CN218568958U - Convertible blade battery formation mechanism - Google Patents

Abstract

The utility model discloses a turnover type blade battery formation mechanism, which comprises an equipment frame, a turnover mechanism and a battery formation mechanism; the turnover mechanism and the battery formation mechanism are arranged in the equipment frame; the battery formation mechanism comprises a support mechanism frame, a formation clamping assembly and a tray support assembly; a tray bracket component and a formation clamping component are arranged in the supporting mechanism frame; the tray support assembly is arranged in the support mechanism frame; the formation clamping assembly comprises a fixed clamping formation part and a movable clamping formation part, and probes are arranged on the heads of the fixed clamping formation part and the movable clamping formation part which are opposite; the turnover mechanism is connected with the battery formation mechanism through a horizontal turnover shaft. The utility model has the advantages that: the battery electrolyte injection process and the formation process can be integrated on one station, and the battery electrolyte injection amount can be increased by overturning the formation mechanism, so that the energy density of the battery is improved; the battery box can be suitable for batteries with different lengths and thicknesses and can be automatically realized.

Description

Convertible blade battery formation mechanism

Technical Field

The utility model relates to a convertible blade battery becomes mechanism belongs to battery test technical field.

Background

Lithium ion batteries have been widely used from the practical new types to the present, with the advantages of high energy density, long service life, light weight, low self-discharge, etc., and are mainly used in the fields of mobile electronic devices, electric bicycles and electric automobiles at present.

In recent years, under the situation that the country greatly supports the new energy battery industry, the lithium battery and the related manufacturing industry have unprecedented development. Under such circumstances, the requirements for the quality and production efficiency of lithium batteries are becoming more and more strict, and therefore, it is necessary to enhance the control of each production process of battery production and to improve the product quality and production efficiency of each production process. In the formation and capacity grading process, researchers often clamp the batteries one by using spring clamps, the efficiency is low, the pressure of the spring clamps is inconsistent, and the performance parameters of the batteries are influenced. The automatic component capacity grading equipment can improve the stability of products and reduce a large amount of manpower requirements in the production process.

SUMMERY OF THE UTILITY MODEL

In order to solve the battery and annotate the liquid and become the problem that the station separation becomes inefficiency with the formation, the utility model provides a can be suitable for the battery of different length and thickness, can full automatization, need not manual operation, to promoting battery output efficiency's convertible blade battery formation mechanism.

A convertible blade battery ization become mechanism, its characterized in that: the device comprises an equipment frame, a turnover mechanism and a battery formation mechanism;

the turnover mechanism and the battery formation mechanism are arranged in the equipment frame;

the battery formation mechanism comprises a support mechanism frame, a formation clamping assembly and a tray support assembly;

a tray support assembly and a formation clamping assembly are arranged in the supporting mechanism frame;

the tray bracket assembly is arranged in the support mechanism frame and is used for clamping a battery tray;

the formation clamping assembly comprises a fixed clamping formation part and a movable clamping formation part which are arranged at two longitudinal end parts of the tray bracket assembly at intervals, and probes are arranged at the opposite heads of the fixed clamping formation part and the movable clamping formation part and used for performing charging and discharging activation treatment on the battery;

the turnover mechanism is connected with the battery formation mechanism through a horizontal turnover shaft, and the turnover shaft has a rotational degree of freedom around the axis of the turnover shaft; the axial direction of the turnover shaft is defined as the transverse direction, and the horizontal direction perpendicular to the turnover shaft is defined as the longitudinal direction, and is used for driving the battery formation mechanism to turn over.

Preferably, the equipment frame comprises an outer support frame and an inner support frame, the outer support frame and the inner support frame are both frame structures formed by overlapping a plurality of frame square pipes, and a plurality of frame bottom feet are arranged at the bottom of the outer support frame; and a frame anti-collision pad is arranged on the inner support frame.

Preferably, the turnover mechanism comprises a pushing cylinder, a transmission gear, a rack, a transmission mechanism slide rail, a bearing seat, a cylinder connecting block and a rack base, and the pushing cylinder is mounted on the inner support frame; the transmission mechanism slide rail is arranged at the top of the inner support frame; the rack is arranged on the rack base, and the rack base is slidably arranged on the transmission mechanism slide rail and is connected with the telescopic end of the pushing cylinder through a cylinder connecting block; the transmission gear and the bearing seat are arranged on two sides of the rack at intervals, the transmission gear is meshed with the rack, and a central shaft of the transmission gear is overlapped with a central shaft of the bearing seat; the turnover shaft is transversely and fixedly arranged in the transmission gear and the bearing seat in a penetrating mode.

Preferably, the supporting mechanism frame is arranged above the turnover mechanism, a needle plate slide rail longitudinally arranged is arranged at the inner bottom of the supporting mechanism frame, and a turnover shaft is arranged outside the supporting mechanism frame.

Preferably, the tray support assembly comprises fixed supports, movable supports and movable support driving cylinders which are arranged in parallel at intervals, the fixed supports are fixedly arranged at the bottom of the support mechanism frame, the movable supports are fixedly arranged on the movable needle plate frame, and supporting surfaces at the same horizontal height are arranged at the tops of the fixed supports and the movable supports and are supported at the bottom of the battery tray together; the movable support driving cylinder is arranged at the bottom of the support mechanism frame, and the telescopic end of the movable support driving cylinder is connected with the movable support and used for driving the movable support to longitudinally move.

Preferably, the fixed clamping formation part comprises a fixed needle plate and a fixed needle plate driving cylinder; the fixed needle plate is slidably arranged on the first longitudinal needle plate slide rail; the fixed needle plate driving cylinder is horizontally arranged on the fixed support, and the telescopic end of the fixed needle plate driving cylinder is connected with the fixed needle plate and used for adjusting the longitudinal position of the fixed needle plate. Preferably, the movable clamping formation part comprises a movable needle plate and a movable needle plate driving cylinder; the movable needle plate is slidably arranged on the second longitudinal needle plate slide rail; the movable needle plate driving cylinder is horizontally arranged on the movable support; the movable needle plate drives the flexible end of cylinder with the movable needle plate links to each other for the adjustment the longitudinal position of movable needle plate.

Preferably, the tray support assembly comprises a fixed support and a movable support which are arranged at intervals in parallel, the fixed support is fixedly arranged on the bottom plate, the movable support is fixedly arranged on the movable needle plate frame, and the top of the fixed support and the top of the movable support are provided with supporting surfaces at the same horizontal height and jointly support the bottom of the battery tray.

Preferably, the fixing needle plate comprises a first supporting section bar which is transversely arranged and a plurality of first probe assemblies which are arranged on the supporting section bar and are mutually linked, and a transverse clamping groove is formed in the inner side, facing the battery tray, of the first supporting section bar; the head of the first probe assembly is provided with a probe, and the tail of the first probe assembly can be slidably inserted into the transverse clamping groove of the first supporting section bar.

Preferably, the movable needle plate comprises a second support section bar which is transversely arranged and a plurality of second probe assemblies which are arranged on the second support section bar and are mutually linked, and a transverse clamping groove is formed in the inner side, facing the battery tray, of the second support section bar; the number of the second probe assemblies is the same as that of the first probe assemblies, the second probe assemblies are opposite to the first probe assemblies, probes capable of being in contact with the anode and the cathode of the battery are arranged at the head of each second probe assembly, and the tail of each second probe assembly is slidably inserted into the transverse clamping groove of the second supporting section.

Preferably, the top of the fixed support and the top of the movable support are provided with blocking blocks for fixing the battery tray.

More preferably, the fixed bracket and the movable bracket are respectively provided with a row of stop blocks along the transverse direction. The battery tray may be confined between two columns of the stopper pieces.

The utility model has the advantages that: the battery formation mechanism is simple in structure, the battery liquid injection process and the formation process can be integrated on one station, the battery electrolyte injection amount can be increased through the overturning of the formation mechanism, and the energy density of the battery is improved; the formation mechanism component has the function of adjusting the transverse axis and the longitudinal axis, and can be suitable for batteries with different lengths and thicknesses; the whole system is a fully automatic system, manual operation is not needed, and the system plays an important role in improving the output efficiency of the battery.

Drawings

Fig. 1 is a front view of an overall structure of a turnover type blade battery formation mechanism according to an embodiment of the present invention;

fig. 2 is a perspective view of the overall structure of the turnover type blade battery formation mechanism according to an embodiment of the present invention;

fig. 3 is a perspective view of an apparatus frame of the convertible blade battery formation mechanism according to an embodiment of the present invention;

fig. 4 is a perspective view of a turnover mechanism assembly of the turnover type blade battery formation mechanism according to an embodiment of the present invention;

fig. 5 is a perspective view of a battery formation mechanism of the turnover blade battery formation mechanism according to an embodiment of the present invention.

Fig. 6 is an enlarged view of a portion a of fig. 5.

Detailed Description

The following describes in detail embodiments of the present invention with reference to the accompanying drawings. It is to be understood that the description herein is only intended to illustrate and explain embodiments of the present invention, and is not intended to limit embodiments of the present invention.

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

The invention will be described in detail below with reference to the accompanying drawings in conjunction with exemplary embodiments.

The utility model discloses a turnover type blade battery formation mechanism, which comprises an equipment frame 100, a turnover mechanism 200 and a battery formation mechanism 300;

the turnover mechanism 200 and the battery formation mechanism 300 are arranged in the equipment frame 100 from bottom to top;

the battery formation mechanism 300 comprises a support mechanism frame 310, a formation clamping assembly 320 and a tray bracket assembly 330, wherein the overturning shaft 311 overturns the shaft 311, and the tray bracket assembly 330 and the formation clamping assembly 320 are arranged in the support mechanism frame 310;

the tray support assembly 330 is disposed in the support mechanism frame 310 for holding a battery tray;

the formation clamping assembly 320 comprises a fixed clamping formation part and a movable clamping formation part which are arranged at two longitudinal end parts of the tray support assembly 330 at intervals, and probes are arranged at the opposite heads of the fixed clamping formation part and the movable clamping formation part and used for performing charging and discharging activation treatment on the battery;

the turnover mechanism 200 is connected with the battery formation mechanism 300 through a horizontal turnover shaft 311, and the turnover shaft has a rotational degree of freedom around the axis of the turnover shaft; the axial direction of the turnover shaft is defined as the transverse direction, and the horizontal direction perpendicular to the turnover shaft is defined as the longitudinal direction, and is used for driving the battery formation mechanism to turn over.

In some embodiments of the present invention, the equipment frame 100 includes an outer support frame 110 and an inner support frame 120, the outer support frame 110 and the inner support frame 120 are both frame structures formed by overlapping a plurality of frame square pipes, and a plurality of frame feet 111 are installed at the bottom of the outer support frame 110; a frame crash pad 121 is installed on the top of the inner support frame 120 to prevent the battery formation mechanism 300 from directly contacting the inner support frame 120, which may cause abrasion between components.

In some embodiments of the present invention, the outer support frame 110 and the inner support frame 120 are both rectangular frames, and a part of the square tubes of the frame at the bottom of the outer support frame 110 is provided with threaded mounting holes; the four sets of frame feet 111 are distributed at four corners of the outer support frame 110 and are mounted in the corresponding threaded mounting holes. The height of the whole formation mechanism can be conveniently adjusted finely. In some embodiments of the present invention, the top frame of the inner support frame 120 is a horizontal U-shaped frame, the U-shaped frame has an opening and a connection tail portion, which are oppositely disposed, and the frame crash pad 121 is disposed on the connection tail portion. When the battery formation mechanism 300 is in a horizontal non-turnover state, one end of the battery formation mechanism 300 is lapped on the frame crash pad 121, and when the battery formation mechanism 300 is in a turnover state, because the top of the inner support frame 120 is provided with an opening, the battery formation mechanism 300 can be conveniently turned over without hindrance.

In some embodiments of the present invention, the turnover mechanism 200 includes a push cylinder 210, a rack 220, a transmission gear 230, a transmission slide rail 250, a bearing seat 240, a cylinder connecting block 260, and a rack base 270, the push cylinder 210 is mounted on the inner support frame 120, and a telescopic end of the push cylinder 210 is longitudinally telescopic; the transmission mechanism slide rail 250 is laid on the top of the inner support frame 120 along the longitudinal direction; the rack 220 is longitudinally mounted on the rack base 270, and the rack base 270 is slidably disposed on the transmission mechanism slide rail 250 and connected to the telescopic end of the push cylinder 210 through a cylinder connecting block 260; the transmission gear 230 and the bearing seat 240 are arranged at two sides of the rack 220 at intervals, the transmission gear 230 is meshed with the rack 220, and the central axis of the transmission gear 230 is overlapped with the central axis of the bearing seat 240; the turning shaft 311 is transversely and fixedly inserted into the transmission gear 230 and the bearing seat 240. The pushing cylinder 210 pushes the rack 220 to linearly move along the axial direction of the transmission mechanism sliding rail 250, so as to drive the transmission gear 230 to rotate, and the linear motion of the pushing cylinder 210 is converted into the rotation of the transmission gear 230, and because the transmission gear 230 is fixed with the turnover shaft 311, the rotation of the transmission gear 230 can be converted into the synchronous rotation of the turnover shaft 311.

In some embodiments of the present invention, the supporting mechanism frame 310 is a rectangular parallelepiped frame, a bottom plate is laid at the bottom of the supporting mechanism frame 310, when the supporting mechanism frame 310 is in a horizontal state, the end of the supporting mechanism frame 310 can be supported on the frame anti-collision pad, so as to prevent the supporting mechanism frame 310 from directly contacting the inner supporting frame 120 below.

In some embodiments of the present invention, the supporting mechanism frame 310 is disposed above the turnover mechanism 200, and a tray support slide rail 312 arranged along the longitudinal direction is disposed on a bottom plate of the supporting mechanism frame 310, and a turnover shaft 311 is disposed outside the supporting mechanism frame. In other embodiments of the present invention, the supporting mechanism frame 310 is provided with a horizontal turning shaft 311 along the middle of the two lateral sides, and the central axes of the two turning shafts 311 coincide. Each turnover shaft 311 corresponds to one turnover mechanism. The whole battery formation mechanism can be stressed uniformly, and stable overturning is realized.

In some embodiments of the present invention, the tray support assembly 330 includes a fixed support 331, a movable support 332, and a movable support driving cylinder 333, which are arranged side by side at intervals, the fixed support 331 is fixedly disposed at the bottom of the supporting mechanism frame 310, the movable support 332 is fixedly mounted on the movable needle plate frame 324, and the top of the fixed support 331 and the top of the movable support 332 are provided with supporting surfaces at the same horizontal height, and are supported at the bottom of the battery tray together; the movable support driving cylinder 333 is disposed at the bottom of the supporting mechanism frame 310, and a telescopic end of the movable support driving cylinder 333 is connected to the movable support 332 for driving the movable support 332 to move longitudinally.

In some embodiments of the present invention, the fixing bracket 331 is disposed inside the supporting mechanism frame 310 and at the top thereof, a first longitudinal needle plate slide rail 3311 is disposed.

In some embodiments of the present invention, the movable support 332 is slidably disposed in the supporting mechanism frame 310 and located at the opposite side of the fixed support 331, and the top of the movable support 332 is provided with a second longitudinal pin plate sliding rail 3321.

In some embodiments of the present invention, the fixed clamping formation portion is slidably disposed on the top of the fixed bracket 331, the movable clamping formation portion is slidably disposed on the top of the movable bracket 332, and the contact and separation between the positive and negative electrodes of the battery in the battery tray and the probe can be realized by adjusting the vertical distance between the fixed clamping formation portion and the movable clamping formation portion.

In some embodiments of the present invention, the fixed nip formation comprises a fixed needle plate 322 and a fixed needle plate driving cylinder 323; the fixed needle plate 322 is slidably disposed on the first longitudinal needle plate slide rail 3311; the fixed needle plate driving cylinder 323 is horizontally arranged on the fixed support 331, and the telescopic end of the fixed needle plate driving cylinder 323 is connected with the fixed needle plate 322 and used for adjusting the longitudinal position of the fixed needle plate.

In some embodiments of the present invention, the movable clamping formation portion comprises a movable needle plate 325 and a movable needle plate driving cylinder 324; the movable needle plate 325 is slidably arranged on the second longitudinal needle plate slide rail 3321; the movable needle plate driving cylinder 324 is horizontally arranged on the movable bracket 332; the flexible end of the movable needle plate driving cylinder 324 is connected with the movable needle plate 325 for adjusting the longitudinal position of the movable needle plate.

In some embodiments of the present invention, the fixing needle plate 322 includes a first supporting section 3221 arranged transversely and a plurality of first probe assemblies 3222 arranged on the supporting section and linked with each other, the first supporting section 3221 is provided with a transverse slot facing to the inner side of the battery tray; the head of the first probe assembly 3222 is provided with a probe, and the tail of the first probe assembly is slidably inserted into the transverse slot of the first support profile; the first probe assembly 3222 is connected to the fixed needle plate driving cylinder 323 for controlling the lateral spacing between adjacent probes.

In some embodiments of the present invention, the movable pin plate 325 includes a second support section 3251 disposed transversely and a plurality of second probe assemblies 3252 disposed on the second support section and linked with each other, the second support section 3251 has a transverse slot facing the inner side of the battery tray; the number of the second probe assemblies 3252 is the same as that of the first probe assemblies and the second probe assemblies are opposite to each other, probes are arranged at the head of each second probe assembly 3252, and the tail of each second probe assembly 3252 is slidably inserted into the transverse clamping groove of the corresponding second supporting section; the second probe assembly 3252 is coupled to the movable needle plate drive cylinder 324 for controlling the lateral spacing between adjacent probes.

In some embodiments of the present invention, a row of stopping blocks 333 is respectively disposed on the fixed bracket 331 and the movable bracket 332 along the transverse direction. The bottom of the battery tray is supported on the supporting surfaces of the fixed bracket 331 and the movable bracket 332 and is limited between the two rows of the blocking pieces 333, so that the battery tray can be fixed.

When the battery stacker is used specifically, a battery tray loaded with batteries is sent to the tray support assembly 330 inside the battery formation mechanism 300 by the stacker, the pushing cylinder 210 pushes the rack 220 to do linear motion, the rack 220 drives the meshed transmission gear 230 to do rotary motion, and the transmission gear 230 drives the turnover shaft 311 to do rotary motion. And the tumble shaft 311 is welded to the support mechanism frame 310. The entire battery formation mechanism 300 is rotated by 90 degrees. After the rotation, the liquid filling port of the battery faces upwards, and the battery liquid filling process can be carried out. After the liquid injection process is completed, the pushing cylinder 210 moves in the reverse direction again, so that the battery formation mechanism 300 rotates back to the horizontal direction. The movable needle plate 325 mounted on the second needle plate slide rail 3241 and the fixed needle plate 322 mounted on the first needle plate slide rail 3311 are driven by the movable needle plate frame driving cylinder 327 and the fixed needle plate frame driving cylinder 323 respectively to move toward the center of the battery formation mechanism so that the probes contact the battery, and the battery is activated in the formation process.

The movable support 332 arranged on the tray support slide rail 312 can drive the whole movable needle plate 325 to move towards the battery direction along the longitudinal direction, so that the whole battery formation mechanism 300 can be suitable for blade batteries with different types within the range of 600mm to 1000mm in length.

In some embodiments of the present invention, the movable needle plate driving cylinder 324 and the fixed needle plate frame driving cylinder 323 are both cylinders, the cylinders are disposed along the vertical level, the cylinder bodies of the cylinders are fixed on the movable support 332 and the fixed support 331 respectively, and the telescopic ends of the cylinders are fixed on the movable needle plate 325 and the fixed needle plate 322.

Of course, the movable needle plate driving cylinder 324 and the fixed needle plate frame driving cylinder 323 may be hydraulic cylinders, electric telescopic rods, or the like, as long as the movable needle plate 325 and the fixed needle plate 322 can be driven to move left and right in the longitudinal direction.

The movable needle plate 325 and the fixed needle plate 322 are made of aluminum profiles with mounting chutes, and the front and rear positions of the probe can be freely adjusted on the chutes. The longitudinal front and back positions of the probe are adjusted, so that the battery forming mechanism can adapt to batteries with different thicknesses, and the wide applicability of the battery forming mechanism of the turnover type blade is enhanced.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship indicated based on the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, 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 at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., 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; may be mechanically coupled, may be electrically coupled or may be in communication with each other; they may be directly connected or indirectly connected through intervening media, or they may be interconnected within two elements or in a relationship where two elements interact with each other unless otherwise specifically limited. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present application, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "above," and "over" a second feature may be directly on or obliquely above the second feature, or simply mean that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present invention have been shown and described, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art without departing from the scope of the present invention.

Claims (10)

1. The utility model provides a convertible blade battery ization becomes mechanism which characterized in that: the device comprises an equipment frame, a turnover mechanism and a battery formation mechanism;

the turnover mechanism and the battery formation mechanism are arranged in the equipment frame;

the battery formation mechanism comprises a support mechanism frame, a formation clamping assembly and a tray support assembly;

a tray bracket component and a formation clamping component are arranged in the supporting mechanism frame;

the tray bracket assembly is arranged in the support mechanism frame and is used for clamping a battery tray;

the formation clamping assembly comprises a fixed clamping formation part and a movable clamping formation part which are arranged at two longitudinal end parts of the tray bracket assembly at intervals, and probes are arranged at the opposite heads of the fixed clamping formation part and the movable clamping formation part and used for performing charging and discharging activation treatment on the battery;

the turnover mechanism is connected with the battery formation mechanism through a horizontal turnover shaft, and the turnover shaft has a rotational degree of freedom around the axis of the turnover shaft; the axial direction of the turnover shaft is defined as the transverse direction, and the horizontal direction perpendicular to the turnover shaft is defined as the longitudinal direction, so that the battery formation mechanism is driven to turn over.

2. The convertible blade battery formation mechanism of claim 1, wherein: the equipment frame comprises an outer supporting frame and an inner supporting frame, the outer supporting frame and the inner supporting frame are of frame structures formed by overlapping a plurality of frame square pipes, and a plurality of frame bottom feet are arranged at the bottom of the outer supporting frame; and a frame anti-collision pad is arranged on the inner support frame.

3. The flip-chip blade battery formation mechanism of claim 2, wherein: the turnover mechanism comprises a pushing cylinder, a transmission gear, a rack, a transmission mechanism slide rail, a bearing seat, a cylinder connecting block and a rack base, wherein the pushing cylinder is arranged on the inner support frame; the transmission mechanism slide rail is arranged on the inner support frame; the rack is arranged on the rack base, and the rack base is slidably arranged on the transmission mechanism slide rail and is connected with the telescopic end of the pushing cylinder through a cylinder connecting block; the transmission gear and the bearing seat are arranged on two sides of the rack at intervals, the transmission gear is meshed with the rack, a central shaft of the transmission gear is overlapped with a central shaft of the bearing seat, and the turnover shaft is transversely and fixedly arranged in the transmission gear and the bearing seat in a penetrating mode.

4. The flip-chip blade battery formation mechanism of claim 3, wherein: the supporting mechanism frame is arranged above the turnover mechanism, a needle plate slide rail which is longitudinally arranged is arranged at the inner bottom of the supporting mechanism frame, and a turnover shaft is arranged outside the supporting mechanism frame.

5. The convertible blade battery formation mechanism of claim 4, wherein: the tray support assembly comprises fixed supports, movable supports and movable support driving cylinders which are arranged in parallel at intervals, the fixed supports are fixedly arranged at the bottom of the support mechanism frame, the movable supports are fixedly arranged on the movable needle plate frame, and supporting surfaces at the same horizontal height are arranged at the tops of the fixed supports and the movable supports and are supported at the bottom of the battery tray together; the movable support driving cylinder is arranged at the bottom of the support mechanism frame, and the telescopic end of the movable support driving cylinder is connected with the movable support and used for driving the movable support to longitudinally move.

6. The flip-chip blade battery formation mechanism of claim 5, wherein: the fixed clamping formation part comprises a fixed needle plate and a fixed needle plate driving cylinder; the fixed needle plate is slidably arranged on the first longitudinal needle plate slide rail; the fixed needle plate driving cylinder is horizontally arranged on the fixed support, and the telescopic end of the fixed needle plate driving cylinder is connected with the fixed needle plate and used for adjusting the longitudinal position of the fixed needle plate.

7. The flip-chip blade battery formation mechanism of claim 6, wherein: the movable clamping formation part comprises a movable needle plate and a movable needle plate driving cylinder; the movable needle plate is slidably arranged on the second longitudinal needle plate slide rail; the movable needle plate driving cylinder is horizontally arranged on the movable support; the movable needle plate drives the flexible end of cylinder with the movable needle plate links to each other for the adjustment the longitudinal position of movable needle plate.

8. The convertible blade battery formation mechanism of claim 7, wherein: the fixing needle plate comprises a first supporting section bar and a plurality of first probe assemblies, wherein the first supporting section bar is transversely arranged, the first probe assemblies are arranged on the supporting section bar and are mutually linked, and a transverse clamping groove is formed in the inner side, facing the battery tray, of the first supporting section bar; the head of the first probe component is provided with a probe, and the tail of the first probe component is slidably inserted into the transverse clamping groove of the first supporting section bar.

9. The convertible blade battery formation mechanism of claim 8, wherein: the movable needle plate comprises a second support section bar which is transversely arranged and a plurality of second probe assemblies which are arranged on the second support section bar and are mutually linked, and a transverse clamping groove is formed in the second support section bar facing the inner side of the battery tray; the number of the second probe assemblies is the same as that of the first probe assemblies and the second probe assemblies are opposite to each other, probes are arranged at the head of each second probe assembly, and the tail of each second probe assembly is slidably inserted into the transverse clamping groove of the corresponding second supporting section bar.

10. The flip-chip blade battery formation mechanism of claim 9, wherein: and a row of stop blocks are respectively arranged on the fixed support and the movable support along the transverse direction.

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