for fixing the laminated battery.

3. The dual channel laminated lithium battery rapid CT detector of claim 2, wherein the fixing assembly comprises:

the mounting block is arranged on the top wall of the supporting plate;

the fixed groove plate is rotatably arranged on the mounting block, one end of the fixed groove plate is provided with a first rotating wheel, and the other end of the fixed groove plate is provided with a second rotating wheel;

the torsion spring rotates and sets up in on the installation piece, torsional spring one end roof is held the installation piece lateral wall, the other end roof is held fixed frid lateral wall, so that the second of fixed frid rotates the wheel extrusion and is at lamination battery surface.

4. The dual-channel laminated lithium battery rapid CT detection device according to claim 2, wherein a chamfer is arranged at the top of the positioning block.

5. The dual channel laminated lithium battery rapid CT detector of claim 1, wherein the detector assembly comprises:

the light pipe emitter is arranged inside the detection hole;

the flat plate is arranged on one side of the detection hole far away from the light pipe emitter; the light pipe emitter is arranged opposite to the flat plate and is matched with the flat plate.

6. The dual channel laminated lithium battery rapid CT detector of claim 1, wherein the drive assembly comprises:

the first motor is arranged on the top wall of the support frame, and a driving gear is coaxially arranged on an output shaft of the first motor;

the toothed ring is arranged on the outer surface of the swivel and meshed with the driving gear.

7. The dual-channel laminated lithium battery rapid CT detection device according to claim 1, wherein a second rotary platform is arranged at one end of the battery platform far away from the first rotary platform, a laminated battery accommodating position is arranged at the top of the second rotary platform, and a third rotary platform is arranged at the bottom of the battery platform so that the battery platform rotates.

8. The dual-channel laminated lithium battery rapid CT detection device according to claim 7, wherein a first linear module is arranged at the bottom of the first rotary platform.

9. The dual-channel laminated lithium battery rapid CT detection device according to claim 7, wherein a second linear module is arranged at the bottom of the third rotary cylinder, and a frame body is arranged at the bottom of the second linear module and is arranged on the ground.

10. The dual-channel laminated lithium battery rapid CT detection apparatus of claim 7, wherein the first rotary platform, the second rotary platform, and the third rotary platform are rotary cylinders.