DE2003332C3 - Corrosion-resistant, partially crystallized enamel and method for producing an enamel coating - Google Patents

Description

The invention relates to a corrosion-resistant, partially crystallized enamel, and to a method for producing an enamel coating.

Metal substrates, especially steel substrates, are often provided with an enamel coating to prevent corrosion of the substrate. With the usual Enamelling is an enamel frit along with a milling additive on the surface of the substrate applied in the form of a squeegee, and after the squeegee has dried it is coated Substrate heated or fired to an elevated temperature, this temperature generally between 816 ° and 982 ° C. The enamel mass is melted in the process.

The main component of most enamels is silicon dioxide. Now that is coated with the enamel If the substrate is exposed to strongly corrosive media during its use, the aim is to achieve the Keep the silicon dioxide content at 70 to 85%, as the silicon dioxide increases the resilience of the enamel

increased against chemical attack.

It is also known that a devitrified enamel has good impact and shock resistance as well as excellent Has tenacity. However, an email that has been declassified generally lacks an adequate one Corrosion resistance because the devitrified particles consist mainly of silicon dioxide while the amorphous glass matrix, which is depleted in silicon dioxide, has a low resistance to

'<> has a corrosive attack.

A move has therefore been made to combine a glass mass (enamel mass) with a high SiO ₂ content and good corrosion resistance with a devitrifiable glass mass (enamel mass) in order to

'5 to get an enamel cover that is not just one has good impact resistance but also good corrosion resistance. It has been the case up to now before that one milled the corrosion-resistant glass mass with the devitrifiable glass mass and thereby obtained mixture applied to the substrate. After baking the coated substrate until Melting the glass coating, the coated article was subjected to a further heat treatment at a temperature below the firing temperature to develop the devitrified particles. as The result of this final heat treatment was a three-phase system consisting of the amorphous Glass matrix of the devitrifiable glass mass, which is formed by the excretion of the devitrified particles Silica is depleted, consisted of devitrified particles and corrosion-resistant glass mass. Since the silica-depleted amorphous glass matrix has poor corrosion resistance, the entire enamel coating showed a low level of corrosion

JS sion resistance.

From US Pat. No. 3,361,588 there is a method known, in which a steel substrate with both a devitrifiable glass mass and a corrosion-resistant Glass mass is coated and then heat-treated. In doing so, the corrosion-resistant Glass mass applied to the devitrified glass mass and then fired. However, when performing this procedure, you need two separate heat treatments are carried out, making this process technically cumbersome and becomes costly.

From British patent specification 1126031 is a Process for enamelling a metal substrate is known, in which first a devitrifiable primer coating and then applying a devitrifiable topcoat to the metal substrate. The one with it The resulting composite structure is then heated to form both the primer coat and the top coat to partially devitrify (to crystallize). There is also a method from British patent specification 984446 known for coating a metal substrate, in which a devitrifiable (crystallizable) glass mass the metal substrate is applied and then the metal substrate is heated to a temperature at which the Glass mass is at least partially devitrified (crystallized). From Swiss patent specification 433 903 is finally a method for applying a crystallizable glass mass to a metal substrate known, in which the crystallizable glass mass is first pulverized, the powder on the to be coated Metal substrate is applied and then melted by heating, the elevated temperature so is maintained for a long time until a partial deglazing

sung (crystallization) of the coating occurs.

In all of these cases a coating is obtained which does not have the desired combination of improved impact resistance and toughness and excellent corrosion resistance.

The object of the invention is therefore to provide a corrosion-resistant metal substrate coating with good To develop mechanical properties that does not have the disadvantages described above, the in particular, has improved impact strength and corrosion resistance and is technically simple and economical to achieve protective metal substrate can be applied.

It has now been found that this object can be achieved with an enamel which consists of a mixture of a glass mass that has been devitrified and a glass mass that cannot be devitrified . During baking, the amorphous glass matrix of the devitrified glass mass dissolves in the corrosion-resistant glass mass, whereby the silicon dioxide-depleted amorphous glass matrix in the finished enamel coating is practically eliminated. After firing, an enamel coating is created, which consists primarily of devitrified crystals and a material from the corrosion-resistant, non-devitrified glass mass and the glass matrix of the devitrified glass mass.

The invention relates to a corrosion-resistant, partially crystallized enamel, which thereby is characterized in that it consists of a mixture of

a) a corrosion-resistant, non-devitrifiable glass mass which contains 63 to 80% by weight silicon dioxide, and

b) up to 60 % by weight of a glass mass devitrified by thermal pretreatment, made of an amorphous glass matrix, which can be melted into the corrosion-resistant glass mass during baking, and embedded »crystalline particles ...

The enamel coating obtained using the enamel according to the invention on the substrate exhibits not only improved impact resistance and impact resistance, but also excellent Corrosion Resistance? .Uf. It also has increased abrasion resistance.

According to a preferred embodiment of the invention, there is at least one deglazed glass mass 50% by weight, in particular 60 to 85% by weight, of crystalline particles.

According to a further preferred embodiment of the invention, the devitrified glass mass makes 20 to 50% by weight of the enamel, and the crystalline particles in the devitrified glass mass preferably have a Size of less than 1 μm.

The invention further provides a process for producing a corrosion-resistant, partially crystallized enamel coating, which is characterized in that, so head passes an e-mail, as described above, that the amorphous glass matrix of the devitrified glass frit is melted substantially in the corrosion-resistant glass mass .

According to a preferred embodiment of this process is to the devitrified glass frit by heating a entgiasbaren glass mass to a temperature of 538 ° to 871 ⁰ C forth. The enamel is preferably fired at a temperature within the range from 760 ° to 927 ° C.

The following procedure is used to produce the enamel coating . A devitrifiable glass mass (hereinafter sometimes also referred to as a glass frit) is first dry-ground and then heated at an elevated temperature within a period of time.

treated, which is sufficient to remove the glass mass (frit) to devitrify as much as possible. * Devitrification involves the development of small crystals, e.g. B. of silicon dioxide, in a matrix of amorphous glass result. Subsequent to the devitrification, the devitrified

Ό Glass mass (frit) with a standard corrosion-resistant glass mass (glass frit) that has a high Percentage of silica contains, wet milling. The resulting scraper is applied to the substrate to be coated. After drying nen the coated substrate is baked at an elevated temperature within a period of time that enough to melt the glass. The degassable glass mass (glass frit) is a common glass frit that is used during the heat treatment can be devitrified. The devitrifiable glass frit can, for example, have the following composition (in% by weight):

Li ₂ O 1-25%

ALC ₃ 0-30%

SiO ₂ 60-80%

Na ₂ O 0-5%

MgO 0-5 %

CeO. 0-10%

TiO ₂ '0-5%

ZrO ₂ O- 5%

PbO 0-5%

CaO 0-10%

Specific examples of such glass frits (composition in% by weight):

15.0 1.5 8.0 25.0 2.0 60.0 75.0 75.0 5.0 - 3.0 3.0 8.5 - 3; 0 - 3.0 - 4.0 -

Li ₂ O ALO,

SiO ₂
Na ₂ O
MgO
CeO ₂
TiO ₂

ZrO ₂
PbO
CaO - - 9.0

The devitrifiable glass frit is first dry-ground in the usual way. The particle size ά € τ overall-ground glass frit is not critical, but is generally less than 0.5 mm. Subsequent to the grinding, the glass frit is heated to an elevated temperature for a period of time that is sufficient to devitrify the glass frit practically completely. The temperatures and times required for devitrification depend on the composition of the glass frit, but the temperatures are generally between 538 ° and 871 ° C. The periods of time maintained at such temperatures generally vary between 1 and 2 hours. During this heat treatment, silicon dioxide particles crystallize out of the amorphous glass matrix. It is advisable to crystallize out (vitrify) the part of the glass frit that can be completely de-gassed. In most cases, the crystals after devitrification make up at least 50, often 60 to 85% by weight of the devitrified glass frit. The devitrified crystals have a size of

less than 10 µm. Preferably they are between 0.1 and 2.0 µm in size.

Subsequent to devitrification, the devitrified frit is wet with a corrosion-resistant glass frit and a mill additive. The corrosion-resistant glass frit can be composed as follows (% By weight):

SiO ₂ 63-80% TiO, 0-2% ZrOj 0- 8% CaO 0-2% Li ₂ O 1- 5% Na ₂ O .8-17% K ₂ O 0- 7% MgO 0-2% F ₂ 0-3% CoO 0-1.25% MnO 0-1.50% NOK 0-1.50%

Specific examples of corrosion-resistant frits falling under the composition given above are given below (% by weight):

1 2 3 SiO ₃ 72.5 73.5 75.0 TiO ₂ 1.0 - - ZiO ₂ 4.0 5.5 4.5 CaO 1.0 2.0 1.5 Li ₂ O 2.5 3.0 3.0 Na ₃ O 13.5 14.0 12.5 K ₂ O 2.0 - 1.0 MgO 1.0 - 1.0 F ₂ - 2.0 - CoO 0.5 - 0.5 MnO 1.0 - 0.5 NOK 1.0 " - 0.5

In most cases, the corrosion-resistant glass frit is a non-devitrifiable frit. However, this is not essential. The corrosion-resistant frit can be devitrifiable, but not under the conditions of the enamel firing. Even if the corrosion-resistant frit can be devitrified, it will not be devitrified during the burning period, and not because the metal object is not We are kept at the firing temperature for a period of time sufficient to make a devitrifiable corrosion-resistant Deglass frit.

The milling additives that are added to the glass frit are conventional additives, for example to sodium nitrate, bentonite, sodium aluminate, clay or the like.

The devitrifiable frit makes up to 60% by weight of the dry frit mixture and preferably 20% up to 50% of the dry mix.

The devitrifiable frit and the corrosion-resistant glass frit are preferably in the form of a wet grinding aqueous suspension. In some cases, however, the two frits can also be dry-milled and then applied to the metal object in the form of a dry dust coating will. The particle size of the milled frit mixture is not critical. It corresponds to what is usually observed in enamelling technology Particle sizes. Generally up to 85% of the ground frit particles pass through a sieve a clear mesh width of 0.075 mm through it.

The wet grinding mixture of fries can be added to the Metal base can be applied in the usual way, namely by spraying, dipping, pouring, Brush on or the like. After it has been applied to the metal substrate, the coating dried to evaporate the water.

The metal base can be steel or be any other metal with a coefficient of thermal expansion equal to that of voi.

Steel is similar. In particular, the metal base can be made of mild steel, stainless steel or the like exist.

The metal base coated with the enamel mixture is kept at a temperature between 760 and

Fired at 927 ° C. Burning usually occurs at a temperature between 816 and 871 ° C, namely for a period of about 5 to 15 minutes. During the firing, the amorphous tends to be Glass matrix of the devitrifiable frit to dissolve in the corrosion-resistant glass, so that the low-silicon dioxide amorphous glass matrix is then eliminated in the resulting glass coating. To After firing, the coating consists of devitrified crystals and a material made of the corrosion-resistant Glass and the glass matrix of the devitrifiable frit. Since the glass matrix of the devitrifiable frit is not as If there is a separate phase in the final product, the corrosion resistance of the glass coating is noticeable improved. The presence of the devitrified particles improves the thermal shock resistance as well as the Toughness of the glass coating.

The devitrification of the devitrifiable glass frit is made possible before the frit is applied to the metal object compliance with a wider range of

Heat treatment for performing devitrification. If the frit on the metal object after the Firing devitrified, then the heat treatment area is limited as it is not possible to use some metal parts heat treat for extended periods of time without raising.

Another disadvantage of the previously known methods, when they are carried out, then devitrification carried out after the glass has been applied to the respective metal object, loading

means that different parts of the object are heated to a different temperature, with the result that devitrification takes place differently in the glass. This will make different physical properties in the enamel

train received. This problem is eliminated according to the invention, since the frit as such is prior to application is devitrified onto the respective object, so that the object does not undergo prolonged de-vitrification heat treatment must be subjected.

If the frit as such is subjected to a devitrification heat treatment, then it is also possible to use more refractory frit ingredients which have higher proportions contain silicon dioxide and have higher devitrification temperatures to use. High fire festivals Preparations cannot be used if devitrification is carried out then after the frit has been applied to the respective object, as a longer heating on tile high devitrification temperature disadvantageously can affect the physical properties of the item.

Specific examples of the method of the invention are given below:

example 1

A devitrifiable frit is produced which has the following composition (in% by weight): Li ₂ O 8.0

Al ₂ O ₃ 2.0

SiO ₂ 75.0

MgO 3.0

TiO ₂ 3.0

CaO 9.0

The frit is ground and heated to a temperature of 732 ° C and at this temperature during held for 17 hours to devitrify the frit. Subsequent to the devitrification the frit is cooled to room temperature in the air.

40 parts of the devitrified frit are ground with 60 parts of a corrosion-resistant glass frit, a milling additive composed of 3 parts of clay, 0.2 parts of a suspension aid based on colloidal Al ₂ O ₃ and 0.1 part of sodium aluminate and 43 parts of water .

The corrosion-resistant glass frit has the following composition (in% by weight): SiO, 72.5

1.0
4.0
1.0
2.5
13.5
2.0

MgO 1.0

CoO 0.5

MnO 1.0

NiO 1.0

When wet milling is carried out, the devitrified frit and the milling additives are initially milled for a period of 1 hour, after which the corrosion-resistant frit is added and the milling is continued for a further _1/2 hour. After grinding, the particles of the frit mixture are of such a size that less than 3% is retained by a sieve with a mesh size of 0.075 mm.

The slipper is then sprayed onto the primed surface of a mild steel plate and placed under Infrared lamps dried.

After the coated plate has dried, it is kept at a temperature of 838 ° C. for a Burned time span of 9 minutes.

TiO ₂

ZrO ₂

CaO

Li ₂ O

Well, O

K ₂ O

The coated steel plate obtained has good impact and shock resistance as well as excellent Corrosion resistance.

Example 2

A devitrifiable frit is produced which has the following composition (in% by weight): Li ₂ O 8.0

Al ₂ O ₃ 2.0

ίο SiO, 75.0

MgO 3.0

TiO ₂ 3.0

CaO 9.0

The frit is ground and heated to a temperature of 843 ° C. and held at this temperature for a period of IV ₂ hours to devitrify the frit. After the devitrification, the frit is cooled in the air to room temperature.

30 parts of the devitrified frit are ground with 70 parts of a corrosion-resistant glass frit, a milling additive composed of 3 parts of clay, 0.2 part of a suspension aid based on colloidal Al ₂ O ₃ and 0.1 part of sodium aluminate and 43 parts of water.

The corrosion-resistant glass frit has the following composition (in% by weight):
SiO, 73.5

5.5
2.0
3.0

Na ₂ O 14.0

F ₂ 2.0

When carrying out the wet milling process, the devitrified frit and the milling additives are initially milled for a period of 1 hour, after which the corrosion-resistant frit is added and the milling is continued for a further IV ₂ hours. After grinding, the particles of the frit mixture are of such a size that less than 3% are retained by a sieve with a mesh size of 0.075 mm.

The slipper is then sprayed onto the primed surface of a mild steel plate and placed under Infrared lamps dried.

The obtained steel plate provided with a crystallized enamel coating has a good one Impact and shock resistance as well as excellent corrosion resistance.

ZrO ₂
CaO
Li ₂ O

Claims (8)

Patent claims: 1. Corrosion-resistant, partially crystallized enamel, dadu cn marked that it consists of a mixture of a) a corrosion-resistant, non-devitrifiable glass mass containing 63 to 80 wt.% Silici umdioxid , and b) up to 60 wt.% of a glass mass devitrified by thermal pretreatment from a amorphous glass matrix, which can be melted into the corrosion-resistant glass mass when it is burned in, and embedded in it crystalline particles. 2. Email according to claim 1, characterized in that the devitrified glass mass to at least 50% by weight consists of crystalline particles. 3. Email according to claim 2, characterized in that the devitrified glass mass to 60 to 85% by weight consists of crystalline particles. 4. Email according to one of claims 1 to 3, characterized in that the devitrified glass mass Makes up 20 to 50% by weight of the enamel. 5. Email according to one of claims 1 to 4, characterized in that the crystalline particles in the devitrified glass mass are less than 1 μm in size. 6. Process for producing a corrosion-resistant, partially crystallized enamel coating, characterized in that an enamel according to claims 1 to 5 is burned on in such a way that that the amorphous glass matrix of the devitrified glass mass is essentially in the corrosion-resistant Glass mass is melted down. 7. The method according to claim 6, characterized in that the devitrified glass mass by heating a devitrifiable glass mass to a temperature of 538 "to 871 ° C. 8. The method according to claim 6 or 7, characterized in that the email at a Temperature within the range of 760 ° to 927 "C burns up.