DE1932456C3 - Process for increasing the resistance of die castings made of alloys of the lead-calcium type to intergranular corrosion - Google Patents

Description

20th

The invention relates to increasing the resistance of die castings made of calcium-lead alloys, in particular for use in die-cast battery grids, to intergranular corrosion. t $

Battery grids made from lead-calcium alloys are known. So you have according to the German patent 7 44 900 an addition of 0.02 to 0.06% calcium for Bismuth-containing lead proposed for accumulator purposes. Battery grids generally have a structure that is either a gravity cast or a die cast. The calcium present in traces gives the battery grid the load-bearing capacity, while the lead gives the necessary electrochemical properties. The die casting method of making battery grids is highly preferred because of such grids can be produced faster and cheaper than gravity cast grids. However, so far die-cast battery grids are used only as negative battery grids and not as positive battery grids because of their Tendency to corrosion. Gravity cast grids have therefore been used for positive battery grids, which oppose Are more resistant to corrosion.

In general, the corrosion resistance depends on the formation of the grain boundaries. the narrow grain boundaries with fine grain structures, such as those found in die casting, should be one have higher corrosion resistance than broader grain boundaries of the coarse grain structures like them form during gravity casting. However, due to the rapid solidification of the die casting in the fine grain structure formed tension high tension tight grain boundaries that much faster corrode than the stress-free further grain boundaries in gravity casting. Accordingly gravity casting is used for positive battery grids to improve their resistance to corrosion.

The aim of the invention is to increase the resistance to intergranular corrosion of die castings made of alloys of the lead-calcium type.

According to French patent specification 12 94 005, lead alloys with good corrosion resistance are known which contain 0.5 to 6.5% antimony and 0.3 to 2.5% arsenic. The patent also reveals that it is expedient to achieve recrystallization to improve the electrochemical and mechanical properties by reheating the alloy to temperatures between 150 and 250 ^° C. and subsequent hardening at temperatures between 50 and 100 ^{° C.}

Proposals for a treatment of die castings made of alloys of the lead-calcium type with a relatively low calcium content 0.05-0.07% for the purpose of improving strength and corrosion resistance however, have not yet been made. The alloy treated according to the invention has inter alia: m the advantage of having only very small amounts of calcium as an alloy component apart from lead. The alloys of the French patent contain up to 6.5% antimony + up to 2.5% arsenic. According to the invention, hardening at 50 to 100.degree. C. is also dispensed with.

The method according to the invention is characterized in that the die castings made of a lead-calcium alloy are heat-treated for approximately 6 hours at 232 to 288 ° C and then cooled in air to a temperature of 15 to 26 ° C. The heat treatment is advantageously carried out at an oven temperature of 260 ^° C.

Although the battery grids treated according to the invention can have very different shapes all have a cell structure that is porous but still strong enough to support the battery plates. Other elements such as lithium or antimony can be added to the lead.

The grids have projections that are connected to other grids or plates by welding or the like can be or the grids can be attached to the pole bolt of the battery. For use in Lead-acid batteries, pure lead would be the best electrochemical one Show effect, but experience has shown that such grids for ordinary Lead-acid batteries are insufficiently strong. Therefore, the lead must be treated with a hardening agent such as calcium, antimony or lithium, can be mixed. The preferred method for making calcium-lead battery grids, takes place in the die casting process. Here, the Caldum lead alloy is pressed into a mold under pressure, wherein the battery grid is formed quickly. Die-cast battery grids have a fine Grain structure in contrast to the coarse grain structure as it is in the more slowly cooled gravity castings being found. However, these die-cast battery grids contain a large number of high tension Grain boundaries, as a result of which corrosion occurs very quickly.

Through the treatment according to the invention of a pre-cast calcium-lead alloy battery grid a battery grid is obtained which has an improved corrosion resistance.

The heat treatment and cooling of the battery grid creates an edge layer on the grid formed having a typical thickness of 0.015 to 0.03 mm has. This layer can be referred to as a single crystal layer because it has very few or no grain boundaries on which corrosion can take place. In this respect, the outer layer contains the battery grid essentially a single crystal, which has a high corrosion resistance because of the absence of grain boundaries at which corrosion can attack. In the drawing, the figure represents a photomicrograph a lead-calcium alloy treated according to the invention, the edge of which is essentially is single crystal. In addition, as a result of the increased treatment temperature,

space the stress along the remaining grain boundaries on the battery grid is released.

As a result of this relaxation through the heat treatment at temperatures between 232 and 288 ° C the loss of hardness is only about 10%, while at a heat treatment at temperatures of 149 to 204 ° C, the loss of hardness is about 30 to 40%.

Tests have also shown that the breaking strength of the battery grid is not noticeable by a Heat treatment at temperatures in the range from 232 to 288 ° C is affected.

To determine the corrosion resistance of die-cast battery grids made of lead-calcium alloys that were heat-treated according to the invention and comparatively not heat-treated, experiments were carried out at room temperature with different current densities and with different calcium-lead alloys. It was at approximately 7 billions / cm ² and

28 milliamps / cm ^{2 worked for} 4 weeks in a sulfuric acid electrolyte with a specific gravity of 1.115. The heat-treated lead alloys with a calcium content of 0.07 percent by weight showed the best corrosion resistance at the higher current density. Also, at a current density of 7 milliamperes / cm ^2, the corrosion resistance of the treated at 26O ⁰ C lead alloy was substantially greater than the non-treated alloy. Tests were also carried out with heat-treated and non-heat-treated gravity castings made from lead-calcium alloys. Photomicrographs of coarse grain lead alloy samples showed after a corrosion at 7 milliamps / cm ^3, that even with large grains of the corrosion resistance of the treated at 26O ⁰ C Preßgußmuster was increased grain boundary layer because of the formed in the outer layer Ei ·.

1 sheet of drawings

Claims (3)

Patent claims: 1. Process for increasing the resistance of die castings made of alloys of the lead-calcium type against intergranular corrosion, characterized in that the die castings Heat treated for approximately six hours at 232 to 288 ° C and then in air to a temperature be cooled from 15 to 26 ° C. 2. The method according to claim 1, characterized in that that die-castings made from a lead-calcium alloy treated with 0.05 to 0.07% calcium. 3. The method according to claim 1, characterized in that the heat treatment is carried out at an oven temperature of 260 ⁰ C.