CN213688863U - Flexible vibration frock of battery package - Google Patents

Abstract

The utility model discloses a battery pack flexible vibration tool, which comprises a frame and a battery box body arranged in the frame, wherein the frame is also provided with an X-axis adjusting mechanism for adjusting the X direction of the battery box body, a Y-axis adjusting mechanism for adjusting the Y direction of the battery box body and a Z-axis adjusting mechanism for adjusting the Z direction of the battery box body; this vibration frock dismouting is convenient fast, simple structure, and low in manufacturing cost, repetitious usage for a lot of, for traditional vibration mechanism, compatibility improves greatly, can compatible most battery box installation demand, has further reduced use cost, is favorable to using widely in a large number.

Description

Flexible vibration frock of battery package

Technical Field

The utility model relates to a lithium cell preparation technical field especially relates to a battery package flexible vibration frock.

Background

Lithium batteries are batteries using a nonaqueous electrolyte solution and using lithium metal or a lithium alloy as a negative electrode material. The lithium battery module is a combination body which is formed by combining lithium batteries in a series-parallel mode and can directly supply power after a circuit board and a shell are protected.

Lithium battery box is in process of production, need carry out intensity vibration test to lithium battery box, the modal test experiment, according to industry standard, need carry out the box vibration experiment according to the mounted state of battery box in the car, this process needs vibration mechanism simulation car installation inner chamber fixed battery box, traditional vibration mechanism is according to the unique structural feature of each battery box, design vibration mechanism and install the battery box, this kind of mode compatibility is very poor, can only satisfy the vibration demand of single battery box, very big extravagant experimental cost, prolong the experimental period.

SUMMERY OF THE UTILITY MODEL

Based on the technical problem that the background art exists, the utility model provides a battery package flexible vibration frock, the dismouting is quick convenient, simple structure, and used repeatedly many times, it is compatible big.

The utility model provides a pair of battery package flexible vibration frock, include the frame and set up the battery box in the frame, still be provided with the X axle adjustment mechanism who is used for adjusting battery box X direction on the frame, the Y axle adjustment mechanism who is used for adjusting battery box Y direction, the Z axle adjustment mechanism who is used for adjusting battery box Z direction, X axle adjustment mechanism and frame fixed connection, Y axle adjustment mechanism and X axle adjustment mechanism fixed connection, Z axle adjustment mechanism and Y axle adjustment mechanism fixed connection, battery box and Z axle adjustment mechanism fixed connection.

Furthermore, X axle adjustment mechanism includes the U template, has seted up first waist type hole on the U template, and the support frame of setting up in the relative both sides of frame is respectively erect at the both ends of U template, and first waist type hole is fixed with the first screw hole spiro union of seting up on the support frame.

Furthermore, a protruding block is further arranged at the contact position of the U-shaped plate and the supporting frame, and the protruding block is nested in a first groove formed in the supporting frame.

Furthermore, the Y-axis adjusting mechanism comprises an L-shaped moving plate, one bending surface of the L-shaped moving plate is fixedly connected with the U-shaped plate, and the other bending surface of the L-shaped moving plate is fixedly connected with the Z-axis adjusting mechanism.

Furthermore, a plurality of second waist-shaped holes are formed in the U-shaped plate and are arranged in a staggered mode, a second threaded hole is formed in the L-shaped moving plate, and the second waist-shaped holes are fixedly connected with the second threaded hole in a threaded mode.

Furthermore, the Z-axis adjusting mechanism comprises a T-shaped pull lug plate, a third threaded hole is formed in one side face of the T-shaped pull lug plate, a third waist-shaped hole is formed in the L-shaped moving plate and is arranged in a staggered mode, and the third waist-shaped hole is fixedly connected with the third threaded hole.

Furthermore, a fourth waist-shaped hole is formed in the other side face of the T-shaped pull lug plate, and the battery box body is fixedly connected with the T-shaped pull lug plate through the fourth waist-shaped hole.

Furthermore, second grooves are formed in the side face, provided with the third waist-shaped hole, of the L-shaped moving plate, and the second grooves are arranged in rows at equal intervals; the T-shaped lug plate is provided with third grooves on the side surface provided with third threaded holes, the third grooves are arranged in rows at equal intervals, and the second grooves and the third grooves are arranged in a nested connection mode.

Furthermore, a plurality of mounting holes are formed in the frame, and the frame is fixed on the vibration equipment through the mounting holes.

The utility model provides a pair of battery package flexible vibration frock's advantage lies in: the flexible vibration tool for the battery pack provided by the structure of the utility model has the advantages of quick and convenient assembly and disassembly, simple structure, low manufacturing cost, repeated use, greatly improved compatibility compared with the traditional vibration mechanism, compatibility with most of the installation requirements of the battery box body, further reduced use cost and contribution to large-scale popularization and use; the battery box body is adjusted and positioned in a three-dimensional space through the X-axis adjusting mechanism, the Y-axis adjusting mechanism and the Z-axis adjusting mechanism, so that the position of the battery box body in the frame is adjusted, the mechanism of each fixed battery box body is uniformly stressed, the vibration uniformity of the tool for fixing the battery box body on the vibration equipment is improved, and the accuracy and the stability of the vibration test of the battery box body are finally improved.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a schematic view of the connection structure among the X-axis adjusting mechanism, the Y-axis adjusting mechanism and the Z-axis adjusting mechanism;

FIG. 4 is a schematic structural view of an X-axis adjustment mechanism;

FIG. 5 is a schematic structural view of a Y-axis adjustment mechanism;

FIG. 6 is a schematic structural view of a Z-axis adjustment mechanism;

the battery box comprises a frame 1, a battery box 2, an X-axis adjusting mechanism 3, a Y-axis adjusting mechanism 4, a Z-axis adjusting mechanism 5, a support frame 11, a first threaded hole 12, a first groove 13, a first groove 14, a mounting hole 31, a U-shaped plate 32, a first kidney-shaped hole 33, a lug 34, a second kidney-shaped hole 34, a 41-L-shaped moving plate 42, a second threaded hole 43, a third kidney-shaped hole 44, a second groove 51, a T-shaped lug plate 52, a third threaded hole 53, a fourth kidney-shaped hole 54 and a third groove.

Detailed Description

The technical solutions of the present invention are explained in detail below with reference to specific embodiments, and many specific details are set forth in the following description to provide a thorough understanding of the present invention. The present invention can be embodied in many other forms than those specifically described herein, and it will be apparent to those skilled in the art that similar modifications can be made without departing from the spirit and scope of the invention.

As shown in fig. 1 to 6, the utility model provides a battery package flexible vibration frock, include frame 1 and set up the battery box 2 in frame 1, still be provided with the X axle adjustment mechanism 3 that is used for adjusting battery box 2 in the X direction on the frame 1, a Y axle adjustment mechanism 4 for adjusting battery box 2 in the Y direction, a Z axle adjustment mechanism 5 for adjusting battery box 2 in the Z direction, X axle adjustment mechanism 3 and frame 1 fixed connection, Y axle adjustment mechanism 4 and X axle adjustment mechanism 3 fixed connection, Z axle adjustment mechanism 5 and Y axle adjustment mechanism 4 fixed connection, battery box 2 and Z axle adjustment mechanism 5 fixed connection.

Carry out three-dimensional space adjustment location to battery box 2 through X axle adjustment mechanism 3, Y axle adjustment mechanism 4, Z axle adjustment mechanism 5 to the position of adjustment battery box 2 in frame 1 makes the mechanism atress of each fixed battery box 2 even, and then has improved the vibration homogeneity of frock of fixed battery box 2 on vibration equipment, has finally improved the accuracy and the stability of battery box 2 vibration testing.

When the whole tool is fixed on the vibration equipment, the frame 1 is provided with a plurality of mounting holes 14, and the frame 1 is fixed on the vibration equipment through the mounting holes 14. Preferably, the mounting holes 14 are arranged around the frame 1 at equal intervals, so that the tool can be stably fixed on the vibrating equipment through the mounting holes 14.

Further, the X-axis adjusting mechanism 3 includes a U-shaped plate 31, a first waist-shaped hole 32 is formed in the U-shaped plate 31, two ends of the U-shaped plate 31 are respectively erected on the support frames 11 on two opposite sides of the frame 1, and the first waist-shaped hole 32 is fixed to a first threaded hole 12 formed in the support frame 11 in a threaded manner.

The first threaded holes 12 are formed in the support frame 11 at equal intervals in the length direction, and the first waist-shaped holes 32 are fixedly connected with the first threaded holes 12 at different positions, so that the U-shaped plate 31 can move in the length direction of the support frame 1. Meanwhile, the waist-shaped design of the first waist-shaped hole 32 enables the U-shaped plate 31 to be finely adjusted in the direction perpendicular to the supporting frame 11.

At the fixed in-process of U template 31 and support frame 11, for the convenience of U template 31 with fixed, can specifically be through certain spacing realization: the U-shaped plate 31 is also provided with a convex block 33 at the contact position with the support frame 11, and the convex block 33 is nested in a first groove 13 formed in the support frame 11; the first groove 13 and the first threaded hole 12 are oppositely arranged, so that after the bump 33 is sleeved in the first groove 13, the first threaded hole 12 corresponds to the first kidney-shaped hole 32, and the U-shaped plate 31 and the support frame 11 can be effectively fixed through screw/bolt fixation. The protrusions 33 may be arranged in a row, and the corresponding first grooves 13 are also arranged in a row.

Further, the Y-axis adjusting mechanism 4 includes an L-shaped moving plate 41, wherein one bending surface of the L-shaped moving plate 41 is fixedly connected with the U-shaped plate 31, and the other bending surface is fixedly connected with the Z-axis adjusting mechanism 5. The two bending surfaces of the L-shaped moving plate 41 are perpendicular to each other.

A plurality of second waist-shaped holes 34 are formed in the U-shaped plate 31, the second waist-shaped holes 34 are arranged in a staggered mode to guarantee the strength of the whole structure, a second threaded hole 42 is formed in the L-shaped moving plate 41, and the second waist-shaped holes 34 are fixedly connected with the second threaded hole 42 in a threaded mode. By changing the fixing position between the second threaded hole 42 and the second kidney-shaped hole 34, the fixing position between the L-shaped moving plate 41 and the U-shaped plate 31 can be adjusted, and the movement of the L-shaped moving plate 41 in the Y-axis direction is realized. Meanwhile, enough fixing space is reserved when the second waist-shaped hole 34 is fixed with the second threaded hole 42, and the defect that when two threaded holes of the same specification are arranged in a corresponding mode, the threaded holes are staggered to a certain extent and cannot be fixed well is overcome.

Further, the Z-axis adjusting mechanism 5 includes a T-shaped tab plate 51, a third threaded hole 52 is formed in one side surface of the T-shaped tab plate 51, a third kidney-shaped hole 43 is formed in the L-shaped moving plate 41, the third kidney-shaped holes 43 are arranged in a staggered manner to ensure the strength of the whole structure, and the third kidney-shaped holes 43 are fixedly connected with the third threaded hole 52. The fixing positions of the T-shaped pull lug plate 51 and the L-shaped moving plate 41 can be adjusted by changing the fixing positions between the third threaded holes 52 and the third waist-shaped holes 43, so that the T-shaped pull lug plate 51 can move in the Z-axis direction, meanwhile, enough fixing space is reserved when the third waist-shaped holes 43 are fixed with the third threaded holes 52, and the defect that when two threaded holes of the same specification are arranged, the threaded holes are dislocated to cause poor fixing is overcome.

Specifically, a fourth waist-shaped hole 53 is formed in the other side surface of the T-shaped tab plate 51, and the battery case 2 is fixedly connected with the T-shaped tab plate 51 through the fourth waist-shaped hole 53. Through the movement of the U-shaped plate 31 in the X-axis direction, the movement of the L-shaped moving plate in the Y-axis direction and the movement of the T-shaped pull lug plate 51 in the Z-axis direction, the position movement of the battery box body 2 in a three-dimensional space is realized so as to adjust the position in the frame 1, and the structure of each hospital fixed battery box body 1 in the frame 1 is uniformly stressed.

On the fixed attached face of L type movable plate 41 and T type tab board 51, in order to improve the anti-skidding setting between L type movable plate 41 and T type tab board 51, can be through increasing the frictional force of two attached faces, specifically be: the side surface of the L-shaped moving plate 41 provided with the third waist-shaped hole 43 is provided with second grooves 44, and the second grooves 44 are arranged in rows at equal intervals; the T-shaped pull lug plate 51 is provided with a third groove 54 on the side surface provided with a third threaded hole 52, the third grooves 54 are arranged in rows at equal intervals, and the second grooves 44 and the third grooves 54 are connected in a nested manner, so that the L-shaped moving plate 41 and the T-shaped pull lug plate 51 are not easy to slide, the structural stability of the whole tool is improved, and the vibration stability of the battery box body 1 is further improved.

The working process is as follows: during installation, the T-shaped lug plate 51 is connected with the lugs of the battery box body 2 by using bolts, pre-tightening force does not need to be added for the connection, the T-shaped lug plate 51 can be ensured to move relative to the lugs of the battery box body 2, then the T-shaped lug plate 51 is matched with the L-shaped movable plate 41 and then is preliminarily connected, the L-shaped movable plate 41 is connected with the U-shaped plate 31, then the battery box body 2 is integrally hoisted into the frame 1, the battery box body 2 is suspended above the frame 1, the lug distance between the T-shaped lug plate 51 and the battery box body 2 is adjusted according to the actual lug hanging condition of the battery box body 2, the height direction displacement between the L-shaped movable plate 41 and the T-shaped lug plate 51 is adjusted, the width direction distance between the L-shaped movable plate 41 and the U-shaped plate 31 is adjusted, the fixed positions of the U-shaped plate 31 and the supporting frame 11 in the length direction are adjusted, and, the battery box body 2 is slowly placed into the frame 1 integrally, each part bears the gravity of the battery box body 2, all screw parts are locked, mutual assembly between the battery box body 2 and the whole vibration tool is completed, the whole vibration tool is lifted to a vibration platform of vibration equipment integrally, and the frame 1 is tightly connected with the vibration platform by utilizing mounting holes 14 reserved around the frame 1.

During disassembly, after the vibration experiment is completed, the battery box body 2 is firstly hung for bearing, then the hangers of the battery box body 2 and the bolts between the T-shaped lug plates 51 are removed, at the moment, the battery box body 2 can be moved to other places from the vibration platform by utilizing the crane, then the T-shaped lug plates 51, the L-shaped movable plates 41 and the U-shaped plates 31 on the whole vibration tool are sequentially detached from the frame 1 and respectively placed into specific positions for storage, and then the frame 1 is detached from the vibration platform by utilizing the crane, so that the part disassembly work of all the vibration experiments can be completed.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (9)

1. The utility model provides a battery package flexible vibration frock, a serial communication port, including frame (1) and battery box (2) that set up in frame (1), still be provided with X axle adjustment mechanism (3) that are used for adjusting battery box (2) X direction on frame (1), Y axle adjustment mechanism (4) that are used for adjusting battery box (2) Y direction, Z axle adjustment mechanism (5) that are used for adjusting battery box (2) Z direction, X axle adjustment mechanism (3) and frame (1) fixed connection, Y axle adjustment mechanism (4) and X axle adjustment mechanism (3) fixed connection, Z axle adjustment mechanism (5) and Y axle adjustment mechanism (4) fixed connection, battery box (2) and Z axle adjustment mechanism (5) fixed connection.

2. The flexible vibration tool for the battery pack according to claim 1, wherein the X-axis adjusting mechanism (3) comprises a U-shaped plate (31), a first waist-shaped hole (32) is formed in the U-shaped plate (31), two ends of the U-shaped plate (31) are respectively erected on the support frames (11) on two opposite sides of the frame (1), and the first waist-shaped hole (32) is fixed with a first threaded hole (12) formed in each support frame (11) in a threaded manner.

3. The flexible vibration tool for the battery pack according to claim 2, wherein a protruding block (33) is further arranged at a contact position of the U-shaped plate (31) and the support frame (11), and the protruding block (33) is nested in a first groove (13) formed in the support frame (11).

4. The flexible vibration tool for the battery pack according to claim 2, wherein the Y-axis adjusting mechanism (4) comprises an L-shaped moving plate (41), one bending surface of the L-shaped moving plate (41) is fixedly connected with the U-shaped plate (31), and the other bending surface of the L-shaped moving plate is fixedly connected with the Z-axis adjusting mechanism (5).

5. The flexible vibration tool for the battery pack according to claim 4, wherein the U-shaped plate (31) is provided with a plurality of second kidney-shaped holes (34), the second kidney-shaped holes (34) are arranged in a staggered manner, the L-shaped moving plate (41) is provided with second threaded holes (42), and the second kidney-shaped holes (34) and the second threaded holes (42) are fixedly connected in a threaded manner.

6. The flexible vibration tool for the battery pack according to claim 4, wherein the Z-axis adjusting mechanism (5) comprises a T-shaped lug pulling plate (51), a third threaded hole (52) is formed in one side face of the T-shaped lug pulling plate (51), a third waist-shaped hole (43) is formed in the L-shaped moving plate (41), the third waist-shaped holes (43) are arranged in a staggered mode, and the third waist-shaped holes (43) are fixedly connected with the third threaded hole (52).

7. The flexible vibration tool for the battery pack according to claim 6, wherein a fourth waist-shaped hole (53) is formed in the other side surface of the T-shaped pull lug plate (51), and the battery box body (2) is fixedly connected with the T-shaped pull lug plate (51) through the fourth waist-shaped hole (53).

8. The flexible vibration tool for the battery pack according to claim 7, wherein the L-shaped moving plate (41) is provided with second grooves (44) on the side surface provided with the third kidney-shaped hole (43), and the second grooves (44) are arranged in rows at equal intervals; the T-shaped pull lug plate (51) is provided with third grooves (54) on the side surface provided with third threaded holes (52), the third grooves (54) are arranged in rows at equal intervals, and the second grooves (44) and the third grooves (54) are arranged in a nested connection mode.

9. The flexible vibration tool for the battery pack according to claim 7, wherein the frame (1) is provided with a plurality of mounting holes (14), and the frame (1) is fixed on the vibration equipment through the mounting holes (14).

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