WO2014057081A1

WO2014057081A1 - Use of oxygen compounds of aluminium as corrosion protection agents and release agents for soda-lime-silicate glasses

Info

Publication number: WO2014057081A1
Application number: PCT/EP2013/071257
Authority: WO
Inventors: Martin Gross
Original assignee: Technische Universität Bergakademie Freiberg
Priority date: 2012-10-12
Filing date: 2013-10-11
Publication date: 2014-04-17
Also published as: DE102012020094B3; EP2906509A1

Abstract

The invention relates to the use of oxygen compounds of aluminium or particulate dust which contains oxygen compounds of aluminium as corrosion protection agent and release agent for soda-lime-silicate glasses in glass storage and during glass transport. The release agents contain release powder based on plastic and oxygen compounds of aluminium as corrosion protection additive having a particle size below that of the particles of the release powder based on plastic.

Description

Use of oxygen compounds of aluminum as corrosion inhibitors and release agents for soda lime silicate glasses

The invention relates to the use of aluminum compounds or particulate dust containing aluminum compounds, as corrosion inhibitors for glass, in particular for soda-lime silicate soda glasses and release agents.

If flat glass is transported, there must be a release agent between the panes, otherwise the glasses will stick together so strongly due to adhesive forces or chemical reaction that the user will no longer be able to separate them. Traditionally, paper has been used for this purpose in the glass industry. However, this is known to have the disadvantage that it leaves residues on the glass, which make the glass unusable. Since the seventies therefore increasingly fine polymer beads are used for this purpose, which also have the advantage that they no longer need to be removed manually.

Since glass surfaces can corrode during transport or storage, additives are added to these polymer particles (typically special acids) to prevent corrosion. Here are polymer beads of a very narrow particle size distribution between 50 and 150 μηη based on polymethyl methacrylate and polyolefins application. Boric acid or adipic acid are added as an additive. As an alternative to powdered release agents with corrosion protection and a liquid corrosion protection is used to prevent glass corrosion. The liquid corrosion protection is sprayed onto the glass. After the drying process, a pure release agent is used [http://www.acw-info.de/Anwendungen/Kategorien/Trennen].

In the acidic pH range, the common silicate glasses are chemically very resistant. The acid character of the Si0 ₂ network causes this high resistance. In the alkaline range, the Si0 ₂ network of the glass is not stable. The bonds of the network are broken up, which dissolves all the glass. If sufficiently stable constituents are present in the glass, then a layer that is not soluble in the alkaline range can form on the glass surface, which counteracts the alkaline attack.

During storage of flat glass, the glass surface corrodes due to the effect of atmospheric moisture. Here, the water is initially in gaseous form. When the ambient temperature fluctuates, condensation of small amounts of water on the glass surface occurs. This can be assumed to be approximately of chemically pure water. This water initially leaches alkalis from the glass surface and thus becomes slightly basic. There is an attack on the glass network. Due to the low water volumes, the saturation limit of the solubility for various sparingly soluble glass reached parts. This results in the formation of adherent, difficult or impossible to remove layers on the glass surface. Thus, while the cleaning and leaching of the glass surface dominate during dishwashing, the formation of an undesirable surface layer prevails during the storage of flat glass.

These layers disturb the optical and mechanical properties of the glass and are therefore undesirable. Therefore, the products hitherto used to inhibit glass corrosion during the storage of flat glass are aimed at maintaining an acidic environment on the glass surface, because the transport and storage of the glasses should take place in a slightly acidic environment [http://de.wikipedia.org/ org / wiki / glass corrosion]. As a result, the alkaline glass attack can not take place.

The solutions used so far have crucial disadvantages. Boric acid is classified by the new REACH regulation as toxic for reproduction Category II as well as SVHC ("substance of very high concern") [EC-Regulation No. 1907/2006 (REACH) Registration, evaluation, authorization and restriction of chemicals ]. Comparative experiments have shown that adipic acid and zinc compounds have an insufficient effect.

According to DE 10 2009 025 411 B4, the use of zinc dust particles or particulate dust containing zinc or a zinc compound is known as a corrosion inhibitor for soda-lime float glass. In this case, sodium ions are replaced on the glass surface of stacked soda-lime float glass by zinc ions, whereby a glass corrosion is prevented.

From US 5,624,892 A is known to use to inhibit the corrosion of fine tableware dishwashing detergents, the u. a. Contain aluminum salts.

US Pat. No. 5,731,277 A discloses a method for producing a dishwasher rinse aid intended to prevent the washing out of transition metals from tableware and containing aluminum compounds which form aluminum tetrahydroxide in solution.

No. 7,759,299 B2 describes a dishwashing detergent composition consisting of a detergent, an alkali source and a corrosion inhibitor. The corrosion inhibitor contains a source of water-soluble aluminum ions and at least one source of calcium or magnesium ions.

When cleaning in the dishwasher, a slightly alkaline washing solution attacks the glass surface. This results in an uneven removal of surface components and only subordinate to a layer formation. The excess of attacking medium as well as the flow rates in the dishwasher cause corrosion products to be washed from the surface. The effectiveness of the aluminum Detergent based on the formation of a thin, macroscopically invisible layer on the surface. This inhibits the further glass corrosion without disturbing the visual impression of the glass.

The object of the invention is to develop a glass corrosion inhibitor with improved activity.

According to the invention the object is achieved in that compounds of aluminum or particulate dust containing compounds of aluminum are used as corrosion inhibitors for glass. In principle, all compounds of aluminum such as aluminum sulfate, aluminum phosphate, aluminum acetate, zeolite A, aluminum formate, aluminum nitrate, aluminum oxide, aluminum hydroxide and / or alkali aluminates are suitable.

Oxygen compounds of aluminum or particulate dust containing oxygen compounds of aluminum are preferably used as corrosion inhibitors for soda-lime silicate glasses in glass storage and in glass transport.

Particle dust is understood to mean powders of the compounds according to the invention having a particle size of from 10 to 80 μm, preferably from 15 to 70 μm, very particularly preferably from 20 to 65 μm.

Oxygen compounds of aluminum (aluminum oxide, aluminum hydroxide, alkali aluminate), in particular mixtures of aluminum hydroxide and sodium aluminate in a ratio of 2: 1 to 11: 1, particularly preferably mixtures of aluminum hydroxide and sodium metaaluminate in the ratio of 3: 1 to 8: 1, are preferred. The ratios mentioned here denote mass ratios. These mixtures react weakly alkaline, but surprisingly show the best corrosion protection.

It is also possible to apply the aluminum compounds alone to the glass surfaces, especially in molded glass products.

The corrosion-inhibiting effect is not bound to the addition to a release agent. Certain glass products require no release agent during storage. This is z. B. on the inner surface of container or tube glass the case. Here, the corrosion inhibitor can be used without additional plastic particles. It should be noted that the corrosion inhibitor is not between two touching glass surfaces. This can lead to mechanical damage to the glass surface.

The invention therefore also includes corrosion inhibitors for the treatment of shaped soda lime silicate glasses, z. B. for corrosion protection treatment of the inner surface of container or tube glass, which consists of powdered oxygen compounds of aluminum ums and optionally additives for better flowability and water repellency of the oxygen compounds of aluminum.

The powdery oxygen compounds are preferably aluminum oxide and / or aluminum hydroxide and / or alkali aluminate. Particularly preferred are mixtures of aluminum hydroxide and sodium metaaluminate in a mass ratio of 2: 1 to 1 1: 1, most preferably mixtures of aluminum hydroxide and sodium metaaluminate in a mass ratio of 3: 1 to 8: 1.

The grain size of the aluminum compounds is 10 to 80 μηη, preferably 15 to 70 μηη, most preferably 20 to 65 μηη.

It is advantageous to formulate release agents for soda lime silicate glasses with the aluminum compounds according to the invention.

The compounds of aluminum are added to the separating powders used as corrosion-inhibiting substances. The grain size of the compounds of aluminum must be below that of the plastic particles used.

The release agents contain for this purpose plastic-based release powders and oxygen compounds of aluminum as anti-corrosion additive with a particle size smaller than the particles of the plastic-based release powder. Plastic-based separating powders are polymethylmethacrylate (PMMA) or polyethylene powders.

Advantageously, the release agent contains oxygen compounds of aluminum in a proportion of 5 to 50% by weight, preferably 10 to 30% by weight.

Aluminum oxide, aluminum hydroxide, alkali aluminate, in particular mixtures of aluminum hydroxide and sodium metaaluminate in a mass ratio of 2: 1 to 1: 1, particularly preferably mixtures of aluminum hydroxide and sodium metaaluminate in a mass ratio of 3: 1 to 8: 1 are used as corrosion protection additive.

The grain size of the aluminum compounds is smaller than the grain size of the plastic particles. Under this condition, the grain size of the aluminum compounds is advantageously 10 to 80 μm, preferably 15 to 70 μm, very particularly preferably 20 to 65 μm.

The aluminum compounds and release agents according to the invention are advantageously used for the storage and transport of flat glasses. In addition, the aluminum compounds and release agents according to the invention can be used in the range of tubular glass (for example for the production of fluorescent tubes) and in container glass. Corrosion inhibitors are mainly acidic or partially neutral compounds, since basic compounds attack the silicate network of the glass surface and thus lead to an increase in corrosion. It is therefore surprising that the aluminum compounds and release agents according to the invention have a corrosive effect due to their basic character. This contradicts previously known corrosion protection and release agents. A basic product would promote glass corrosion.

Despite the basic character of the aluminum compounds and release agents according to the invention, it was possible to effectively suppress a layer formation on the glass surface.

By using a mixture of aluminum hydroxide and sodium aluminate, the proper balance between basicity and thus prevention of film formation and release of aluminum and thus prevention of corrosion can be achieved. This can both the corrosion of the glass inhibited and a layer formation can be prevented by aluminum ions. The spectrometric measurement of the transmission shows a very small change in the glass surface, which is due to the noise of the measuring method. Other aluminum compounds show a significantly changed surface. The excellent effectiveness of this preferred mixture can not be readily deduced from its chemical properties.

With the aluminum compounds and release agents according to the invention a chemically unchanged as possible glass surface is maintained in order not to disturb further process steps such as the occupancy of the glass surface with functional layers.

The main advantage over known corrosion inhibitors lies in the small change in the glass surface. As a result, subsequent process steps of glass processing are facilitated. This has been confirmed by experiments with flat glass.

So flat glasses were powdered with release agents of the invention and stored Vi year at 10 - 20 ° C and 80% relative humidity. The reference sample used was a standard separation powder. Two different powders with different concentrations of corrosion inhibitors were also used. Subsequently, they were subjected to a hydrolytic resistance test based on DI N 52296. The glass surface is exposed after thorough washing of the powder and any dirt a water attack with deionized water for 1 h at 121 ° C in an autoclave. If the surface is altered by glass corrosion, the concentration of the ions dissolved out changes as there is a different chemical composition of the glass surface. This change is much less pronounced with the samples stored with the new powders than with the reference sample powdered with the standard glassware product. As stated in the exemplary embodiment, mixtures of aluminum hydroxide and sodium metaaluminate in particular show a significantly better corrosion-inhibiting effect than the conventionally used products.

Compounds of aluminum were tested on a float glass in comparison with the conventional corrosion-inhibiting additives zinc oxide, adipic acid and boric acid. The particle sizes of all powders used were below 63 μηι. The float glass samples measuring 66 mm x 66 mm were powdered over with the respective powder. Then they were exposed in the autoclave to a direct attack of water vapor at 135 ° C for 5 hours. An unpudged sample (blank sample) was also subjected to this test. The evaluation of the surface change by the corrosion was made by determining the integral transmission of the corroded sample and the starting glass. The corrosion index represents the ratio of the integral transmission of the corroded sample to the starting glass. The glass corrosion forms a water-rich, low-alkali layer on the glass surface. This has a relation to the base glass modified refractive index. If this layer is relatively flat, it leads to a transmission increase in certain wavelength ranges. The layer acts as a so-called λ / 4 layer. Often, however, the layer is uneven, so that there is a diffuse scattering of the light and the transmission in certain wavelengths decreases significantly. Both effects are superimposed, so that on a sample in certain wavelength ranges to an increase in the transmission and in other areas to a reduction in transmission. Both effects are due to corrosion. The corrosion index detects both effects by detecting the absolute value of the deviation of the transmission of the corroded sample from a non-corroded reference. This is described by the following equation.

Code number = 100

i

7 "...

'Transmission of the reference at the wavelength i in%

^ ^kDr ^ - ¹ Transmission of the corroded sample at the wavelength i in% i Number of measuring points Table 1 summarizes the results. Table 1

Corrosion-inhibiting additive Corrosion index

Without (blank) 253%

Zinc oxide (comparative sample) 133%

Boric acid (comparative sample) 30%

Adipic acid (comparative sample) 52%

Aluminum sulphate 53%

Aluminum phosphate 43%

Aluminum acetate 37%

Zeolite A 37%

Aluminum formate 30%

Aluminum nitrate 28%

Alumina pyrolytic 130m ² / g 27%

Aluminum hydroxide (hydrargillite) 22%

Aluminum hydroxide and sodium metaaluminate

Mix 1: 22 13%

Aluminum hydroxide and sodium metaaluminate

Mixture 1: 11 9%

Aluminum hydroxide and sodium metaaluminate

Mix 1: 3 8%

Aluminum hydroxide and sodium metaaluminate

Mix 1: 2 13%

Sodium Metaaluminate 11%

Claims

claims

1 . Use of oxygen compounds of aluminum or particulate dust containing oxygen compounds of aluminum as a corrosion inhibitor for soda lime silicate glasses in glass storage and glass transport.

2. Use according to claim 1, characterized in that the oxygen compounds of aluminum are aluminum hydroxide and / or alkali aluminates.

3. Use according to claim 1 or 2, characterized in that the oxygen compounds of aluminum are aluminum hydroxide and sodium metaaluminate.

4. Use according to any one of claims 1 to 3, characterized in that the oxygen compounds of aluminum are aluminum hydroxide and sodium metaaluminate in a mass ratio of 2: 1 to 1 1: 1.

5. Use according to one of claims 1 to 3, characterized in that the oxygen compounds of aluminum are aluminum hydroxide and sodium metaaluminate in a mass ratio of 3: 1 to 8: 1.

6. release agent for soda-lime silicate glasses containing plasticized powder and anti-corrosion agent, characterized in that the release agent contains as corrosion inhibitor oxygen compounds of aluminum with a particle size smaller than the particles of the release powder based on plastic.

7. Release agent according to claim 6, characterized in that it contains oxygen compounds of aluminum in a proportion of 5 to 50 wt .-%.

8. Release agent according to claim 6 or 7, characterized in that it contains alumina and / or aluminum hydroxide and / or alkali aluminate.

9. Release agent according to one of claims 6 to 8, characterized in that it contains aluminum hydroxide and sodium metaaluminate.

10. Release agent according to one of claims 6 to 8, characterized in that it contains aluminum hydroxide and sodium metaaluminate in a mass ratio of 2: 1 to 1 1: 1.