WO2012141616A1

WO2012141616A1 - Lead-acid rechargeable battery

Info

Publication number: WO2012141616A1
Application number: PCT/RU2012/000274
Authority: WO
Inventors: Андрей Анатольевич УСКОВ; Игорь Леонидович КОПТЕЛОВ; Денис Вячеславович ПЕСТОВ
Original assignee: Uskov Andrej Anatolievich; Koptelov Igor Leonidovich; Pestov Denis Vyacheslavovich
Priority date: 2011-04-12
Filing date: 2012-04-11
Publication date: 2012-10-18

Abstract

This utility model relates to the electrical engineering industry and in particular to steady-state lead-acid rechargeable batteries. In a lead-acid rechargeable battery comprising a housing (1), in which positive electrode plates (2) and negative electrode plates (3) are arranged, separated from one another by a separator (4), wherein the negative electrode plates (3) are supported on support prisms (6) formed on the base of the housing (1), glass mats (7) are attached to the separators (4) on the side of the positive electrode plates (2), and the positive electrode plates (2) are mounted in the housing (1) with a gap (8) relative to the support prisms (6), wherein the lower edges of the positive electrode plates (2) are rectilinear. The time before shorting between the positive and negative electrode plates is increased and, correspondingly, the service life of the rechargeable battery is increased.

Description

Lead acid battery

Technical field The utility model relates to the electrical industry, in particular to stationary lead-acid batteries.

State of the art

Known lead-acid battery containing blocks of negative and positive electrode plates separated by a separator, equipped with tongues connected to the output of the Born, placed in a tank and filled with electrolyte; on the separator there is a plate equipped with perforations, RU 70052 Ш.

One of the main causes of short circuits between the positive and negative electrodes is the formation of bridges between them, which appear as a result of the gradual growth of dendrites consisting of lead oxides and sulfates on the positive electrodes. The presence of short circuits between the electrodes dramatically affects performance battery, the battery current is not spent on useful purposes, but on its heating. When storing a battery having short circuits between the electrodes, its intense self-discharge occurs.

Also known is a lead-acid battery, including a housing, in which positive and negative electrode plates are separated by a separator, while both positive and negative electrode plates are supported on support prisms made at the bottom of the housing, M.A. Dasoyan et al. “Production of electric batteries”, M, 1977, p. 70, 71 (copy attached).

This technical solution was made as a prototype of this utility model.

The lower edges of the positive and negative electrode plates are stepped with the formation on them of the supporting protrusions in contact with the supporting prisms. This design leads to the fact that the bridge from the positive electrode plate to the negative grows along the shortest path, enveloping the bottom edge of the separator. At a build-up rate of 0, 1 mm per year on the positive electrode of dendrites consisting of lead oxides and sulfates of lead, a short circuit between the electrodes will occur in 7-8 years, which determines the relatively short battery life.

Also, due to the formation of lead oxides on the surface of the positive electrodes during battery operation, there is an increase in the overall dimensions of the positive electrodes. Since the positive electrodes in their lower part is supported by support prisms, and in the upper part it is rigidly welded to the pole terminal fixed in the battery cover; destruction of the battery case may occur with an increase in the overall dimensions of the positive electrodes.

Utility Model Disclosure

The objective of this utility model is to increase the time until a short circuit is formed between the positive and negative electrode plates and, accordingly, increase the battery life.

According to a utility model, in a lead-acid battery including a housing in which the positive and negative electrode plates are separated by a separator, while the negative electrode plates are supported on support prisms made at the bottom of the housing, glass mat is attached to the separators on the side of the positive electrode plates, positive electrode plates are installed in the housing with a gap relative to the reference prisms, while the lower edges of the positive electrode plates are made rectilinear.

The applicant has not identified any technical solutions identical to the claimed one, which allows us to conclude that the utility model meets the criterion of “Novelty” (“N”). Brief Description of the Drawings

In the future, the utility model is illustrated by a detailed description of examples of its implementation with reference to the drawings, which show:

in FIG. 1 - longitudinal section of the battery;

in FIG. 2 - section A - A in figure 1;

in FIG. 3 - fragment B in figure 2 on an enlarged scale; in FIG. 4 - the same as in FIG. 3, shows the growth of dendrites on

positive electrode plate.

The best option for implementing a utility model

The lead-acid battery includes a housing 1, made in the form of a tank of shockproof acid-resistant transparent plastic. In the housing 1 placed positive 2 and negative 3 electrode plates. The electrode plates 2, 3 are made of an alloy containing Pb, Sb, As, Sn, Se. Plates 2, 3 are lattice down conductors filled with active mass and separated by separators 4 made of durable insulation acrylic plastic AGN from AMER-SIL (Luxembourg). Negative electrode plates have protrusions 5 on the lower edges, with which they are supported on supporting prisms 6 made on the bottom of the housing 1. Positive electrode plates 2 are installed in the housing 1 with a gap 8 relative to the supporting prisms 6, while the lower edges of the positive electrode plates 2 are made rectilinear, without supporting protrusions.

When assembling the battery, the electrode block is additionally fixed relative to the housing 1 using plastic wedges (not shown in the drawing). Case 1 is filled with electrolyte - an aqueous solution of H ₂ S0 ₄ with a density of 1, 25. Glass separators 7 are attached to the separators 4 from the side of the positive electrode plates with a chemically resistant glue 7. In this example, chemically resistant glass mat “C-glass” company AMER-SIL (Luxembourg) was used.

At the initial stage of battery operation, the positive electrode plates 2 are maintained in the required position by pressing them with a glass mat due to compression of the electrode block by fixing wedges. As the battery operates, additional fixation due to wedges weakens due to a number of physical and chemical factors. However, on the surface and lower edge of the positive electrode plates 2 there is an increase in lead oxides and sulfates (dendrites 9), which from the surfaces in contact with the glass mat 7 grow inside the glass mat 7. As a result, the system monopolizes: positive electrolyte plate - glass mat - separators, which provides a strong connection of the positive electrode plates with glass mat and their maintenance in the required position without bearing on the elements of the housing 1 (reference prisms 6). Due to this, dendrites 9, growing on the lower edge of the positive electrode plates 2, have enough places (gap 8) for growth; as a result, the formation of a bridge and a short circuit between the positive electrode plates 2 and negative electrode plates 3 within the estimated battery life (15 - 20 years) practically does not occur. The destruction of the battery case is also prevented. The size of the gap 8 is 8 - 12 mm and is determined in each case by the growth rate of dendrites 9 and a given battery life. Industrial applicability

Prototypes of the product were manufactured and successfully tested by Novgorod Battery Company LLC, Veliky Novgorod. This allows, according to the applicant, to conclude that the claimed technical solution meets the criterion of "Industrial Applicability" ("IA").

Claims

Utility Model Formula

A lead-acid battery, comprising a housing in which the positive and negative electrode plates are separated by a separator, while the negative electrode plates are supported on support prisms made at the bottom of the housing, characterized in that glass mat is attached to the separators on the side of the positive electrode plates, positive electrode plates are installed in the housing with a gap relative to the reference prisms, while the lower edges of the positive electrode plates are made rectilinear.