Conductive connecting plate for a lithium battery and a method for forming the same

Abstract

A conductive connecting plate for a lithium battery and a method for forming the same are provided. By punching a metal plate in a generally linear shape, the conductive connecting plate is formed to comprise an elongated positioning plate, a bending plate, and a first extending plate. The elongated positioning plate has a first and a second end in an elongated direction. The bending plate extends vertically downwards from the second end in a direction away from the second end. The first extending plate extends horizontally from one side of the bending plate in a direction away from and perpendicular to that side. Thereby, when the elongated positioning plate and first extending plate are electrically connected with a terminal component and a tab-set of a lithium battery core, it can meet the requirement for the charge and discharge of high-rate and large current.

Claims

1. A conductive connecting plate for a lithium battery, comprising: an elongated positioning plate, having a first end and a second end opposite to the first end in an elongated direction, the elongated positioning plate provided to be in electrical connection with a terminal component on a top of a lithium battery core; a bending plate, extending downwardly from the second end of the elongated positioning plate in a direction away from the second end and generally perpendicular to the elongated positioning plate; and a first extending plate, extending horizontally from one side of the bending plate in a direction away from the side and toward the first end and generally perpendicular to the bending plate, provided to be in electrical connection with a tab set of the lithium battery core.

2. The conductive connecting plate of a lithium battery according to claim 1, wherein the elongated positioning plate comprises a positioning part, a bending part, and an extending part that are extended in sequence along the elongated direction; the positioning part is provided to be in electrical connection with the terminal component on the top of the lithium battery core, and the bending part extends horizontally downwards at an angle from one end of the positioning part in a direction away from the end, so as to form a space between a lower portion of the positioning part and the bending part; and the extension part extends horizontally from one end of the bending part in a direction away from the end.

3. The conductive connecting plate of a lithium battery according to claim 2, further comprising a second extending plate, wherein the second extending plate extends from another side of the bending plate in a direction generally perpendicular to the bending plate, and the first extending plate and the second extending plate are parallel to each other.

4. The conductive connecting plate of a lithium battery according to claim 3, wherein one end of the first extending plate is provided with a first guiding plate, one end of the second extending plate is provided with a second guiding plate, and the first guiding plate and the second guiding plate extend respectively from the ends of the first extending plate and the second extending plate in a direction away from each other.

5. The conductive connecting plate of a lithium battery according to claim 2, further comprising a third extending plate, wherein the bending plate includes a base and at least two parallel lower protruding parts extending downwards from the base's bottom; the first extending plate extends horizontally from one side of one lower protruding part in a direction away from the side and generally perpendicular to the lower protruding part; and the third extending plate extends horizontally from one side of another lower protruding part in a direction away from the side and generally perpendicular to the another lower protruding part.

6. The conductive connecting plate of a lithium battery according to claim 5, further comprising a fourth extending plate, wherein the fourth extending plate extends from another side of the another lower protruding part in a direction generally perpendicular to the another lower protruding part, and the third extending plate and the fourth extending plate are parallel to each other.

7. The conductive connecting plate of a lithium battery according to claim 6, wherein one end of the third extending plate is provided with a third guiding plate, one end of the fourth extending plate is provided with a fourth guiding plate, and the third guiding plate and the fourth guiding plate extend respectively from the ends of the third extending plate and the fourth extending plate in a direction away from each other.

8. The conductive connecting plate of a lithium battery according to claim 1, further comprising a second extending plate, wherein the second extending plate extends from another side of the bending plate in a direction generally perpendicular to the bending plate, and the first extending plate and the second extending plate are parallel to each other.

9. The conductive connecting plate of a lithium battery according to claim 8, wherein one end of the first extending plate is provided with a first guiding plate, one end of the second extending plate is provided with a second guiding plate, and the first guiding plate and the second guiding plate extend respectively from the ends of the first extending plate and the second extending plate in a direction away from each other.

10. The conductive connecting plate of a lithium battery according to claim 1, further comprising a third extending plate, wherein the bending plate includes a base and at least two parallel lower protruding parts extending downwards from the base's bottom; the first extending plate extends horizontally from one side of one lower protruding part in a direction away from the side and generally perpendicular to the lower protruding part; and the third extending plate extends horizontally from one side of another lower protruding part in a direction away from the side and generally perpendicular to the another lower protruding part.

11. The conductive connecting plate of a lithium battery according to claim 10, further comprising a fourth extending plate, wherein the fourth extending plate extends from another side of another lower protruding part in a direction generally perpendicular to the another lower protruding part, and the third extending plate and the fourth extending plate are parallel to each other.

12. The conductive connecting plate of a lithium battery according to claim 11, wherein one end of the third extending plate is provided with a third guiding plate, one end of the fourth extending plate is provided with a fourth guiding plate, and the third guiding plate and the fourth guiding plate extend respectively from the ends of the third extending plate and the fourth extending plate in a direction away from each other.

13. A method for forming the conductive connecting plate for a lithum battery according to claim 1, comprising steps of: a. providing an elongated metal plate in a generally linear shape; b. punching the metal plate to form an elongated positioning plate, a bending plate, and a first extending plate; c. punching the bending plate to have the bending plate extended downwards in a direction generally perpendicular to the elongaed positioning plate; and d. punching the first extending plate to have the first extending plate horizontally extended in a direction generally perpendicular to the bending plate.

14. The method for forming the conductive connecting plate for a lithum battery according to claim 13, further comprising a step after the step b: punching the elongated positioning plate to form a positioning part, a bending part, and an extending part that are extended in sequence along an elongated direction, where the bending part is extended horizontally downwards at an angle from one end of the positioning part in a direction away from the end, so as to form a space between a lower portion of the positioning part and the bending part; and the extension part is extended horizontally from one end of the bending part in a direction away from the end.

15. The method for forming the conductive connecting plate for a lithum battery according to claim 14, further comprising a plurality of steps after the step b: punching a second extending plate, a first guiding plate, and a second plate, so that the second extending plate is extended from another side of the bending plate in a direction generally perpendicular to the bending plate; the first extending plate and the second extending plate are parallel to each other; and the first guiding plate and the second guiding plate are extended respectively from the ends of the first extending plate and the second extending plate in a direction away from each other.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] FIG. 1 is a perspective view showing a first embodiment of a conductive connecting plate for a lithum battery according to the present invention.

[0021] FIG. 2 shows the use of the first embodiment of the conductive connecting plate for a lithum battery according to the present invention.

[0022] FIG. 3 is a perspective view showing a second embodiment of a conductive connecting plate for a lithum battery according to the present invention.

[0023] FIG. 4 is a perspective view showing a third embodiment of a conductive connecting plate for a lithum battery according to the present invention.

[0024] FIG. 5 is a perspective view showing a matal plate in a linear shape used in a method for forming the conductive connecting plate for a lithum battery in the first embodiment according to the present invention.

[0025] FIG. 6 is a perspective view showing a punched elongated positioning plate in the method for forming the conductive connecting plate for a lithum battery in the first embodiment according to the present invention.

[0026] FIG. 7 is a perspective view showing the formation of a bending plate in the method for forming the conductive connecting plate for a lithum battery in the first embodiment according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0027] Please refer to FIG. 1, which shows a first embodiment of a conductuve connecting plate 1 for a lithium battery according to the present invention. The conductuve connecting plate 1 is formed by bending an elongated metal plate in a generally linear shape and comprises an elongated positioning plate 2, a bending plate 3, and a first extending plate 4.

[0028] The elongated positioning plate 2 is a generally rectagular plate. The elongated positioning plate 2 has a first end 21 and a second end 22 opposite to the first end 21 in an elongated direction. The elongated positioning plate 2 comprises a positioning part 23, a bending part 24, and an extending part 25 that are extended in sequence along the elongated direction. The positioning part 23 is provided with two holes 231 on its plate surface. The bending part 24 extends horizontally downwards at an angle from one end of the positioning part 23 in a direction away from the end, so as to form a space 241 between the lower portion of the positioning part 23 and the bending part 24. The extension part 25 extends horizontally from one end of the bending part 24 in a direction away from the end.

[0029] The bending plate 3 is a upright plate and extends downwardly from the second end 22 of the elongated positioning plate 2 in a direction away from the second end 22 and generally perpendicular to the elongated positioning plate 2. The first extending plate 4 is a rectagular upright plate and extends horizontally from one side of the bending plate 3 in a direction away from the side while toward the first end 21 of the elongated positioning plate 2 and generally perpendicular to the bending plate 3.

[0030] Thereby, when an insulation adhesive plate 9 is located in the space 241 between the positioning part 23 and the bending part 24 of the elongated positioning plate 2 while the positioning part 23 is in electrical connection with a terminal component 92 on a top of a lithum batter core 91, it is able to weld the first extending plate 4 onto a tab set 93 provided at one side of the lithum battery core 91, so as to establish a large-area electrical connection between the first extending plate 4 and the tab set 93.

[0031] Please refer to FIG. 3, which shows a perspective view showing a second embodiment of a conductive connecting plate 1 for a lithum battery according to the present invention. This embodiment is different from the first one in that: a second extending plate 5 is extended from another side of the bending plate 3 in a direction generally perpendicular to the bending plate 3, and the first extending plate 4 and the second extending plate 5 are parallel to each other. Thereby, when the first extending plate 4 and the second extending plate 5 are respectively welded to the tab set 93 provided at one side of the lithum battery core 91, it is able to increase the welding area with the tab set 93. Moreover, one end of the first extending plate 4 is provided with a first guiding plate 41, one end of the second extending plate 5 is provided with a second guiding plate 51, and the first guiding plate 41 and the second guiding plate 51 are extended respectively from the ends of the first extending plate 4 and the second extending plate 5 in a direction away from each other. Thereby, when the tab set 93 provided at one side of the lithum battery core 91 is inserted in-between the first extending plate 4 and the second extending plate 5, it is able to prevent the occurrence of short circuit caused by the piercing of the tab set 93 and is convenient for operation.

[0032] Please refer to FIG. 4, which shows a third embodiment of a conductive connecting plate 1 for a lithum battery according to the present invention. This embodiment is different from the first one and the second one in that: the bending plate 3 includes a base 31 and two parallel lower protruding parts 32, 33 extended downwards from the bottom of the base 31. The first extending plate 4 and the second extending plate 5 are extended horizontally from two sides of one lower protruding part 32 in a direction away from the two sides and generally perpendicular to the lower protruding part 32. A third extending plate 6 and a fourth extending plate 7 are extended horizontally from two sides of another lower protruding part 33 in a direction away from the two sides and generally perpendicular to the another lower protruding part 33. The third extending plate 6 and the fourth extending plate 7 are parallel to each other. Moreover, one end of the third extending plate 6 is provided with a third guiding plate 61, one end of the fourth extending plate 7 is provided with a fourth guiding plate 71, and the third guiding plate 61 and the fourth guiding plate 71 extend respectively from the ends of the third extending plate 6 and the fourth extending plate 7 in a direction away from each other.

[0033] In implementation, a method for forming the conductive connecting plate 1 in the first embodiment comprises steps of: [0034] a. providing an elongated metal plate 8 in a generally linear shape as shown in FIG. 5; [0035] b. punching the metal plate 8 to form an elongated positioning plate 2, a bending plate 3, and a first extending plate 4; [0036] c. as shown in FIG. 6, punching the elongated positioning plate 2 to form a positioning part 23, a bending part 24, and an extending part 25 that are extended in sequence along an elongated direction, where the bending part 24 is extended horizontally downwards at an angle from one end of the positioning part 23 in a direction away from the end, so as to form a space between a lower portion of the positioning part 23 and the bending part 24; and the extension part 25 is extended horizontally from a bottom of the bending part 24 in a direction away from the bottom; [0037] d. as shown in FIG. 7, punching the bending plate 3 to have the bending plate 3 generally perpendicular to the elongated positioning plate 2 and extended downwards; and [0038] e. as shown in FIG. 1, punching the first extending plate 4 to have the first extending plate 4 horizontally extended in a direction generally perpendicular to the bending plate 3 and toward the first end 21 of the elongated positioning plate 2.

[0039] Please refer to FIG. 3, which shows a method for forming the conductive connecting plate 1 for a lithum battery in the second embodiment. In this embodiment, in step b, a second extending plate 5 is simultaneously punched. In step c, one end of the first extending plate 4 and one end of the second extending plate 5 are punched respectively to form a first guiding plate 41 and a second guiding plate 51. In step e, while the first extending plate 4 is punched, the second extending plate 5 is extended from another side of the bending plate 3 in a direction generally perpendicular to the bending plate 3, the first extending plate 4 is made parallel to the second extending plate 5, and the first guiding plate 41 and the second guiding plate 51 are extended respectively from the ends of the first extending plate 4 and the second extending plate 5 in a direction away from each other.

[0040] As shown in FIG. 4, a method for forming the conductive connecting plate 1 for a lithum battery in the third embodiment is different from the formation method for the second embodiment lies in that: in step b, a bending plate 3, a third extending plate 6, and a fourth extending plate 7 are punched simultaneously, so as to have the bending plate 3 to include a base 31 and two parallel lower protruding parts 32, 33 that are extended downwards from one end of the base 31; in step c, one end of the third extending plate 6 and one end of the fourth extending plate 7 are punched respectively to form a third guiding plate 61 and a fourth guiding plate 71; and in step e, the third extending plate 6 is made to be parallel to the fourth extending plate 7, and the third guiding plate 61 and the fourth guiding plate 71 are extended respectively from the ends of the third extending plate 6 and the fourth extending plate 7 in a direction away from each other.

[0041] Therefore, the present invention has the following advantages:

[0042] 1. According to the present invention, the conductive connecting plate is formed integratedly by punching a metal plate, and a plurality of extending plates are formed to be in large-area electrical connection with a tab set. Thereby, it is able to stablize the voltage and current, fulfill the requirement of the charge and discharge of high-rate and large current, make the heat dissipation effective, lengthen the service time, and ensure the safety of use.

[0043] 2. According to the present invention, the conductive connecting plate is formed integratedly by punching a metal plate in a generally linear shape to form an elongated positioning plate, a bending plate, and at least one extending plate. Thereby, the area of the waste material could be reduced effectively during the punching process for the metal plate, so as to save the manufacturing cost.

[0044] 3. According to the present invention, one end of the first extending plate and one end of the second extending plate of the conductive connecting plate are respectively provided with a first guiding plate and a second guiding plate. Thereby, it would be convenient for an operator to insert the tab set provided at one side of a lithum battery core in-between the first extending plate and the second extending plate, so as to prevent the occurrence of short-circuiting caused by the piercing of the tab set during the assembling process and ensure the safety of use.

[0045] 4. According to the present invention, a space is formed between the elongated positioning plate and the bending plate. Thereby, an insulation adhesive plate could be securely located in-between the lithium battery core and the terminal component, so as to prevent the displacement of the insulation adhesive plate and thus ensure the safety of use.

[0046] Therefore, according to above-disclosed descriptions, the present invention can achieve the expected objects to provide a conductive connecting plate for a lithium battery, which could fulfill the requirement of the charge and the discharge of the high-rate and large current, improve the conductivity and the heat dissipation, reduce the manufacturing cost, and ensure the safety of use. It is novel and has industrial use.