UA63563A - Current lead of an electrode of a lead-acid accumulator - Google Patents

Abstract

The proposed current lead of an electrode of a lead-acid accumulator constitutes a grid consisting of radial straps of varying cross-section and horizontal straps. The straps are disposed in a frame of varying width. At the lower section of the frame, a hole is provided. The radial straps meet at the frame hole. The cross-section dimension of each radial strap increases in the direction of the frame hole. The grid is reinforced by three radial straps and three horizontal straps of increased thickness, which are uniformly arranged over the grid area. Each horizontal strap has a wedge-shaped expansion at the crossing of the strap with the vertical side strip of the frame.

Description

Description of the invention

The invention relates to electrical engineering, namely to the production of lead-acid batteries 2 and can be used in their manufacture.

In batteries, the current collector performs two most important functions: a current collector and a supporting base for the active mass of the electrode. On the one hand, the material of the current drain does not directly participate in the charge-discharge processes that occur in the active mass and electrolyte, so a decrease in the mass of the current drain leads to an increase in the specific energy of the battery and battery. On the other hand, the current drain 70 should provide supply and discharge of electric current with minimal ohmic losses, as well as reliable maintenance of the active mass throughout the life of the battery under conditions of action of factors that gradually destroy the electrodes. Thus, from the very beginning, the current collector poses a technical contradiction between the requirement of high specific energy and the requirement of high reliability of battery electrodes. This is especially relevant for the positive electrodes of lead-acid batteries, because the electrical conductivity of the active mass of the 72 positive electrodes (lead dioxide) is significantly less than the electrical conductivity of the active mass of the negative ones (spongy lead), and also because the positive electrodes are more susceptible to destruction than the negative ones.

Recently, the requirements for current outlets have increased due to the use of maintenance-free sealed (with gas recombination) storage batteries, as well as an increase in the average operating temperatures at which batteries are operated in modern vehicles. The lead-antimony alloys used before and until now are characterized by good casting properties and allow casting current collectors of a rather complex design and small thickness. Such current drains make it possible to achieve high specific energy of the storage battery, however, they are unsuitable for use in maintenance-free sealed batteries, because the presence of antimony will lead to increased gas evolution and self-discharge, and positive current drains, moreover, are quickly destroyed by corrosion in conditions of elevated operating temperatures. 22 The lead-calcium alloys used in modern maintenance-free batteries make it possible to sharply reduce gas evolution and self-discharge, as well as to increase the corrosion resistance of positive current outlets, but they differ in reduced casting properties, which imposes significant restrictions on the design of current outlets and requires an increase in their thickness, which reduces the specific battery power. Thus, in modern maintenance-free sealed storage batteries, the technical contradiction between the requirement of high specific energy and the requirement of high reliability of the electrodes becomes even more acute. Gee)

A known current collector for the electrode of a lead-acid battery, which is a grid of vertical and horizontal veins of constant cross-section, located inside a frame of constant width. at

The cross-section of the conductors of the current drain has the shape of a square, rhombus or trapezoid. In the upper part of the frame, in the corner, there is an eye that serves to connect the electrodes to the electrode block; in the lower part of the frame there are legs with which the electrode rests on the bottom of the monobloc | Starter battery: Device, operation and repair / MA. Dasoyan, N.I. Kurzukov, O.S. Tyutryumov, V.M. Yagnyatinsky - M.: Transport, 1991. - P. 25-26).

The disadvantages of such a current collector are the irrational location of the wires, the size and shape of their cross-section, as well as the irrational location of the lug, which leads to increased ohmic losses and an increased voltage drop, especially during starter discharges. The largest voltage drop in such a design occurs in the upper part of the current outlet, near the lug. Increased ohmic losses in the current outlet lead to an increase in the inhomogeneity of the current distribution along the height of the electrode. And this, in turn, creates conditions for a local deep discharge in the upper part of the electrodes (especially with starter discharges), a decrease in the coefficient of use of the active mass (especially in the lower part of the electrodes). All this reduces the specific energy of the battery and shortens its durability. Another disadvantage of the specified current outlet is that it is subject to increased corrosion, especially in its upper part, where the distribution of electric current and potential is most uneven. Making the current collector from a lead-calcium alloy slightly reduces corrosion, but does not solve the problem caused by the irrational design of the current collector.

A current collector in which the vertical veins are replaced by inclined ones | see ibid.), although it is characterized by slightly lower ohmic losses, it is fundamentally no different from the above and has the same

Gee! 20 disadvantages.

A well-known current collector for the electrode of a lead-acid battery, which is a grid of c" vertical and horizontal veins of variable cross-section, located inside a frame of constant width.

The cross-section of the conductors of the current drain has the shape of a diamond or a circle and decreases in the direction from the frame to the center, where it is 0.98-0.49 of the thickness of the frame. In the upper part of the frame in the corner there is an eyelet, in the lower part of the frame 59 there are legs (Patent Mo2127930 Russia, IPC U NOTMaA/72, 10/12, 1999). In comparison with the above in analogues, the advantage of such a current outlet is a certain increase in the specific energy of the battery due to a decrease in lead consumption and an increase in the amount of active mass in the center of the electrode. However, in general, the specified current collector has the same disadvantages as for the analogues listed above. In addition, the proposed reduction of the cross-section of the wires in the center of the current outlet leads to additional ohmic losses and to an increase in the inhomogeneity of the current distribution along the height of the electrode with all the negative consequences that follow.

A known current collector for the electrode of a lead-acid battery, which is a grid of multi-directional wires of variable cross-section, located inside a frame of variable width. The cross-section of the conductors of the current drain has the shape of a square, diamond or circle and increases in the direction from the lower frame to the upper frame, and decreases in the direction of the side frames. In the upper part of the frame in the corner there is an eyelet, in the direction of which the upper frame expands; in the lower part of the frame there are legs | US Patent Mo5582936,

MPKU noimMa4/74, 1996). The advantage of such a current outlet is a more rational design, which allows you to reduce ohmic losses, especially during starter discharges, and also to increase the coefficient of use of the active mass due to the reduction of its amount in areas with minimum current. This leads to some

Increasing the specific energy of the battery. The disadvantages of such a current collector are the complex multidirectional pattern of veins and the irrational placement of the lug, which does not allow to fully solve the problem of reducing ohmic losses and obtaining a more uniform current distribution along the height of the electrode. In addition, the complex multi-directional pattern of current drain veins imposes significant limitations on the properties of the lead alloys used for casting. For example, the use of lead-calcium alloys, characterized by 70 reduced casting properties, leads to an increase in production defects. And this means that for modern maintenance-free sealed (with gas recombination) storage batteries, the use of the proposed drain will be ineffective and lead to an increase in material losses and claims from consumers.

A known current collector for the electrode of a lead-acid battery, which is a grid of 75 radial and horizontal wires of constant cross-section, located inside a frame of constant width.

The cross-section of the conductors of the current drain has the shape of a square, rhombus or trapezoid. In the upper part of the frame, at a distance of 30-35 mm from the corner, there is an eye, approximately to the side of which the radial veins are directed; in the lower part of the frame there are legs. The current collector is made of lead-calcium alloy with the addition of other metals

Patent Mo5298350 USA, IPC? NO1MA4/68, 1992 The advantage of such a current collector is the use of lead-calcium alloys, which allows the use of a current collector for maintenance-free sealed storage batteries. Another advantage of the proposed current outlet is the displacement of the eye at a distance of 30-35 mm from the corner of the frame and the presence of radial veins directed approximately to the side of the eye, which allows to reduce ohmic losses in the current outlet and increase the power of the battery during starter discharges. The disadvantage of the proposed current collector is the constant size of the cross-section of the wires, which limits the effect of reducing ohmic losses and does not allow to increase the coefficient of use of the active mass. In addition, the lead-calcium alloys used for the casting of the drain lead to characteristic restrictions on the minimum thickness of the cores and the frame, which limits the specific energy of the battery.

The closest technical solution, taken as a prototype, is a current collector for the electrode of a lead-acid battery, which is a grid of inclined veins of variable cross-section and horizontal veins located inside a frame of variable width. The cross-section of the wires of the current outlet has the shape of a square, rhombus or trapezoid, and the cross-section of the inclined wires increases in the direction from the frame to the ear by 1.5 times. In the upper part of the frame, at a distance of 35-38 mm from the corner, there is an eyelet that serves for IC o) connection of electrodes in the electrode block; in the lower part of the frame there are legs, which the electrode rests on the bottom of the monoblock. The width of the lower frame is reduced by 1.5 times, and the width of the vertical frame distant from the ear is reduced by 1.2-1.3 times compared to other frames |Yagnyatinsky V.M., Luzhyn V.K., Lvova V. AND. (Se)

Distribution of voltage drop and current density on the surface of the lead-acid battery electrode. /

Research in the field of electric accumulators. A collection of studies and works. L.: Znergoatomizdat, 1988. -

P.15-23.4). The advantage of the prototype current drain is the displacement of the lug at a distance of 35-38 mm from the corner of the frame and "the presence of inclined veins directed to the side of this corner of the frame, which allows to reduce ohmic losses in the current drain | to increase the capacity of the battery with starter discharges. The reduction of ohmic losses is facilitated by the alternating cross-section of inclined veins, which increases to the side of the ear, where the greatest voltage drop occurs. and In addition, the current collector-prototype allows you to reduce the consumption of material for its manufacture and increase the "" coefficient of use of the active mass of the electrode due to the reduction of the width of the lower frame and the vertical frame distant from the lug. (o) However, the current collector-prototype is not free from shortcomings, which still lead to high production rates of missing castings, low production productivity of current collectors, and also reduce the reliability of electrodes and their resistance to vibrations and shocks. casting of thin conductors often occurs 1 violation of directional crystallization along all frames and veins of the conductor, which generates shrinkage processes, b 50 additional defects and stresses in the structure. This also forces to prolong the exposure time in the casting mold after crystallization. The most vulnerable places are: the connection point of the lug with the upper frame, especially when the eyelet too far from the corner of the frame; places of connection of the legs with the lower frame; places of connection of veins with frames. This is especially relevant when using the prototype in sealed (with gas recombination) storage batteries. Lead-calcium alloys, which are characterized by low fluidity, significantly increase these disadvantages, which can even lead to non-shedding of the conductor wires in the central part of the grid.

In addition, the prototype has one common drawback with all the analogues mentioned above - the low strength of the current drain near the legs located in the lower part of the frame. Currently existing technologies for the production of current collectors and electrodes provide for the division of smeared electrodes into separate, single ones. At 60 This division is performed between paired legs. As a result of this operation, there are deformations of the lower frame, as well as burrs on the legs, which can damage the separator. A more advanced method of separating paired electrodes using disk knives, which allows you to completely eliminate legs and burrs, still does not exclude deformations of the lower frame and violation of the integrity of the active mass. This increases the production shortage of electrodes, reduces the durability and resistance of the electrode to vibrations and shocks. 65 The invention is based on the task of increasing the reliability and resistance of the electrode to vibrations and shocks while maintaining its high specific energy due to increasing the strength of the current collector, the task of reducing production defects in the manufacture of current collectors and electrodes, as well as the task of increasing the productivity of the manufacture of current collectors.

The problem is solved by the fact that in the current outlet for the lead-acid battery electrode,

Which is a grid of non-horizontal veins of variable cross-section and horizontal veins located inside a frame of variable width, in the upper part of the frame there is an eye, according to the invention, non-horizontal veins are radial, directed to the eye, the cross-section of the radial veins increases in the direction from the frame to the eye by 1.3-1.4 times, the net is strengthened by three thickened horizontal and three thickened radial veins, evenly distributed over the field of the net, in places 7/0 of the connection of the horizontal veins with the vertical frame close to the ear, the horizontal veins have a wedge-shaped expansion with a slope of 8- 127 and 4 mm long, the width of the upper frame in the direction of the lug increases by 1.5-1.6 times, the lug is located at a distance of 18-24 mm from the corner of the frame, the lower frame has two extensions 33-40 mm long, 3.5- 4.5 mm.

Let's reveal the essence of the declared technical solution. The presence of radial veins directed towards the ear, the /5 section of which increases in this direction by 1.3-1.4 times, allows you to reduce ohmic losses in the current outlet and increase the capacity of the battery during starter discharges. In contrast to the prototype, which uses inclined veins, radial veins are more effective for the purposes of reducing electrical resistance due to their more rational direction - the direction to the ear. This leads to some equalization of the current distribution over the height of the electrode. This is due to the fact that the optimal increase in the cross-section of the radial veins on the side of the Ear is 1.3-1.4, instead of 1.5 - in the prototype. Less than a 1.3-fold increase in cross-section is ineffective in reducing ohmic losses. A more than 1.4 times increase in the cross-section leads to excessive consumption of material and a decrease in the specific energy of the electrode.

The purpose of reducing ohmic losses and equalizing the distribution of current along the height of the electrode is the expansion of the upper frame in the direction of the eye by 1.5-1.6 times and the location of the eye at a distance of 18-24 mm from the corner of the frame. About The specified parameters are determined empirically. Less than 1.5 times the extension of the upper frame to the lug, as well as less than 18mm displacement of the lug from the corner, are not enough to reduce the ohmic losses in the current drain. More than 1.6 times the expansion of the upper frame to the lug leads to overspending of material. More than 24 mm displacement of the lug from the corner can lead to the formation of defects of shrinkage origin at the point of connection of the lug with the frame, especially when using lead-calcium alloys. For the same reason, the thickness of the eyelet is made 10-209o less than the thickness of the upper frame.

In the places where the horizontal veins connect with the vertical frame close to the ear, adjacent to x, directly to the spring and the pouring bowl, the horizontal veins have a wedge-shaped expansion with a slope of 8-127 and a length of 4 mm. This contributes to the maintenance of the directed crystallization front in these areas close to the spring and to the prevention of shrinkage processes. The lattice grid of the current outlet is strengthened by three thickened o

With horizontal and three thickened radial veins, evenly distributed over the mesh field. In addition to the function of increasing the strength of the current outlet, these thickened veins determine the thickness of the paste that is smeared during the manufacture of electrode plates and reduce the electrical resistance of the current outlet. The thickened cores also prevent spillage of other cores of the current drain in the central part of the grid when using lead-calcium alloys, as they serve as distributors of the liquid melt. For the same reason, as well as "to ensure directional crystallization to the uppermost horizontal thickened vein, short oblique veins in the amount of 6-Osht are connected with c. Directional crystallization of the melt makes it possible to shorten the technological cycle of the production of the current collector due to the reduction of the holding time in the casting mold after crystallization. ;" The cross-section of all the veins of the lattice mesh has a hexagonal shape, close to a regular hexagon with no sharp corners, unlike analogues and the prototype. This allows the veins to better retain the paste and active mass, as well as to more effectively resist corrosion that begins in the area of increased mechanical

Ge" of stresses and increased concentrations of defects near the sharp faces of the veins (the acute angles of the cross-section of the veins).

The lower frame near the legs has two extensions 33-40mm long and 3.5-4.5mm wide. Before the separation of paired electrodes, technological jumpers connecting paired electrodes are directly connected to these extensions. Technological jumpers have a length 2.8-3.2 times less than the length of the extensions, and a width of 9.8-1.2 times the width of the extensions. The presence of two extensions allows you to increase the strength of the lower frame and prevent

Me, a manufacturing defect in the separation of paired electrodes: deformation of the lower frame, violation of the integrity of the active 4) mass. The above-mentioned dimensions of the extensions of the lower frame are selected empirically in order to achieve sufficient strength with minimal material consumption. Smaller sizes of expansions reduce the effectiveness of strengthening the current drain, large sizes lead to excessive consumption of material. The above ratio of the dimensions of the expansions and the dimensions of the technological jumpers, as well as the presence of special thinned places on the technological jumpers - markings for separation, also contribute to the prevention of production defects during the separation of paired electrodes.

R The linear dimensions of the cells of the grid, that is, the dimensions of the empty areas of the cells are limited to 6-12 mm. With sizes larger than 12 mm, there is an increased loss of the paste, and then the loss of the active mass from the cells. This reduces the durability of the electrodes and resistance to vibrations and shocks. At sizes smaller than bmm boron, the cells may not be coated with the paste, which also reduces the durability and specific energy of the electrodes.

According to the information available to the authors, significant differences characterizing the essence of the invention are proposed, which are not known in this section of technology.

The proposed technical solution can be used at enterprises for the production of lead-acid batteries and storage batteries, primarily in the production of sealed (with 65 gas recombination) storage batteries.

In fig. 1 shows a general view of a single current outlet, as well as a cross-section of radial and horizontal veins. In fig. 2, C shows the connection of paired electrodes, as well as a section of the extensions of the lower frame and technological jumpers. In fig. 4, a close-up view shows the connection of horizontal veins with a vertical frame close to the ear, as well as wedge-shaped extensions of horizontal veins.

The current collector is a grid of radial cores 1 and horizontal cores 2 located inside the frame 3. The cross-section of the radial cores 1 increases by 1.3-1.4 times towards the lug 4. Upper frame

C expands 1.5-1.6 times in the direction of eyelet 4. Eyelet 4 is located at a distance of 18-24mm from the corner of the frame. The lower frame has two extensions 5. The length a 5 and width b" of the extensions 5 are equal: ag-33-40mm, ro-3.5-4.5mm. The length a and width B of the technological jumpers b are related to the length and 7/0 width of the extensions: аг/ай-2.8-3.2, р1/р2-0.8-1.2. The lattice mesh is strengthened by three thickened horizontal veins 7 and three thickened radial veins 8. Six short oblique veins 9 are connected to the uppermost horizontal thickened vein 7. The section A-A of the veins of the lattice mesh has a hexagonal shape, close to a regular hexagon with no sharp corners.

At the junction of horizontal veins 2 with the vertical frame 10 close to the ear, which is directly adjacent to the spring and the pouring bowl, the horizontal veins have a wedge-shaped extension 11 with a slope of se. - 8-12 and with a length of 4-bmm.

When pouring the current outlet, the lead melt flows from the spring to the vertical frame close to the eye, which is directly adjacent to the spring and the pouring bowl, as well as to the upper frame and the eye.

Wedge-shaped extensions 11 contribute to the support of the directional crystallization front in areas close to the spring and prevent shrinkage processes. At the same time, the melt tends to fill the three thickened horizontal veins 7 and the three thickened radial veins 8. The thickened veins prevent other drain veins from spilling in the central part of the grid, especially when using lead-calcium alloys, as they serve as liquid melt distributors. The improvement of pouring conditions, as well as the provision of directional crystallization along all veins of the current outlet, are facilitated by short inclined veins 9. Stabilization of the melt crystallization process in heat-stressed zones makes it possible to shorten the technological cycle of production of the current outlet by 8-1295 due to the reduction of the holding time in the foundry mold after crystallization.

The cast double current collector is to be smeared with electrode paste, while the thickened veins of 7 iv set the thickness of the smeared paste. The resulting paired electrode plate is then divided into two single plates by technological jumpers b with the help of disk knives. The cut is made in special thin places 12 on the jumpers 6. Extensions 5 of the lower frame increase the strength of the lower frame and prevent production defects during separation.

Electrode plates are then involved in battery assembly and electrochemical forming. Yes)

The batteries obtained in this way were subjected to laboratory tests. Tests of rechargeable batteries with electrode current drains, which are declared, showed compliance with the requirements of GOST 959 and

ЕМ50342 (ЕМбО095-1) in capacity, starter characteristics and durability. (Se)

Claims (1)

The formula of the invention "Current drain for the electrode of a lead-acid battery, which is a grid of non-horizontal veins of variable cross-section and horizontal veins located inside a frame of variable a width, an eye is made in the upper part of the frame, which is distinguished by the fact that the non-horizontal veins are made of » radial, directed towards the lug, the cross-section of the radial veins increases in the direction from the frame to the lug by 1.3-1.4 times, the mesh is reinforced with three thickened horizontal and three thickened radial veins, evenly distributed over the field of the mesh, in the places where the horizontal veins connect with vertical (o) frame close to the ear, horizontal veins have a wedge-shaped expansion with a slope of 8-12" and a length of 4-6 mm, the width of the upper frame in the direction of the ear increases by 1.5-1.6 times, the ear is located at a distance of 18- 24 mm from the corner of the frame, the lower frame has two extensions 33-40 mm long, 3.5-4.5 mm wide. 1 b 50 siu" R 60 b5