DE1295307B - Process for the electrophoretic deposition of a metal coating on metals - Google Patents

Description

1 2

The invention relates to a method for which can not be deposited from aqueous baths,

electrophoretic deposition of a metal over- When applying it to shaped objects

in addition to metals from a coating metal in is a particular advantage that one

finely divided form containing suspension. receives even precipitation. The through-

In such a known method, the conditions to be observed are the 5 conduct of the method,

Metal coating of a the coating material in such as particle size of the coating metal, type of

finely divided form containing organic liquid organic liquid, type of ionizable

Liquid deposited and then to the compounds that are to be added to the suspension

serung the adhesion of a heat treatment to achieve under-charges on metallic particles and pulled. ίο the formation of gelatinous metal hydroxide

It is also already known to allow the substrate to be treated so that a coagula-

by electrophoretic means with metal over- the suspension at the electrodes in the elec-

drawn metals under pressure, e.g. B. when pulling trophoresis cell can occur, potential difference in

of wire. of the cell, current density at the one to be coated

In the known method, colloidal surface, heat treatment for solidification and dispersions or sols are used. An application of bonding, etc., changes according to the nature of particles with a diameter of, for example, the coating metal, whereby the appropriate evidence 10 μ is not taken into account, since the conditions for the respective coating metal larger particles usually sediment very quickly. can easily be determined by a preliminary test,
animals, unless the suspension is stirred, so it is preferable to use a polar organic liquid in electrophoresis, because of the colloidal dimensions of the particles. A suitable coagulation of these on the electrode is already nete organic liquid for this purpose is, for example, a denatured ethyl alcohol if the coating has sufficient adhesion on the electrode. This is properly guaranteed, so that difficulties here, for example particle size for the coating material, are in the range between 1 and 10 microns when drawing wire through a die. Which are not to be expected in the bathroom. The ionizable compound contained is a soluble one

Also, the known method is not suitable for salt of the coating material, for example aluminum

for covering larger objects. minium nitrate when aluminum is deposited

The method according to the invention is suitable.

on the other hand, for larger particles to be deposited 30 Pressure is applied to objects and for items of great length, such as tapes in the form of a metal plate or a metal or Rails. Strip usually by rolling. Suitable loading

According to the invention, this is achieved in that actions of the coated surface are, for example, in the case of particles with a diameter of 1 to 10 μ:
containing suspension with a content of soluble 35

feverish salt of the coating _{metal uses the a) sintering of the} metal coating by heating

Coating in a manner known per se under pressure, if necessary in a reducing

is compressed and then heated. Atmosphere followed by cold rolling

Preferably, one or-pressing and a second sintering are carried out before the application of pressure,
further heat treatment of the coated top 40

area made. _b ) Cold rolling or pressing followed by

It is advantageous before electrophoretic sintering
bring the coating to the metallic surface
applied an indium layer.

It is expedient to coat steel with 45. The method according to the invention is intended in the following

Aluminum a suspension of aluminum in the denade with reference to the application of an aluminum

tuierten ethyl alcohol with a tannic acid content of miniumüberzuges on a steel sheet explained in more detail

used up to 1 g / l. will.

The measure according to the invention makes the steel plate with a surface roughness Significant advantage achieved in that for the first time a 50 under 0.25 mm is first achieved by cathodic bepractical economically feasible process action in hot alkali solution and then degreased for the continuous production of steel strips and lightly wired in cold 19 weight percent hydrochloric acid created with an aluminum coating, pickles if there is oxide residue on the surface that are located on a product with an aluminum coating. Acids with more than one charge carry extreme strong adhesion leads. The adhesion of the over the anions, for example sulfur or phosphorus is such that the coated material without acid should not be used for pickling the sheet metal or peeling of the coating are deformed, otherwise there is a risk that the what was previously unthinkable. positive charge on the aluminum particles in the

The method according to the invention can be destroyed by the electrophoresis bath when this is through Coating a variety of metallic surfaces 60 the acid is poisoned. After a good one surfaces, both in terms of the nature of the washing and drying, the sheet metal is in the elecdete Metal as well as their form and shape spent a trophoresis bath. The sheet becomes cathodic turn around. It is particularly suitable for plating, while an aluminum or aluminum anode of iron, iron alloys and copper surfaces steel sheet of the same size is used. the and of metals, which in the form of strips, plates, 65 electrodes are parallel to each other and in the wire, Rods or other entangled stands from 37 to 50 mm. Should both Forms are available. The sides of the sheet steel coated with aluminum are particularly suitable Process for the production of aluminum coatings, then two anodes, one for each

on each side of the steel sheet. The bath consists of a suspension of aluminum powder in denatured ethyl alcohol with small amounts of aluminum salts and tannic acid. Satisfactory Precipitations are obtained with aluminum powder, which is melted by atomization Aluminum is produced. It contains a small amount of aluminum oxide. A purposeful concentration of the powder in the bath is 13 percent by weight, although there are satisfactory precipitates is also obtained over a much wider range of concentrations, with the yield im is substantially approximately proportional to the concentration. If the concentration of the powder is too high, then there is a risk of a short circuit between the electrodes.

To maintain an even concentration of the powder in the bath and an even one To ensure the strength of precipitation on the sheet, it is necessary to stir the bath. The stirring can be done in different ways: with arranged at different heights on vertical shafts Impellers, by circulating with a pump or by blowing air or oxygen through them through a perforated plate covering the bottom of the cell. If the bath is stirred too vigorously, then there is a risk that the electrophoretic precipitate will dissolve again. The bathroom won't used, the powder can be allowed to settle on the bottom of the cell.

With regard to the ionizable compound, good results are obtained with aluminum chloride or aluminum nitrate. In the case of aluminum chloride, it is unimportant whether one is free of water of crystallization or one that contains water Compounds are used provided that there is an appropriate setting in the amounts added undertakes. The concentration used is low and on the order of millimoles per liter. The addition of 10 percent by weight of water to the bath lowers the yield of the electrophoretic Precipitation by only about 5%. If the ionizable compound is missing in the bathroom, then you can do not achieve any noticeable electrophoretic aluminum precipitate. The yield increases rapidly up and falls to a maximum at an aluminum salt concentration of about 0.4 millimoles per liter with further addition slowly to a value that no longer changes significantly with the concentration changes. In the region of the initial rapid increase in the yield with the concentration the risk of short circuits between the electrodes of the cells. Receives the best rainfall one in the area between the maximum yield and the point where the yield is only little is influenced by the concentration of the aluminum salt.

It has been found that the addition of tannic acid up to 1 g / l increases the amount of aluminum precipitate for a given aluminum salt concentration and current density. With higher tannic acid concentrations, aluminum deposits do not always occur. The following table shows the range for the aluminum salt and tannic acid concentration to achieve satisfactory precipitates at a current density of 2.2 mA / cm ² . The concentration of the aluminum powder was basically 13 percent by weight and the bath was operated at room temperature.

aluminum ( 0 Herbic acid concentration (g / 1 0.25 0.83 ) 1.7 concentration C. C. C. C. (Millimoles C. 0.12 C. C. C. per liter) C. C. A. C. C. 5
0 A. C. A. B. C. 0.2 A. B. A. A. C. 0.5 B. A. A. A. C. 0.7 C. A. A. A. C. ¹⁰ 0.9 C. A. B. A. C. 1.1 C. A. C. A. C. 1.3 C. C. C. C. C. 1.6 - C. - C. C. 1.8 C. ¹ S 2.2 - 2.7

A = satisfactory rainfall,
B = doubtful precipitation,
^ao C = very little precipitation.

The conductivity of the bath increases when the concentration of ionizable compound is increased. Thus, the voltage drop in the bath for a given current density depends on the concentration of the ionizable compound present. An average value is 100 volts for 37 mm electrode spacing at a current density of about 2.2 mA / cm ² .

The conductivity decreases when the precipitate forms.

The thickness of the deposited aluminum powder is determined by the product of current and time regulated. When the desired amount of aluminum is deposited on the steel plate, it will carefully removed from the bath, dried with hot air, and then between rollers in a rolling mill passed through, which is set so that it is the thickness of the steel output body between 3 and 10% reduced. As a result of this process step, the aluminum powder is solidified and has a surface quality that depends on the nature of the rollers. However, it is liable not firmly on the steel body and can be pulled off in strips with your finger.

Adhesion is obtained by heating the laminate, preferably in an inert one Atmosphere and at a temperature below the melting point of the coating material mutual diffusion at the aluminum-steel interface and possibly alloying initiate. One can choose from the most varied combinations of treatment time and operate at treatment temperature, for example 2 hours at 250 ° C, 30 minutes at 500 ° C or less seconds at 650 and 750 ° C. The last-mentioned method has the particular advantage of that, if the starting body is made of low-carbon steel, that is responsible for increasing the adhesion Heat treatment required between the coating and the initial body, an additional tempering of the initial body causes.

A suitable plant for the continuous

Coating of low-carbon steel strips with aluminum is shown in the drawing.

The cleaned and heated belt 15 runs over a guide roller 1 after washing and drying

and then under a rubber-coated fountain roller 2 attached to one end of a long Shallow container 3 is arranged, which contains an electrophoresis bath of a composition, such as it has been explained above, for example. The tape 15 passes over the edge at the top of the container the same from. Two aluminum rails 4, 5 run parallel to the diagonal part of the belt and at the same distance from him and form the anodes. The stream is the belt over the roller 1 and a second roller 7 is supplied. After leaving the electrophoresis bath, the belt runs through a heated drying chamber 6 to evaporate the alcohol from the coating.

When the alcohol-laden air from the drying chamber is passed through pipes containing cooling water circulates, then the alcohol can be condensed and recovered. The dry one, with aluminum powder Coated strip arrives at a rolling mill 9, which consists of rollers 7 and 8. There the powder is solidified on the belt and, since the rollers are heated, partly on the steel belt bound. The full bond takes place in a heat treatment part 10, where the temperature of the with aluminum-coated tape first to 350 ° C by passing it through a lead bath 11 and then increased to 700 ° C within 0.3 to 1.0 seconds when the tape passes through a Tower 12 is running, which appropriately contains a reducing atmosphere. The tape reaches a Temperature of about 700 ° C before it enters a second lead bath 13, which is also kept at 350 ° C will. After this treatment, the aluminum-coated tape is wound up or in plates cut and stacked and held at temperatures between 250 and 450 ° C for 30 to 15 minutes. In the end product, the aluminum coating is firmly bonded to the steel, which is completely tempered is.

The method is e.g. B. also for applying coatings to wires, ropes or woven objects applicable, the main difference in this case from the described embodiment consists in that the pressure rollers by suitable pressure-applying devices replaced. In addition, one can in a similar manner by suitable adjustment of the electrophoresis Conditions also replace other coating metals besides aluminum.

Claims (4)

Patent claims: 1. Process for the electrophoretic deposition of a metal coating on metals a suspension containing the coating metal in finely divided form, characterized in that that a suspension containing particles with a diameter of 1 to 10 μ a soluble salt content of the coating metal is used, the coating is known per se Way is compressed under pressure and then heated. 2. The method according to claim 1, characterized in that a before pressure application further heat treatment of the coated surface is carried out. 3. The method according to claim 1 or 2, characterized in that before the electrophoretic Applying the coating to the metallic surface, an indium layer is applied. 4. The method according to claim 1 to 3, characterized in that for coating steel with aluminum, a suspension of aluminum in denatured ethyl alcohol with a tannic acid content of up to 1 g / l is used. 1 sheet of drawings