BG112579A - Lead-acid battery terminal connector - Google Patents

Abstract

The invention will find application in the production of lead-acid rechargeable cells and batteries. It is achieved significantly higher electrical conductivity and it is improved the thermal output of the pole terminals, as well as it is provided reliable electrical contact. It is reduced the consumption of metallic lead and is reduced the weight of the connector. It includes an elongated body (1) with an upper part (2) fixing itself in the opening (31) of the pole terminal (3) and with a lower part (4) with an extended end section (5) to contact positive or negative electrodes of the active lead-acid cell blocks or batteries. The lower part (4) of the elongated body (1) is tight. At its upper part (2) is formed a blind opening (6), filled tightly with low-temperature expanded graphite (7), which is pre-pressed into the blind opening (6) or represents a sintered rod with a shape agreed to the shape of the blind opening (6 ). 9 claims, 2 figures

Description

CONNECTOR FOR LEAD-ACID BATTERY POLES

FIELD OF ENGINEERING

The invention relates to a lead-acid battery pole connector that will find application in the production of lead-acid battery cells and batteries.

PRIOR ART

In the designs of all types of manufactured lead-acid starter, traction and stationary battery cells and batteries, connectors are used that connect the active blocks of the cells and batteries to their positive and negative pole terminals.

One known from application, a connector for poles of lead-acid batteries is a dense oblong body made of lead or lead alloy, which has a cylindrical or prismatic shape. The solid oblong body has a top that snaps into a terminal hole that is mounted on a lead-acid cell or battery cover. At the end of the lower part of the solid oblong body, there is a projecting board or projecting portion of suitable configuration, according to the need to connect to the terminals of the positive or negative electrodes forming an electrode block of the active blocks of the lead cells. The electrical conductivity of the connector is determined by the size and type of material from which the dense oblong body is made. A disadvantage of the solution known from practice is that it does not allow the conduction of high currents and the security of the connections.

It is known from US9,673,441 B2 and another technical solution of a connector for the poles of lead-acid batteries, which is also a solid oblong body made of lead or lead alloy, which has a cylindrical or prismatic shape. The solid oblong body has a top that snaps into a terminal hole that is mounted on a lead-acid cell or battery cover. The upper part of this connector has a smaller diameter than that of the opening of the pole terminal, and in the working position in the resulting clearance between the connector and the pole terminal an additional mechanical and electrical connection is provided. At the end of the lower part of the solid oblong body there is a protruding section for connecting to the terminals of the positive or negative electrodes of the battery cells. The electrical conductivity of the connector is determined by the size and type of material from which the oblong body is made and the mechanical and electrical connection between the connector and the terminal.

The disadvantages of this known solution are related to the fact that it does not allow the conduction of high currents and the security of the connections when cycling high currents.

TECHNICAL ESSENCE OF THE INVENTION

The purpose of the present invention is to create a connector for the poles of lead-acid batteries, which has increased electrical conductivity, for making an electrical connection of the electrode blocks with the pole terminals of the lead cells and batteries.

To achieve this goal, a connector for lead-acid battery poles has been created, which includes an oblong body with an upper part that can be fixed in a pole terminal hole and a lower part with a projecting end section. According to the invention, the lower part of the oblong body is solid, and in its upper part a blind hole is formed, filled densely with low-temperature expanded graphite.

In a preferred embodiment, the blind opening has a cross-section with an area of (30 to 70)% of the cross-section of the elongate body.

Preferably, the blind hole has a length of 1/2 to 2/3 of the total length of the oblong body.

The oblong body is intended to be made of a material with low electrical resistance and high electrical conductivity from the group of lead, lead alloy, carbon, metal or composite materials.

Alternatively, the elongate body has a cylindrical shape.

According to another embodiment, the oblong body has a prismatic shape.

It is suitable for the blind hole to have a cross-section with a shape corresponding to the shape of the oblong body.

According to a further variant, the low-temperature expanded graphite is pre-pressed into the blind hole.

A variant is also possible in which the low-temperature expanded graphite is sintered into a rod with a shape corresponding to the shape of the blind hole.

The advantages of the invention consist in the achieved significantly higher electrical conductivity of the connector, which also determines the electrical conductivity of the overall detail of the construction of the lead-acid cells and batteries. The increase in electrical conductivity also improves the heat dissipation of the pole terminals, which lowers the temperature of the contact surfaces when strong currents flow through them. Thanks to these two positive effects, a reliable electrical contact is ensured, both between the active blocks of the lead cells and batteries with their pole outputs (terminals), and with the current-carrying connections between the individual cells and batteries of the system. Reduced metal lead consumption and reduced connector weight. Another achieved advantage of the connector according to the invention is that it can be applied both to battery terminals up through its cover and to laterally located terminals. The achieved technical characteristics of the connector make it suitable for use in modern battery stations of renewable energy sources.

EXPLANATION OF THE ATTACHED FIGURES fig. 1 - represents a section through a connector according to the invention;

fig. 2 - section through the connector, according to the invention, in one embodiment;

EXAMPLES OF IMPLEMENTATION OF THE INVENTION

The connector for the poles of lead-acid batteries includes an oblong body 1 with an upper part 2, fixed in an opening 31 of a pole terminal 3, and with a lower part 4 with a projecting end section 5. According to the invention, the lower part 4 of the oblong body 1 is solid, and in its upper part 2 a blind hole 6 is formed, densely filled with low-temperature expanded graphite 7. According to a preferred embodiment, the blind hole 6 has a cross-section representing (30 to 70)% of the cross-section of the oblong body 1. Preferably the blind opening 6 has a length of 1/2 to 2/3 of the total length of the oblong body.

The elongated body 1 is made of a material with low electrical resistance and high electrical conductivity from the group of lead, lead alloy, carbon, metal or composite materials. Lead or lead alloy would be most commonly used, but all other materials listed here are suitable and are chosen depending on the practice and specific designs of each individual manufacturer.

The oblong body 1 of the connector may have a different shape depending on the choice of each particular manufacturer, including the cylindrical shape shown in the present exemplary embodiment. Also suitable is prismatic, for example with a square or other cross-section, which does not limit the application of the invention to any other shape required for application in a particular lead-acid battery. The issued end section 5 the lower part 4 of the oblong body 1 can be a board, a thumb, as shown in the figures, or another type, its shape being determined by each manufacturer in view of the specific types of connections applied in his practice between it and the electrode blocks elements of the cell or battery and does not affect the application of the invention.

The blind hole 6 generally has a cross-section with a shape corresponding to the shape of the oblong body 1. This does not limit the application of the invention with respect to other shapes of the cross-section of the blind hole, including combinations of a blind hole with a circular cross-section, shaped at the top of a prismatic oblong body or vice versa.

In one embodiment of the invention, the low-temperature expanded graphite 7 is pre-pressed into the blind opening 6. This allows quick assembly of the entire lead-acid cell or battery.

According to another embodiment of the invention, the low-temperature expanded graphite 7 is a sintered rod with a shape corresponding to the shape of the blind hole 6. It can be made at a separate production position, and the choice of option is related to the specific production decision.

Low-temperature expanded graphite 7 is a carbon material that has high electrical conductivity with values of 1x10' ⁸ p(Ω/m). These values are higher by more than one order of magnitude than the conductivity of a solid lead or lead alloy wire, which has values of 2.2x1 O' ⁷ p-(Q/m) at the same diameter. Thus, according to the invention, a higher by more than 20% electrical conductivity of the connector has been achieved. In addition, due to the presence of the blind hole 6 in the prismatic body 1 and its filling with low-temperature expanded graphite 7, the consumption of metal lead is reduced and the weight of the connector is reduced by (15 - 30)% or more depending on its specific dimensions.

Example 1

In fig. 1 shows a connector in the upper part 2 of the elongated body 1 on which a blind hole 6 is formed. In this case, the shape of the elongated body 1 is cylindrical. In the blind hole 6, powdered carbon material of the type of low-temperature expanded graphite 7 is tightly pressed. To the protruding end section 5 of the lower solid part 4 of the connector, the positive or negative electrodes of the active blocks of the lead-acid cells or batteries are welded. When mounting the cover to the case of the lead-acid cell or battery, the upper part 2 of the oblong body 1 of the connector is inserted into the hole 31 of the pole terminal 3 previously placed in the cover. The formation of the complete pole terminal is done after pouring, as adopted in the practice, with lead or lead alloy of the terminal 3 together with the upper part 2 of the oblong body 1 of the connector placed in its opening.

Example 2

In fig. 2 shows a connector, in the upper part 2 of the oblong body 1, on which a blind hole 6 is formed. In this case, the shape of the oblong body 1 is cylindrical, as in example 1. In the blind hole 6, a rod made of pre-pressed or sintered carbon material of the type of low-temperature expanded graphite 7. The positive or negative electrodes of the active blocks of the lead-acid cells or batteries are welded to the protruding end section 5 of the lower solid part 4 of the connector. When mounting the cover to the case of the lead-acid cell or battery, the upper part 2 of the oblong body 1 of the connector is inserted into the hole 31 of the pole terminal 3 previously placed in the cover. The details thus formed, which combine the connector and pole terminal 3, after lead or lead alloy casting, form their overall pole terminals in lead cell and battery structures.

Claims (9)

1. A connector for poles of lead-acid batteries, comprising an oblong body with an upper part fixed in a pole terminal opening and a lower part with a projecting end section, characterized in that the lower part (4) of the oblong body ( 1) is dense, and in its upper part (2) a blind hole (6) is formed, filled tightly with low-temperature expanded graphite (7). 2. A connector according to claim 1, characterized in that the blind hole (6) has a cross-section (30 to 70)% of the cross-section of the oblong body (1). 3. Connector according to claim 1 or 2, characterized in that the blind hole (6) has a length of 1/2 to 2/3 of the total length of the oblong body. 4. A connector according to any one of claims 1 to 3, characterized in that the oblong body (1) is made of a material with low electrical resistance and high electrical conductivity from the group of lead, lead alloy, carbon, metal or composite materials. 5. A connector according to any one of claims 1 to 4, characterized in that the oblong body (1) has a cylindrical shape. 6. A connector according to any one of claims 1 to 4, characterized in that the oblong body (1) has a prismatic shape. 7. A connector according to any one of claims 1 to 6, characterized in that the blind hole (6) has a cross-section with a shape corresponding to the shape of the oblong body (1). 8. A connector according to any one of claims 1 to 7, characterized in that the low-temperature expanded graphite (7) is pre-pressed into the blind hole (6). 9. A connector according to any one of claims 1 to 7, characterized in that the low-temperature expanded graphite (7) is a sintered rod with a shape corresponding to the shape of the blind hole (6).