KR100827707B1 - Core structure for a square lithium secondary battery - Google Patents

Abstract

The core structure for a rectangular lithium secondary battery includes a core, an electrode assembly, and two panic fixed assemblies. The individual layers of the positive and negative lead regions are clamped together by the conductive pressing pieces, thus the structure of the present invention is simple. In addition, the individual layers of the positive and negative lead regions are pressed against each other and in direct electrical contact therewith. Thus, the internal resistance of the present invention is relatively low and suitable for use in high capacity battery cases.

Rectangular lithium secondary battery, core structure, core, electrode assembly, fixed assembly, positive electrode lead region, negative electrode lead region, conductive pressing piece

Description

Core structure for rectangular lithium secondary battery {CORE STRUCTURE FOR A SQUARE LITHIUM SECONDARY BATTERY}

1 is an explanatory view of a core structure for a conventional lithium secondary battery disclosed in US Pat. No. 6,844,109.

2 is an exploded view of a core structure for a conventional lithium secondary battery disclosed in Taiwan Patent No. 1,233,227.

3 is an assembly view of a core structure for a conventional lithium secondary battery disclosed in Taiwan Patent No. 1,233,227.

4 is a perspective view showing a core structure for a lithium secondary battery according to the present invention;

5 is an assembly view showing a core structure for a lithium secondary battery according to the present invention.

6 is a cross-sectional view showing a core structure for a lithium secondary battery according to the present invention.

7 is an exploded view showing a structure for a lithium secondary battery according to the present invention before being installed in a battery case.

Fig. 8 is a sectional view showing the core structure for a lithium secondary battery according to the present invention after being installed in the battery case.

Fig. 9 is a sectional view showing the inside of a battery case in which a conductive sleeve is further provided in a core structure, according to the present invention.

<Explanation of symbols for the main parts of the drawings>

30 battery case 31 positive lead terminal

32: negative lead terminal 40: base

50 electrode assembly 60 fixed assembly

70: connecting member

The present invention relates to a core structure for a rectangular lithium secondary battery, and more particularly to the design of a conductive connection structure for the core of a lithium secondary battery.

Most rectangular lithium secondary batteries have a low capacity and can be recharged. For example, US Pat. No. 6,844,109 discloses a commonly used low-capacity rectangular lithium secondary battery, as shown in FIG. 1, wherein the core assembly 10 is basically an electrode assembly 11, a plurality of. Positive and negative lead 121, 122, and two conductive sleeves 13. The electrode assembly 11 includes an anode layer, a separation layer and a cathode layer, which generally overlap each other. The electrode is a multilayer structure formed by a superposition or odor method, a plurality of positive and negative leads extend from individual positive and negative layers, and finally two conductive press pieces are used as integrated leads for individual positive and negative leads. .

The secondary lithium battery described above is very simple, but its structure is so weak that it is only suitable for use as a structure of a low capacity battery, but not suitable for a high capacity dynamic battery. 2 and 3, the rectangular battery electrode assembly 20 disclosed in Taiwan Patent No. 1,233,227 includes an anode layer, a separation layer, and a cathode layer overlapping each other. The electrode assembly 20 is a spiral multilayer structure that winds around the base board 21. An uncoated region 22 is formed on one side of each of the anode and cathode layers, and then a plurality of main spacers 23 and sub spacers 24 are formed on the uncoated regions of the individual layers of the electrode assembly 20 ( 22, and finally a plurality of fixing pins 25 are inserted through the main spacer 23, the sub spacer 24 and the base board 21 to form an integrated electrical connection structure of the electrode assembly.

It is noted that the base board not only improves the structural strength of the cell structure, but also that multiple anode or cathode layers can be tightly wound around the base plate, making this design suitable for high capacity cells.

Conventional leads can be omitted by connecting the primary and secondary spacers directly to the individual layers of the electrode assembly of the electrode assembly, and thus the process of welding or forming the leads can be omitted. However, in this battery structure, each layer of the electrode assembly must be provided with a main spacer and a sub spacer. If the number of layers is large, this will increase the number of main and sub spacers, which will lead to an increase in manufacturing cost and complexity of the assembly process. And more importantly, the main spacers disposed in the individual layers of the electrode assembly will increase the internal resistance (contact resistance) of the core structure of the battery, resulting in problems of temperature increase and energy consumption. And, in the charging and discharging process of high capacity batteries, high contact resistance will result in oxidation due to the high temperature of the uncoated region of the electrode assembly.

The main object of the present invention is to provide a core structure for a rectangular lithium secondary battery. The individual layers of the positive and negative lead regions are clamped together by conductive pressing pieces, thus the structure of the present invention is simple. In addition, the individual layers of the anode and cathode lead regions are pressed against each other and in direct electrical contact therewith. '

It is a second object of the present invention to provide a core structure for a rectangular lithium secondary battery. The separate layers of the positive and negative lead regions are clamped together by conductive pressing pieces, and because the structure of the present invention is simple, the final cost and complexity of the assembly process will be substantially reduced.

The invention will become more apparent from the following description, with reference to the accompanying drawings, which show, by way of illustration, preferred embodiments of the invention.

4-7, the rectangular lithium secondary battery structure according to the preferred embodiment of the present invention includes a base 40, an electrode assembly 50, and two conductive fixing assemblies 60. As shown in FIG. The core structure is disposed in the rectangular battery case 30, and the positive and negative lead terminals 31 and 32 on both ends of the battery case 30 are electrically connected by two connecting members 70.

The base board 40 is disposed in the battery case 30.

The electrode assembly 50 includes at least one anode layer 51, a separation layer 52, and a cathode layer 53, which are superimposed on one another and then wound around the base board 40. The surfaces of the anode and cathode layers 51 and 53 are covered with a cathode material and a cathode material, respectively. Separation layer 52 is located between anode and cathode layers 51, 53. An uncoated region is formed on one side of the anode layer 51 for use as the anode lead region 511, and the cathode layer 52 is a side opposite the anode lead region 511 to the anode layer 51. An uncoated region is formed in the film for use as the cathode lead region 531. The anode and cathode lead regions 511 and 531 protrude from both sides of the assembly of the anode layer 51, the separation layer 52, and the cathode layer 53. After the electrode assembly 50 is formed by winding the anode layer 51, the separation layer 52 and the cathode layer 53 around the base board 40, the anode and cathode lead regions 511, 531 are formed. 50) will protrude from both ends.

Each conductive fixation assembly 60 includes a fastener 61 and two conductive pressing pieces 62. Through holes 621 are formed in each of the conductive pressing pieces 62, and are disposed outside the anode lead region 511 or the cathode lead region 531. The fastener may be a bolt and is inserted through the through hole 621 of one of the conductive pressing pieces 62, the through hole 621 of the other of the base board 40 and the conductive pressing piece 62, so that the two The conductive pressing piece 62 is fixed on the base board 40 and firmly pressed against the positive lead region 511 or the negative lead region 531, and the positive lead region 511 or the negative lead region 531. ) Is maintained in intimate electrical contact with the conductive pressing piece 62.

Each connecting member 70 is conductive having one end electrically connected to the conductive pressing piece 62 of the electrode assembly 50 and the other end electrically connected to the positive lead terminal 31 or the negative lead terminal 32. And a curved flexible structure.

The arrangement relationship between the core structure and the parts thereof is described above. The present invention intends to further use the connecting member as the electrically conductive connecting portion to further improve the design of the core structure and to connect the conductive pressing pieces to the positive lead region or the negative lead region, wherein the connecting member is a curved flexible structure. By this arrangement, even if there is a dimensional error in the core or the case, it can be overcome by the deformation of the connecting member, and thus the battery can be assembled successfully.

Referring again to FIGS. 4-8, uncoated wide lead regions 511, 531 are left on electrode assembly 50, and anode and cathode lead regions 511, 531 are multilayer structures. The conductive pressing pieces 62 of the conductive fixing assembly 60 are fixed to the outside of the positive and negative lead regions 511 and 531, and the fasteners are the through holes 621 and the base board 40 of the conductive pressing pieces 62. A portion of the conductive pressing piece 62 is firmly pressed against the individual layers of the anode and cathode lead regions 511 and 531, through and fixed thereto. In this manner, electrical energy of the electrode assembly 50 can be smoothly output from the conductive pressing piece 62 through the anode and cathode lead regions 511 and 531.

Note that the individual layers of the anode and cathode lead regions 511, 531 are clamped together by the conductive pressing piece 62, thus simplifying the structure of the present invention. In addition, the individual layers of the anode and cathode lead regions 511 and 531 are pressed against each other and in direct electrical contact therewith. Thus, compared with the conventional structures made of the main and sub spacers, the internal resistance of the present invention is significantly lowered and is suitable for use in high capacity battery cases.

In addition, as shown in FIG. 9, one end of the base board 40 may be covered with a conductive sleeve 80, and the conductive pressing piece 62 may face the positive and negative lead regions 511, 531. When pressurized, the conductive sleeve 80 improves the electrical connection between the pressing surfaces of the positive and negative lead regions 511, 531, thereby increasing the current path and reducing the resistance of the battery in the charging and discharging process of the battery. Can be.

According to this invention, the core structure for square lithium secondary batteries can be provided. The individual layers of the positive and negative lead regions are clamped together by conductive pressing pieces, thus the structure of the present invention is simple. In addition, the individual layers of the positive and negative lead regions are pressed against each other and in direct electrical contact therewith.

Moreover, according to this invention, the core structure for square lithium secondary batteries can be provided. The separate layers of the positive and negative lead regions are clamped together by conductive pressing pieces, and because the structure of the present invention is simple, the final cost and complexity of the assembly process will be substantially reduced.

Claims (3)

A core structure for a rectangular lithium secondary battery disposed in the battery case and electrically connected to the positive and negative lead terminals of the battery case by two conductive connecting members, An isolated base board disposed in the battery case, An electrode assembly comprising at least one anode layer, a separation layer and a cathode layer; Two conductive fixing assemblies each comprising at least one fastener and a conductive pressing piece, The anode layer, separation layer and cathode layer are superimposed on one another, and then wound around the base board, an uncoated region is formed on one side of the anode layer for use as the anode lead region, and the cathode layer is the anode An uncoated region is formed in the layer on the side opposite the anode lead region for use as the cathode lead region, the anode and cathode lead regions protrude from both sides of the electrode assembly, The conductive pressing piece is disposed outside the positive lead region or the negative lead region, and the fastener is inserted through the through hole of one of the conductive pressing pieces fixed to the base board, thereby firmly pressing against the positive lead region or the negative lead region. And the positive electrode lead region or the negative electrode lead region is in intimate electrical contact with the conductive pressing piece, and the conductive fixing assembly is electrically connected to the positive electrode lead terminal or the negative electrode lead terminal by a connecting member. The method of claim 1, wherein either end of the base board is covered with a conductive sleeve, and when the conductive pressing piece is pressed against the positive lead region or the negative lead region, the conductive sleeve is pressed against the positive lead region and the negative lead region. Core structure for rectangular lithium secondary batteries that can improve the electrical connection between faces. The core structure of claim 1, wherein the conductive connection member is a flexible wire.

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