KR20110008218U - A method for connecting poles of electric cells and a junction for poles of electric cells - Google Patents

Abstract

In particular, a connection method and a junction for a battery module for use in a power supply system in a vehicle having an electric or hybrid drive unit are disclosed. According to the proposed method, the flat poles of two adjacent cells are in contact with each other and clamped together, which are simultaneously curved between the shaping elements. In the created junction, the poles 4, 5 of the two adjacent cells 1 are clamped between the support and shaping element 2 and the cover and shaping element 3.

Description

A METHOD FOR CONNECTING POLES OF ELECTRIC CELLS AND A JUNCTION FOR POLES OF ELECTRIC CELLS

The present invention is a method of connecting the poles of electric cells, ie electric cells, and the poles of the batteries, which are particularly used when generating and operating a battery module for powering an electric or hybrid vehicle. It relates to the junction of a dragon. The individual cells in the module are electrically connected in series or in parallel, or a combination of both, i.

The positive electrode and the negative electrode are drawn out closely to each other since the two thin metal plates each consist of aluminum and copper. The structure of these poles is such that, because the materials to which they are connected have different electrochemical properties, the electrical device makes it possible to efficiently connect the cells into the battery modules, and when they are contacted, the cells are created in the presence of moisture. There is a problem that substantially accelerates corrosion in such a connection and degrades electrical and mechanical parameters. The higher resistance between the connected poles generates more heat where the connection takes place, which in turn accelerates the oxidation of the aluminum element at such a junction. For that reason, additional bimetallic separators are commonly used in known solutions when cell terminals made of two different metals are connected.

From Japanese Patent Application Laid-Open No. JP2007323952, a pack of a battery including a set of cells connected in series by a metal plate connecting a positive electrode with a negative electrode of adjacent cells is known. In order to provide a reliable, long life and low resistance connection, the cell poles are interconnected by ultrasonic welding techniques.

From European Patent Application Publication No. EP939956, there is also known a battery pack in which the leading ends of the connected electrodes are bent at an angle of 90 ° and connected in pairs to facilitate better use of space. In order to have poles of adjacent cells properly attached on a large surface area, it is important to properly position the tips of the connected electrodes. Contacted terminals of adjacent cells are connected by screw clamps, while proper adhesion of the terminal tip in a substantially flat plane is therefore provided due to their substantial thickness and therefore due to their proper stiffness.

It is an object of the present invention to provide such a configuration of a junction for the poles of batteries which ensures proper adhesion of the pole tips on a large plane and consequently a reliable long life electrical connection of small resistance for good use of space. There is.

It is a further object of the present invention to provide a joint that assembles cells (ie, batteries) into a pack and enables their operation with a lower risk of unintended short circuits.

A method of connecting the poles of the cells by contacting the flat poles of two adjacent cells and forcing them by a clamping element is characterized in that the poles of the adjacent cells are supported and shaping and covering and shaping elements. element) and is clamped at the same time.

The clamped poles are advantageously curved along at least one arcuate face.

The junction of the poles of the cells in which the poles of the two adjacent cells are held in contact with each other and clamped by the clamping element is characterized in that the poles of the adjacent cells are clamped between the support and the shaping element and the cover and the shaping element. .

In an advantageous solution, the support, shaping element as well as the cover, shaping element has an arcuate or trapezoidal-arch shaping face.

In an advantageous embodiment, the support, shaping element and / or the cover, shaping element is made of plastic.

 In another advantageous solution, a current lead-out is clamped between the support and the shaping element and the cover and the shaping element.

In another advantageous solution, an insulating front plate is arranged between the front part of the cells and the support and shaping element, the plate comprising an elliptical opening for receiving the poles of the cells. In addition, the poles of certain cells are connected to an electronic plate.

Through the clamping of the flat and flexible poles of adjacent cells between the support and shaping element and the cover and shaping element, the poles of the two cells are profiled and successfully pressed against each other to create less space. Get drunk

The shaping element is, according to the present invention, understood to be each element having a 3-D shaped, non-planarized contour plane, which gives the contour of bending while connecting by clamping the flat poles of the cells.

The solution according to the present invention is presented in exemplary embodiments in the following figures.

1 is a perspective view before clamping the junction for the poles of the cells;
2 is a perspective view before clamping a similar joint;
3 is a perspective view before clamping a junction for poles of batteries with a current terminal disposed between the support and shaping element and the cover and shaping element;
4 is a perspective view of a support / shaping element;
5 is a perspective view of a cover shaping element;
6 shows an insulating front plate;
7 is a plan view of a current drawer of the battery module;
8 is a cross-sectional view of the battery module through screws clamping the support and shaping element and the cover and shaping element;
9 is a sectional view through the assembled battery module;
10 is a perspective view of the components of a single battery module.

As shown in FIGS. 1 and 2, the pole junction of the cells 1 has a support / shaping element 2 and a cover-shaping element 3, between two adjacent cells 1. The poles 4, 5 are located, the poles 4, 5 being in contact with one another, surrounding the support and shaping element 2, by means of screws 6 which are clamping elements the cover shaping element 3. Pressurized through). The support and shaping elements 2 as well as the cover and shaping elements 3 illustrated in FIG. 1 have their shaping surfaces made in the shape of an arch. In FIG. 2, different junctions for the poles of the cells 1 are shown, wherein the support and shaping element 2 as well as the cover and shaping element 3 have a trapezoidal-arch shaping plane. The trapezoidal-arched shape of these elements is created as an equilateral trapezoid substantially in cross section through their shaping plane, while the arms of the trapezoid are determined by an arcuate line.

According to the method, which is the object of the present invention, the flat poles of two adjacent cells remain in contact with each other over a substantial portion of their sides and are clamped together between the shaping elements simultaneously in a bent (ie bent) state. . The support shaping element 2 and the cover shaping element 3 are used as the shaping element, and the clamping is achieved by screws 6.

Before clamping, the poles 4, 5 have a flat rectangular shape, and after clamping they take the shape of the pressing surfaces of the support / shaping element 2 and the cover / shaping element 3. The pole 4 in contact with the support and shaping element 2 bends while clamping on the outer convex pressing surface of the shaping element, while the pole 5 in contact with the cover and shaping element is positioned below it. (4) at the same time. Thus, the structure of the joint according to the present invention is such that the contact surfaces of the poles 4 and 5 are forcibly displaced with respect to each other when they are clamped by the support and shaping element 2 and the cover and shaping element 3 and simultaneously shaped. Be sure to This relative displacement between the contact surfaces of the poles 4, 5 is caused by the fact that the outer surface of the inner pole 4 is stretched while bending, while the inner surface of the outer pole 5 is pressed during the bending. This connection, in which the faces of the poles being contacted against each other, is characterized by a lower resistance, which is associated with greater efficiency and longer life of the electrical connection. This relative displacement of the battery poles against each other in the state that the poles are simultaneously shaped is achieved in each form of the support and shaping element 2 and the cover and shaping element 3. However, in the known solution there is no such effect when pressing the flat battery poles by the flat support and cover clamping elements.

3 shows a junction according to the present invention. This junction is connected to the current drawer 7 to connect the two furthest batteries 1.

4 shows a perspective view of one embodiment of a support, shaping element 2 having an external shaping surface. This support / shaping element 2 has openings 8 for receiving screws 6, while the length of this shaping element is chosen to be approximately equal to the width of the poles 4,5. In order to minimize the possibility of unintended short-circuits during assembly and during operation of the joint, the support / shaping element 2 is made of plastic, for example polypropylene.

5 shows a perspective view of a cover shaping element 3 with an inner shaping surface. This cover shaping element 3 has openings 9 for receiving the screws 6. The length of the cover shaping element 3 corresponds to the length of the cooperating support shaping element 2. This cover shaping element 3 is made of plastic, for example polypropylene, for the same reasons as the support shaping element 2.

A further risk of a short circuit in the operation of the joint according to the present invention is limited by the insulating front plate 10 shown in FIG. 6. This insulating front plate made of plastic has openings 11 for clamping screws 6 and two rows of elliptical openings 12 for the poles 4, 5 of the batteries 1. The elliptical openings 12 are equidistant in each row to ensure equidistance between the junctions of the poles 4, 5 of the cells 1 in the battery module. In order to connect adjacent battery modules into a set of modules, current draw is applied to the first junction according to the present invention to be connected to the positive electrode of the uppermost cell in the battery module as well as to the last junction to be connected to the negative electrode of the lowermost battery in the battery module. Part 7 is further provided. The shape of the current drawing portion is shown in FIG.

A part of the battery module 13 including a plurality of junctions according to the present invention is shown in FIG. 8. The poles 4, 5 of the cells 1 are drawn out through the insulating front plate 10, enclosed by the support and shaping elements 2 and pressed by the cover and shaping elements 3. In the illustrated embodiment, the screws act as clamping elements. The battery module 13 also includes an electronic substrate 14 which collects voltages from all the cells 1, which are connected to a battery control system. The fully assembled battery module 13 is shown in FIG. 9. The module has a housing 15 for protecting a stack comprising nine cells 1 connected in series by junctions according to the present invention.

A perspective view before assembly of the components of one battery module 13 is illustrated in FIG. 10. This figure shows nine cells 1 partially out of the housing 15.

Since the insulating front plate 10 lies on straight poles 4, 5 for connecting the cells 1 of the battery module 13, these poles pass through the elliptical openings 12 and then the appropriate poles ( 4, 5 surround the support and shaping element 2 in pairs, the poles being pressed by the screws 6 to the cover and shaping element 3 and then collect the voltage from all the cells 1. An electronic board 14 is provided and connected to the battery control system. In addition, a current drawing portion 7 is further provided at the outermost junctions of the battery poles, that is, the left junction of the top and the right junction of the bottom.

Claims (10)

A method of connecting the poles of cells by contacting the flat poles of two adjacent electric cells and forcing these poles by a clamping element,
The poles 4, 5 of the adjacent cells 1 are clamped between the supporting and shaping element 2 and the covering and shaping element 3 and bent simultaneously. The method of connecting the poles of the batteries. Method according to claim 1, characterized in that the clamped poles (4, 5) are bent along at least one arcuate shaping plane. As a junction of the poles of the cells in which the poles of two adjacent cells remain in contact and are clamped by the clamping element,
The junction of the poles of the cells, characterized in that the poles (4, 5) of the adjacent cells (1) are clamped between the support and shaping element (2) and the cover and shaping element (3). 4. The junction of the poles of batteries according to claim 3, wherein the support and shaping element (2) as well as the cover and shaping element (3) have an arcuate shaped surface. 4. The junction of the poles of cells according to claim 3, wherein the support and shaping element (2) and the cover and shaping element (3) have a face shaped in a trapezoidal-arch shape. 6. The junction of the poles of cells according to any one of claims 3 to 5, wherein the support and shaping element (2) is made of plastic. 6. The junction of the poles of cells according to claim 3, wherein the cover shaping element is made of plastic. 7. A current lead-out (7) is clamped between the support and shaping element (2) and the cover and shaping element (3). Junction of the poles of the cells. The insulating front plate (10) having an elliptical opening is located between the front part of the batteries (1) and the support and shaping element (2). The junction of the poles of the cells, characterized in that the poles of the cells (1) pass through the opening. 4. The junction of the poles of cells according to claim 3, wherein the poles of the particular cells (1) are further connected to an electronic plate (14).

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