How the E6 Alkaline Etching Bath Works

Alkaline pickling bath E6

For decorative matting of the surface during anodizing of aluminum products in Europe, alkaline etching is mainly used.. These special pickling baths are used in accordance with DIN 17611 for surface treatment "E6". Such pickling baths are usually called so: "baths E6". These bathtubs have a very attractive decorative brushed aluminum surface when properly maintained..

These long term pickling baths are very durable, if properly maintained. Correct maintenance of these baths is especially important then, when they have a high aluminum content, what is needed to achieve a decorative matte surface. This prevents the bath from going into an unstable state.. Insufficient maintenance of the bath can lead to precipitation of aluminum hydroxide, which means the complete loss of this bath.

The main features of this bath are:

  • High aluminum content
  • Specified sodium hydroxide content in relation to aluminum content
  • Special additives for keeping aluminum in solution
  • Additives for the deposition of impurity metals.

Impurity metal precipitation additives separate the impurity metals from the aluminum alloy and form with them insoluble or poorly soluble metal sulfides (usually very small, black particles). Depending on the content of impurity metals in the aluminum alloy, the alkaline solution of the E6 bath quickly turns black. Small, black pigments are not involved in the etching process [1].

Aluminum Alkaline Etching Process

Purpose of Alkaline Etching of Aluminum

The process of alkaline etching of aluminum products occurs when they are immersed in an aqueous solution of sodium hydroxide and some additives.

Factors, which affect this process are:

  • Etching rate, which depends on:
    – temperature
    – aluminum hydroxide concentration
  • Time (processing time).

The purpose of alkaline trawling is:

  • Dissolve the aluminum surface, to remove embedded impurities and imperfections. The result is a smooth, homogeneous base for the subsequent anodizing process to obtain an anodic coating with a decorative finely dispersed matte surface.

Chemical reactions of alkaline etching of aluminum

It happens, when aluminum on the surface of the product interacts with sodium hydroxide and water to form sodium aluminate and release hydrogen, according to the following chemical reaction (reaction No. 1) [2]:

This reaction occurs with the consumption of free sodium hydroxide.

When the concentration of sodium aluminate increases, the side reaction according to the following formula (reaction No. 2) becomes more and more preferable:

 

 

In this reaction, sodium aluminate reacts with water, resulting in the formation of aluminum hydroxide, which accumulates as a suspension in the bath solution E6. As you can see from this formula, this reaction also results in the release of additional sodium hydroxide, which the, in turn, consumed in reaction # 1.

Aluminum hydroxide slowly precipitates from the suspension in the bath solution E6 to the bottom of the bath or to various surfaces inside the bath E6, for example, on heating elements, very hard fossils. This occurs according to the following reaction of aluminum hydroxide dehydration (reaction No. 3):

 

 

The resulting reaction for the aluminum alkaline etching process is a reaction between aluminum and water to form an alumina precipitate and release hydrogen.

2Al + 6H2O = 2Al(OH)3 + 3H2

Factors, which affect the rates of these reactions # 1, # 2 and # 3 are:

  • temperature
  • sodium hydroxide concentration
  • aluminum concentration in solution
  • additives to prevent precipitation of aluminum hydroxide from solution and to promote desired reactions

When the concentration of aluminum in solution increases, free aluminum hydroxide is consumed according to reaction No. 1. It can quickly reduce the sodium hydroxide concentration until, until reaction # 2 releases it back into solution.

Solubility of aluminum in an alkaline solution

Aluminum dissolves well in solutions of caustic soda [3]:

  • 7 moles per liter, which is equivalent to:
  • 7 x 27 = 189 g / l for Al3+ or
  • 7 x 82 = 574 g / l for NaAlO2

The numbers 27 and 82 Is the atomic weight of aluminum and the molecular weight of sodium aluminate, respectively.

Such a high solubility of aluminum in a caustic soda solution is achieved when the following conditions are met simultaneously:

  • the specified concentration of caustic soda (NaOH) is maintained,
  • the set temperature of the solution is maintained,
  • the specified concentration of special additives is maintained, which prevent the precipitation of aluminum hydroxide.

Maintaining the stability of the bath E6

A high aluminum content is required for particularly matt surfaces, which can reach 200 g / l. With such a high aluminum content, special attention is required to bath stability [1].

Stable black bath E6

Just one look is enough, to determine if bath E6 is still stable. If it has a deep black color (picture 1), then you can be sure, that the bath is sufficiently stable. Of course, this visual assessment must always be confirmed by regular chemical analysis of the composition of the bath.


Figure 1 - Bath E6 deep black in stable condition [1]

Gray bath E6 - what's going on?

If the E6 bathtub turns gray instead of rich black, then you need to react immediately. In this case, the process of destabilization has already begun.. During this process, white, poorly soluble aluminum hydroxide particles. If the proportion in the bath continues to increase, then the bathtub becomes more and more gray, that is, the black color changes to dark gray, then medium gray, then light gray, until it turns completely white. In a light gray and white state, the bath is considered lost and must be completely restored., which requires significant amounts of finance, work and time. Therefore, it is necessary in every possible way to avoid the occurrence of such a state..


Figure 2 - Bath E6 dark gray - the beginning of destabilization [1]

How to save the unstable gray bath E6?

If the alkaline bath E6 turns slightly gray, necessary:

  • Complete bath chemistry analysis immediately.
  • A decrease in the aluminum content will indicate the instability of the bath., since part of the dissolved aluminum has already separated from the solution in the form of poorly soluble aluminum hydroxide.
  • At the same time, the sodium hydroxide content will increase, so it is released during the destabilization of the solution.

Figure 3 - Chemical reaction of the destabilization process [1]

It would be a mistake not to add sodium hydroxide to the bath., although its content is most likely still within the specified interval. Low alkalinity contributes to further destabilization of this bath [1]:

  1. A large amount of a special additive must be added to the gray bath (for example, Alfasatin) for extra stabilization, for example, twice as much, than usual.
  2. It is recommended to increase the alkalinity of the bath by adding sodium hydroxide, to further stabilize it.

These stabilization measures ensure that, to:

  • no further precipitation of aluminum hydroxide occurred and
  • the aluminum hydroxide remaining in the bath solution was gradually removed from the bath with treated aluminum surfaces.

As a result, the bath should gradually return to a stable state (black). During this time, monitoring the bath chemistry is especially important.. If the bath solution turns black again, then the stabilization process can be considered successful.

What to do with a light gray or milky white bath E6?

If the bath E6 has reached this state (figure 4), then there is no longer any way to save her. You can only wait a while, until the white sludge settles to the bottom of the bath. The settled liquid phase can then be pumped into an empty bath or container and then, depending on her condition, use when preparing a new bath.

However, the released white alumina sludge must be removed from the bath as soon as possible. If you delay with this, it will become stone and it will already be very difficult to clean the bathtub from it (picture 5).


Figure 4 - Fully destabilized bath E6 [1]


Figure 5 - Fossilized sludge of aluminum hydroxide from the bath E6 [1]

 

Sources:

  1. https://alufinish.de/en/destabilisation-of-alkaline-e6-long-term-pickling-processes/
  2. SPECULAR REFLECTANCE OF ANODIZED 6061-T6 ALUMINUM ALLOY / JON STRAUSS, Oregon State University – 2013
  3. Alkaline Etching of Aluminum & Its Alloys – A New Caustic Soda Recovery System –Italecno S.r.l. & Chemetall 2002.