RU2454757C2 - Connecting structure for external connection of galvanic elements - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: connecting device for external connection of battery cells includes, at least, one connecting element from graphite mixture designed for electric consecutive or parallel connection of two battery cells. In order the connection of battery cells had high electrical conductivity without the application of traditional welding technologies the connecting element from graphite mixture is in close contact with nickel or nickel-plated outputs of battery cells. Connecting element from graphite mixture has lower cost and oxidisability; note that close contact of connecting element from graphite mixture with nickel-plated metallic outputs of positive and negative battery cells leads to their relative dissolution with formation of solid solution containing nickel and carbon, note that due to resistance decrease of external connection a gradual discharge at heavy currents is provided.

EFFECT: decrease of coast and resistance losses.

5 cl, 8 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to an oxidation resistant non-welded connecting device for external connection of battery cells, providing high conductivity of connecting multiple battery cells to each other.

BACKGROUND

Existing high-power batteries are typically a series, parallel or series-parallel connection of a plurality of battery cells by means of connecting plates. Both the terminals of the positive and negative electrodes of the corresponding battery cells, and the connecting plates are usually made of nickel or nickel-plated metal, since nickel is resistant to oxidation and, therefore, better reliability for long service life. As shown in FIGS. 1 and 2, in a conventional secondary battery, both series and parallel connection of all the battery cells 11 is carried out by means of a connecting plate 10 welded to the metal terminals 12 of the electrodes of the battery cells 11 at several welding points 13 to reduce external contact resistance battery pack.

It should be noted that the above-described technology for connecting traditional battery cells, in which the electrical connection of two battery cells with nickel connecting plates is carried out by spot welding, has many disadvantages, among which are the following:

1. Long-term operation will ultimately lead to oxidation or contamination of the nickel plates by foreign substances, resulting in an increase in the electrical resistance of the plates.

2. The connection of nickel connecting plates with the terminals of the electrodes of the battery cells at the welding points occurs, as a rule, at small contact areas, resulting in high contact resistance and, consequently, an increase in the temperature of the terminals of the electrodes of the battery cells and welding points, as well as additional losses of battery power elements in the process of recharging or discharging.

3. The combination of the high cost of nickel connecting plates with significant time and labor costs associated with the welding process, makes the traditional technology of battery assembly uneconomical.

The objective of the present invention is to correct and / or eliminate the above disadvantages.

SUMMARY OF THE INVENTION

The primary objective of the present invention is to provide a connecting device for external connection of the battery cells, in which according to the present invention as the connecting part for series or parallel connection of two battery cells is used mainly at least one connecting element of a mixture of graphite. According to the present invention, the connection of a connecting element from a mixture of graphite directly with the terminals of the electrodes of the battery cells will make it possible to dispense with the use of traditional welding technologies when making connections with high conductivity. In addition, since a connecting element made of a mixture of graphite is cheaper than nickel, this will significantly reduce production costs.

Additionally, the present invention solves the problem of creating a connecting device for the external connection of the battery cells, in which a connecting element made of a mixture of graphite is mainly used for series or parallel electrical connection of two battery cells. The connecting element of a mixture of graphite in itself is resistant to oxidation. The tight mutual contact of the connecting element from the graphite mixture with the terminals of the positive and negative electrodes of the battery cells starts the process of their mutual dissolution, namely, the process of replacing the foreign substances present on the surfaces of the terminals of the negative and positive electrodes of the battery cells with carbon particles of the connecting element from the graphite mixture in this way what happens is the filling of voids in the metal surfaces of the terminals of the negative and positive electrons rows of battery cells, which leads eventually to the formation of a solid solution with nickel, and carbon, while by reducing the external connection provided by smooth discharge resistance at high currents.

To solve the above problems, the present invention proposes a connecting device for external serial connection of the battery cells, comprising: a first battery cell with an external nickel-plated metal terminal of the positive electrode and the terminal of the negative electrode, designed to take power from the first galvanic cell; at least one graphite connecting element made of a mixture of graphite selected from the group comprising a mixture of silver and graphite, a mixture of copper and graphite, a mixture of silver, copper and graphite, and connected to the terminal of the positive electrode of the first battery cell; a second battery cell with external nickel-plated metal terminal of the positive electrode and the output of the negative electrode, designed for power take-off from the second battery cell. The negative electrode terminal of the second battery cell is connected to the connecting element from a mixture of graphite in such a way as to make a series connection of the first and second battery cells.

A connection device is also provided for external parallel connection of battery cells, comprising: a first battery cell with external nickel-plated metal terminal of a positive electrode and a terminal of a negative electrode for power take-off from the first battery cell; at least one first connecting graphite element made of a mixture of graphite selected from the group comprising a mixture of silver and graphite, a mixture of copper and graphite, a mixture of silver, copper and graphite, and connected to the terminal of the positive electrode of the first battery cell; a second battery cell with an external nickel-plated metal terminal of the positive electrode and a terminal of the negative electrode for power take-off from the second battery cell, the terminal of the positive electrode of the second battery cell being connected to the first graphite connecting element; and at least one second connecting graphite element made of a mixture of graphite selected from the group comprising a mixture of silver and graphite, a mixture of copper and graphite, a mixture of silver, copper and graphite, and connected to the negative electrode terminal of the first battery cell and the output of the negative electrode of the second battery cell in such a way as to parallel the first and second battery cells.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a perspective view of a fragment of a traditional battery, made in series connection of the battery cells by means of a Nickel plate.

Figure 2 shows the design of another traditional battery, made in parallel connecting the battery cells by means of a nickel plate.

Figure 3 shows a schematic view of a connecting device for external serial connection of the battery cells by means of a connecting element made of a mixture of graphite.

Figure 4 shows a schematic view of a connecting device for external parallel connection of battery cells by means of a connecting element made of a mixture of graphite.

Figure 5-1 shows the corresponding terminals of the electrodes of the battery cell with a surface contaminated with foreign substances, as described in the present invention.

Figure 5-2 shows the substitution of a foreign substance by carbon particles after the connecting element from the graphite mixture comes into contact with the electrode exit surface, as described in the present invention.

Figure 6 shows a side view of the battery, made in series-parallel connection of the battery cells by means of a connecting element made of a mixture of graphite, according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

For a better understanding of the present invention, a description thereof is given below with reference to the accompanying drawings, used solely to illustrate a preferred embodiment of the present invention.

Figure 3 shows the series connection of two battery cells, in which, to improve the electrical conductivity between the first and second battery cells 20, 40, the connection between the first and second battery cells 20, 40 is made by means of at least one connecting element made of a mixture of graphite.

The first battery cell 20 is a cylindrical battery cell, at both ends of which there is an external terminal 21 of the positive electrode made of nickel-plated metal and a terminal of the negative electrode 22, designed for power take-off from the first battery cell 20.

The connecting element 30 is made of a mixture of graphite selected from the group comprising silver-graphite (a mixture of silver and graphite), copper-graphite (a mixture of copper and graphite), as well as silver-copper-graphite (a mixture of silver, copper and graphite) . The connecting element 30 of a mixture of graphite is in close electrical contact with the terminal 21 of the positive electrode of the first battery element 20.

At both ends of the second battery cell 40, there is an external positive electrode terminal 41 made of nickel-plated metal and a negative electrode terminal 42 for power take-off from the second battery cell 40. The negative electrode terminal 42 of the second battery cell 40 is in close electrical contact with the connecting element 30 from a mixture of graphite. A spring 50 and a support plate 51, pressing the connecting element 30 of a mixture of graphite to the first and second battery cells 20, 40 to ensure tight contact. In this way, the first and second battery cells 20, 40 are connected in series.

It is additionally possible to connect both the terminal 22 of the negative electrode of the first battery cell 20 and the terminal 41 of the positive electrode of the second battery cell 40 with the corresponding graphite terminal 401, 402, which acts as a terminal for taking power from them. To select power from them, a wire 403, 404 is installed inside each of the graphite leads 401, 402.

Figure 4 shows a parallel connection of two battery cells, in which to improve the electrical conductivity between the first and second battery cells, the electrical connection between the first and second battery cells is made by means of a first connecting element of a mixture of graphite and a second connecting element of a mixture of graphite.

The first battery cell 60 is a cylindrical battery cell, at both ends of which there is an external terminal 61 of a positive electrode made of nickel-plated metal and a terminal of a negative electrode 62 for power take-off from the first battery cell 60.

The first connecting element 70 is made of a mixture of graphite selected from the group comprising silver-graphite (a mixture of silver and graphite), copper-graphite (a mixture of copper and graphite), and silver-copper-graphite (a mixture of silver, copper and graphite ) A graphite mixture connector 70 is in close electrical contact with the positive electrode terminal 61 of the first battery cell 60.

The second battery cell 80 is a cylindrical battery cell, at both ends of which there is an external terminal 81 of the positive electrode made of nickel-plated metal and a terminal 82 of the negative electrode for power take-off from the first battery cell 80. The terminal 81 of the positive electrode of the second battery cell 80 is close electrical contact with the first connecting element 70 of a mixture of graphite.

The second connecting element 90 is made of a mixture of graphite selected from the group comprising silver-graphite (a mixture of silver and graphite), copper-graphite (a mixture of copper and graphite), and silver-copper-graphite (a mixture of silver, copper and graphite ) The second connecting element 90 from a mixture of graphite is connected to the terminal 62 of the negative electrode of the first battery element 60 and the terminal 82 of the negative electrode of the second battery element 80. Two sets of springs 50a, 50b and support plates 51a, 51b, pressing the first and second connecting elements 70, 90 from a mixture of graphite to the first and second battery cells 60, 80 to ensure tight contact. Thus, the parallel connection of the first and second battery cells 60, 80.

In addition, to take power inside both the first and second connecting element 70, 90 from a mixture of graphite, wire 405, 406 is installed.

The positional and structural relationships between the respective components of the preferred embodiment of the present invention have been disclosed above.

With regard to operation, the present invention mainly uses graphite connecting elements for direct series or parallel connection of battery cells without the use of traditional welding technologies, and the elimination of traditional welding technology can improve the electrical conductivity of the compounds and reduce production costs.

It should be noted that, as shown in FIGS. 5-1, the negative electrode terminal 22 and the positive electrode terminal 41 of the first and second battery cells 20, 40 are made of nickel-plated metal, and the surfaces of both positive and negative electrode terminals 41, 22 are contaminated with foreign substances 500 or 200 oxides, while the presence of foreign substances 500 or 200 oxides 200 increases the resistance of the compound during the discharge of the first and second battery cells 20, 40 and, thereby, reduces the energy efficiency of the discharge Mulatory elements. Figure 3 and figure 5-2, illustrating the principle of the connection with high conductivity between the battery cells, the connecting element 30 of a mixture of graphite is electrically connected to the terminals 41, 22 of the positive and negative electrodes of the first and second battery cells 20, 40; the connecting element 30 from a mixture of graphite in itself is resistant to oxidation, while the connecting element 30 from a mixture of graphite and the terminals 41, 22 of the positive and negative electrodes of the first and second battery cells 20, 40 dissolve in each other, i.e. particles 600 carbon of the connecting element 30 from a mixture of graphite replace foreign substances 500 or 200 oxides present on the terminals 41, 22 of the positive and negative electrodes made of nickel-plated metal, filling in this at the terminals 41, 22 of the positive and negative electrodes and forming a solid solution containing nickel and carbon, which leads to an improvement in the electrical conductivity of the connection between the connecting element 30 from a mixture of graphite, the first battery element 20 and the second battery element 40. In other words, after switching on claimed in the present invention of the battery, due to the claimed in the present invention, a connecting device for external connection of the battery cells, in the absence internal resistance created by oxides 200 or foreign substances 500, the electric current will flow smoothly between the first battery element 20, the connecting element 30 from a mixture of graphite and the second battery element 40, which not only reduces the resistance of the external connection between the first and second battery cells 20, 40 , but also contributes to the successful discharge of the first and second battery cells 20, 40.

As shown in FIG. 6, when a plurality of battery cells 301 are connected in series, parallel or series-parallel to a high-power battery 300 by a plurality of inventive graphite mix connectors 302 due to the dissolution of graphite mix connectors 302 in nickel-plated metal leads positive and negative electrodes that improve the electrical conductivity of the connection between the respective battery cells 301, lost power to the external resistance in the battery 300 is relatively smaller loss in the conventional secondary battery, wherein the battery cells are connected in nickel plates by spot welding. Obviously, the external resistance of the battery assembled using the connection technology disclosed in the present invention is relatively small, while the contact resistance of the battery cells 301 and the connecting elements 302 of the graphite mixture is reduced, thereby lowering the operating temperature. In other words, the battery assembly technology of the present invention reduces discharge losses and provides highly efficient, smooth transmission of power from the battery.

Although various embodiments of the present invention have been illustrated and disclosed above, it will be apparent to those skilled in the art that other variations are possible within the scope of the present invention.

Claims (5)

1. A connecting device for external serial connection of the battery cells, comprising: a first battery cell with external nickel-plated metal lead of the positive electrode and the output of the negative electrode, designed for power take-off from the first battery cell; at least one connecting graphite element made of a mixture of graphite selected from the group comprising a mixture of silver and graphite, a mixture of copper and graphite, a mixture of silver, copper and graphite, and connected to the terminal of the positive electrode of the first battery cell; as well as a second battery cell with an external nickel-metal terminal of the positive electrode and a terminal of the negative electrode intended for power take-off from the second battery cell, the terminal of the negative electrode of the second battery cell being connected to the connecting element from a graphite mixture in such a way as to make the first connection in series and the second battery cells. 2. The connecting device for the external serial connection of the battery cells according to claim 1, characterized in that it has a spring and a support plate, pressing the connecting element of a mixture of graphite to the first and second battery cells to ensure tight contact. 3. The connecting device for the external serial connection of the battery cells according to claim 1, characterized in that both the output of the negative electrode of the first battery cell and the output of the positive electrode of the second battery cell are connected to a graphite terminal acting as a terminal for taking power from them, moreover, to select power from them, a wire is installed inside each of the graphite terminals. 4. A connecting device for external parallel connection of the battery cells, comprising: a first battery cell with an external nickel-plated metal terminal of a positive electrode and a terminal of a negative electrode for power take-off from the first battery cell; at least one first connecting graphite element made of a mixture of graphite selected from the group comprising a mixture of silver and graphite, a mixture of copper and graphite, a mixture of silver, copper and graphite, and connected to the terminal of the positive electrode of the first battery cell; a second battery cell with an external nickel-plated metal terminal of the positive electrode and a terminal of the negative electrode for power take-off from the second battery cell, the terminal of the positive electrode of the second battery cell being connected to the first graphite connecting element; and at least one second connecting graphite element made of a mixture of graphite selected from the group comprising a mixture of silver and graphite, a mixture of copper and graphite, a mixture of silver, copper and graphite, and connected to the negative electrode terminal of the first battery cell and the output of the negative electrode of the second battery cell in such a way as to parallel the first and second battery cells. 5. The connecting device for external parallel connection of the battery cells according to claim 4, characterized in that it has two sets of springs and support plates, pressing the first and second connecting elements of a mixture of graphite to the first and second battery cells to ensure tight contact.

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