EP3705556A1 - Lubricant for metal forming, in particular for forming steel, and method for producing the lubricant - Google Patents

Abstract

The invention relates to a forming lubricant for iron materials, in particular for forming steel. According to the invention, the forming lubricant contains at least one mineral which has a layer structure and an agent for modifying the layer structure. The mineral is expediently swollen, delaminated and / or exfoliated by means of the modifying agent. The modifying agent is or preferably contains a surfactant, which preferably comprises a soap and / or an amine. In one embodiment of the invention, the surfactant is a water-soluble soap, preferably an alkali or alkaline earth salt of a fatty acid, which preferably has a chain length of at least ten carbon atoms. The mineral is expediently a sheet silicate, preferably kaolin or a mineral of the mica group. The invention also relates to a method for producing the forming lubricant and a molded body coated with the forming lubricant.

Description

The invention relates to a lubricant for metal forming, in particular for forming steel. The invention also relates to a method for producing the forming lubricant and a metal body coated with the forming lubricant.

When forming ferrous materials, different forming lubricants known through use are used, depending on the forming temperature. A distinction is made between cold forming, in which the workpieces to be formed are usually inserted into the forming tool at room temperature, warm forming, in which the workpieces are preheated to approx. 600 - 900 ° C before forming, and hot forming with the workpieces preheated to approx. 900 - 1200 ° C.
For a number of years, Lau hot forming has also been discussed, in which the workpieces are preheated to around 200 - 500 ° C before forming, whereby component temperatures of more than 500 ° C can occur during production.

During cold forming, the workpieces can heat up to temperatures> 400 ° C. In many cases, such heating is desirable since the strength of the shaped bodies to be reshaped can be reduced at higher temperatures. However, it is problematic that the previously known lubricants, for example soaps or waxes, are used for forming at the higher temperatures lose required properties. The load-bearing capacity collapses abruptly when temperatures are reached during forming that are in the range of the melting point of the forming lubricant.

In warm forging and hot forging, graphite, molybdenum sulfide or metal powder lubricants are normally used.

There are currently no suitable forming lubricants for the aforementioned Lau hot forming. The lubricants commonly used for cold forming are not suitable due to their low thermal resistance. It is therefore necessary to use the lubricants that are already used for hot or semi-hot forming. However, these lubricants are rarely used for the temperature range below 600 ° C, because during processing in presses, undesired adhesion to the tool and corrosion occur. In addition, molybdenum sulfide and graphite pollute the entire work environment and are comparatively expensive.

The invention is based on the object of creating a forming lubricant which is suitable for cold forming and which can be used at higher temperatures than the known forming lubricants.

According to the invention, this object is achieved in that the forming lubricant contains at least one mineral which has a layer structure and an agent for modifying the layer structure.

By modifying the layer structure, in particular by swelling, delamination and / or exfoliation, it is possible to produce a comparatively large number of individual, mutually displaceable layer layers in the mineral and thereby to provide the forming lubricant with exceptionally good lubricity. Due to the temperature resistance and pressure stability of the mineral, the forming lubricant is also stable at temperatures> 400 ° C, has good coefficients of friction there and can therefore be used for both cold and Lau hot forming.

Fig. 1 und 2

schematisch den Aufbau eines Schichtsilikats,

Fig. 3

das Ergebnis einer DSC-Messung des Umformschmierstoffs,

Fig. 4

chemisch den Aufbau des Umformschmierstoffs,

Fig. 5

schematisch die Anordnung des erfindungsgemäßen Umformschmierstoffs auf einer Oberfläche eines metallischen Werkstücks, und

Fig. 6

das Umformverhalten des Umformschmierstoffs und von Vergleichsstoffen.

The invention is explained in more detail below with reference to the accompanying drawings. Show it:

Figs. 1 and 2

schematically the structure of a layered silicate,

Fig. 3

the result of a DSC measurement of the forming lubricant,

Fig. 4

chemically the structure of the forming lubricant,

Fig. 5

schematically the arrangement of the forming lubricant according to the invention on a surface of a metallic workpiece, and

Fig. 6

the forming behavior of the forming lubricant and of reference materials.

In one embodiment of the invention, the mineral is a sheet silicate, preferably kaolin or a mineral of the mica group. The sheet silicates of the smectite group, the pyrophyllite group, the vermiculite group and the mica group have proven to be particularly suitable. Layered silicates are also known as leaf silicates or phyllosilicates.
Viewed microscopically, the minerals, in particular the phyllosilicates, are particles which are built up from a multi-layer arrangement (stack) of individual mineral flakes and / or layers, in particular silicate flakes and / or layers. These individual mineral flakes and / or layers are like Fig. 1 shows, each connected to one another by ionic interactions.
Ions are arranged between the mineral platelets, which can be exchanged through a suitable chemical treatment. By exchanging the ions, which is referred to as intercalation, the distances between the mineral platelets can be increased ("sources") and / or, as in FIG Fig. 2 is shown, individual mineral platelets are completely detached and rearranged. The detachment of the mineral flakes is called delamination. Exfoliation is when stacks of the mineral flakes have been delaminated, preferably at least in a proportion of> 30%, particularly preferably 50%.

The mineral, in particular the sheet silicate, is expediently produced synthetically or obtained from natural resources. It can advantageously be formed from naturally occurring weathering products that are found, for example, as components of various clay minerals. The mean particle size of the mineral is expediently 0-30 μm, preferably with a mean particle size <15 μm. Particle sizes between 0.1 μm and 5 μm have proven to be particularly advantageous for the formation of the forming lubricant.

In one embodiment of the invention, the phyllosilicates mentioned are compounds of the oxides, the hydroxides and / or the hydrates of aluminum and / or magnesium with silica, it being possible for aluminum and magnesium in these compounds to replace one another wholly or in part.
Such layered silicates can be described with the following basic formula:

xAl ₂ O ₃ • yMgO • zSiO ₂ • nH ₂ O

Examples of sheet silicates that are particularly suitable for producing the forming lubricant are: Kaolinite Al ₄ [(OH) ₈ | Si ₄ O ₁₀ ] (2Al ₂ O ₃ • 4SiO ₂ • 4H ₂ O) Pyrophyllite Al ₂ [(OH) ₂ | Si ₄ O ₁₀ ] (2Al ₂ O ₃ • 4SiO ₂ • H ₂ O) Talk Mg ₃ Si ₄ O ₁₀ (OH) ₂ (3MgO • 4SiO ₂ • H ₂ O)

In a particularly preferred embodiment of the invention, the modifying agent is or contains a surfactant, which preferably comprises a soap and / or an amine. The surfactant is expediently a water-soluble soap, preferably an alkali or alkaline earth salt of a fatty acid, which preferably has a chain length of at least ten carbon atoms. The modification, in particular the swelling, the delamination and / or the exfoliation, means that the layers of the mineral are covered with fatty acids or other long-chain carboxylic acids (C C10).
Salts of palmitic acid (hexadecanoic acid, C16) or stearic acid (octadecanoic acid, C18), for example, are well suited and inexpensive.
In a preferred embodiment of the invention, the soaps are at least in part soaps of divalent metals. Soaps made from magnesium, calcium and / or zinc are suitable, for example. The forming lubricant could also contain soaps of other divalent metal ions such as Sr ²⁺ , Ba ²⁺ , Pb ²⁺ , Cd ²⁺ .

In one embodiment of the invention, the forming lubricant has a metal soap, preferably calcium and / or magnesium stearate, and at least one stearate of monoethanolamine, triethanolamine, isopropanolamine and / and isobutanolamine (2-amino-2-methyl-1-propanol) . Unreacted, in particular unbridged, stearate residues remaining in the coating can react with any amine residues that may still be present with the formation of amides during subsequent drying (> 100 ° C.). The amides show higher melting points than the originally present, unreacted stearate components.
In addition to stabilizing the exfoliated mineral flakes, the metal soap also acts as a lubricant, the lubricating function of which is caused in particular by the fatty or carboxylic acid components.

It has surprisingly been found that even with a comparatively low metal soap content of <20% by weight, preferably <15% by weight, sufficiently good friction values are achieved. In addition, surprisingly, due to the exfoliated sheet silicate, the typical melting points of the metal soaps cannot be observed in the forming lubricant, even at higher contents. For example, as shown below using the in Fig. 3 DSC measurement shown is shown, a film made of the forming lubricant with a content of 30% calcium stearate no longer has the typical melting point for calcium stearate of about 160 ° C. From this it can be concluded that the calcium stearate contained is completely or at least largely adsorbed by the exfoliated silicate constituents or is present in a bridging form. A corresponding chemical arrangement is shown schematically in Fig. 4 shown.
In one embodiment of the invention, the metal soap content is 10-35% by weight, preferably 15-25% by weight.

In one embodiment of the invention, the forming lubricant comprises at least one polymeric film former, which is preferably in the form of a solution or a dispersion. In addition to its effect as a lubricant, the film former serves to give the forming lubricant such chemical and / or physical properties that it forms a film with the formation of a coating on the metal. This is achieved, among other things, because chemical bonds are formed at the phase boundary with the metal. The film former is expediently formed by at least one water-soluble and / or dispersible polymer that can be derived from the monomers of the vinyl group, in particular by at least one polymer or copolymer of at least one ethylene, one vinyl alcohol, one styrene and / or one acrylic acid in the form of the free acid Alkyl or their alkylene esters. The film former is preferably in the form of a microdispersion. It is particularly suitable for binding the forming lubricant to a, preferably phosphated, steel surface.

The polymer dispersion expediently contains a polyethylene-acrylic copolymer and / or, in order to increase the hardness of the forming lubricant, if it is arranged on the iron material, in particular steel, an acrylate. The acrylate can be present in unesterified, partially or completely esterified form, for example as methyl-ethyl, propyl and / or (iso-) butyl esters.
It has proven to be particularly advantageous to provide the polyethylene-acrylic copolymer as a mixture with an acrylate dispersion, since this results in an additional interaction and thus stabilization with swollen, delaminated and / or exfoliated mineral flakes.
In addition, the acrylate can be used to influence the adhesion and hardness of a layer formed by the forming lubricant on the iron material at a low temperature ("initial hardness"). The same applies to the hardness or toughness of the forming lubricant at higher temperatures ("final hardness").
A high initial hardness can be achieved, for example, by adding a styrene-acrylic copolymer. A high final hardness or toughness can be achieved, for example, by adding an acrylic-butadiene copolymer, which tends to cross-link at higher temperatures. A similar effect can be achieved with other crosslinkable acrylic derivatives or copolymers which, for example, have a propylene, butylene or isobutylene component.

The film former, which preferably bears carboxyl groups, can be in ionic and / or non-ionic form. It can be adjusted by means of alkali hydroxide and / or at least one amine.
In one embodiment of the invention, the ionic film formers have ammonia and / or a, preferably volatile, amine as counterion. The amine used is preferably at least one short-chain alkyl or alkanol derivative of ammonia with a maximum of four linear carbon units (C4). Monoethanolamine, triethanolamine, isopropanolamine and / or isobutanolamine have proven particularly suitable for this.

In a particularly preferred embodiment of the invention, the forming lubricant contains a powder made of polymer which has a particularly high hardness and / or a particularly high molecular weight (M .000 1,000,000). The polymer is incorporated into the coating film formed on the metal by the forming lubricant and has an advantageous effect particularly at low to medium temperatures of 400 400 ° C.

A powder, preferably micro-powder, of various non-aromatic substituted polyamides, such as polyamide 6, polyamide 66 or even polyamide 12, is suitable for achieving a high level of hardness. For particularly demanding applications, aromatically substituted polyamides can be used have higher melting points and / or temperature resistance. The preferred particle size of the micropowders is approx. 0-30 μm, with a particle size of 0.1 to max. 10 µm is particularly preferred.

As a micropowder with a particularly high molecular weight (M ≥ 1,000,000), the forming lubricant expediently comprises a, preferably spherical, micropowder made of polyethylene, with polyethylene having a linear (= unbranched) structure, for example LLDPE, being preferred due to its better temperature stability (Linear Low Density Polyethylene) or UHMWPE (Ultra High Molecular Polyethylene).
The particle size of the powder is expediently. 0-30 µm, the particle size from 0.1 to max. 15 µm is preferable.

In one embodiment of the invention, the forming lubricant contains an agent for its preservation, preferably a biocide, a foam inhibitor and / or an agent for stabilizing, in particular against sedimentation, of constituents of the forming lubricant. Isothiazolinone derivatives, methylisothiazolinone (MIT), chloromethylisothiazolinone (CMIT) and / or benzisothiazolinone (BIT) are suitable as biocides. The foam inhibitor is preferably formed by polyether-modified siloxanes or polydimethylsiloxanes. The forming lubricant can contain alkyl or alkanol ammonium salts of long-chain acrylic acid derivatives as stabilizers.

In the preferred embodiment of the invention, the forming lubricant is present as a coating on the metal body.
In one embodiment of the invention, the forming lubricant has the mineral in a proportion of 2 to 70% by weight, preferably 10 to 50% by weight, particularly preferably 20 to 40% by weight.
It expediently contains the modifying agent in a proportion of 5 to 50% by weight, preferably 10 to 35% by weight, particularly preferably 15 to 25% by weight.

In one embodiment of the invention, the forming lubricant has the film former in a proportion of 10 to 60% by weight, preferably 15 to 50% by weight, particularly preferably 20 to 45% by weight. The film former is expediently formed with a weight fraction of at least 1/4 from polyacrylate, with a weight fraction of at least 1/4 from polyethylene-acrylic copolymer and / or with a weight fraction of at least 1/4 from polyamide.

The quotient of the proportions by weight of the mineral, in particular the sheet silicate, and the modifier, in particular the metal soap, is expediently between 0.2: 1 and 1.8: 1, preferably between 0.4: 1 and 0.8: 1 .

The forming lubricant advantageously contains the powder mentioned in a proportion of 0-50% by weight, preferably 5 to 40% by weight, particularly preferably 10 to 30% by weight.

In one embodiment of the invention, the forming lubricant is packaged as a liquid coating agent, which is provided for arrangement on the body made of metal, preferably for forming a coating on the body, and is preferably a dispersion of the forming lubricant. The, preferably liquid, coating agent contains the forming lubricant expediently in a concentration of 2 to 70% by weight, preferably 5 to 60% by weight. The continuous phase of the coating agent is expediently formed by an aqueous liquid, preferably water, or an organic liquid.
It has proven to be advantageous to provide the coating agent with a forming lubricant concentration of 2 to 10% by weight, preferably 4 to 8% by weight, if the metal is to be sprayed with the coating agent or dipped into the coating agent. At these concentrations, the coating agent expediently has a pH of 8.4 to 10.5, particularly preferably 8.7 to 9.5.
If the metal is coated with the forming lubricant while the metal is being drawn in a drawing die, it has proven advantageous to provide the coating agent in a forming lubricant concentration of at least 10% by weight, preferably at least 15% by weight. In this case, the coating agent expediently has a pH of 10.0-13.0 and particularly preferably 10.5-11.5.

The metallic body is expediently immersed in a bath of the coating agent, in particular the aqueous solution, in order to form the forming lubricant as a coating on it. As an alternative or in addition to this, the metallic body can be sprayed or misted with the coating agent, in particular the aqueous solution.
The forming lubricant according to the invention can be applied directly to the metal, in particular the steel. If the forming lubricant is applied directly to a preferably bare, ie uncoated, metallic surface, it has proven to be advantageous to clean the surface using a preferably spherical blasting agent, for example abrasive grains, before applying the forming lubricant.
It has been shown, however, that the best forming results are achieved when the metal has been phosphated beforehand. For this purpose, the workpieces in question are previously phosphated in a commonly used zinc, calcium, magnesium or / and manganese-containing phosphating solution, a phosphate layer of 6-10 g / m ^{2 being} particularly preferred.
The workpieces phosphated in this way are then dipped into the aqueous dispersion of the coating according to the invention. After drying in the air or in a dryer, a tightly adhering and water-resistant, thin film remains.

In the preferred embodiment of the invention, the film is formed with a coverage of at least 0.25 g / m ² . Particularly good forming results can be achieved with a film coverage of 0.5-2.5 g / m ² , preferably 1.0-2.0 g / m ² .

The production of the forming lubricant according to the invention is explained in more detail below using examples.

Option A:

A mixture is made from 500 ml of water and 500 g of kaolin and / or sand-free, powdery clay. The pH of the mixture is adjusted to pH 11 using ethanolamine and the mixture is stirred at room temperature for at least 24 hours. After adding 250 g of powdered calcium stearate and approx. 0.25 g of surfactant mixture (anionic / nonionic), the mixture is kneaded and / or stirred for a further 24 hours at room temperature or at a temperature between 50-75 ° C. The surfactant mixture is a mixture of alkali soaps or / and alkyl sulfonates or / and ethoxylates of the structural formula RO (CH ₂ CH ₂ O) _x H (where R = C ₁₆ C ₁₈ fatty alcohol, x = 18-25).

Variation B:

The pH of a commercially available calcium stearate dispersion, which is stabilized by means of an anionic or nonionic surfactant mixture, is adjusted to ≥ 11 by adding ethanolamine and a sand-free, powdery clay is stirred into the calcium stearate dispersion. The dispersion is kneaded or stirred at room temperature or at a temperature between 50 and 75 ° C. for 12 hours.

In both variants, a surface-modified sheet silicate is formed that can be used to produce a forming lubricant, as in the examples explained below.

1st example:

An aqueous agent for forming a coating from the forming lubricant is formed, which has the following composition in% by weight: Surface-modified layered silicate (kaolin / clay) 1.5% Polyacrylate (as an aqueous dispersion) 1.0% Ethylene-Acryl-Co-Polymer (as an aqueous dispersion) 1.0% Calcium stearate 1.5%

The pH value is adjusted to 8.7 - 9.5 with the aid of ethanolamine, the total solids content or the working concentration is 5.0%. The coating agent is filled into a tub which is suitable for holding phosphated steel wire wound in a ring shape. The coating agent is heated to 50 ° C. A ring to be coated can have a bare metal or a phosphated surface. The bare metal surface can be cleaned using abrasive grains before the forming lubricant is applied. The steel wire is dipped into the coating agent, then removed again and excess coating agent is allowed to drip off. It is then dried in the ambient air or preferably in a dryer at preferably 100 100 ° C. The forming lubricant is now formed in the form of a coating on the steel wire.

The structure of a coating formed on a previously phosphated steel surface is shown schematically in cross section in Fig. 5 shown. Exfoliated and with stearate modified phyllosilicate platelets 1 are embedded in a polymer matrix 2 over the phosphate layer 3 of the steel 4.

In the case of coating a metallically bare, non-phosphated ring, the phosphate layer 3 is missing and the matrix 2 with the layered silicate platelets is arranged directly on the steel 4.

The forming lubricant formed on the wire has 30% by weight of sheet silicate, 30% by weight of calcium stearate, 20% by weight of polyacrylate and 20% by weight of ethylene-acrylic co-polymer.

2nd example:

The coating composition according to the invention of the 1st example is sprayed onto the ring of the 1st example by means of a shower in such a way that its surface is completely wetted. The excess coating agent is allowed to drain off. The workpieces or the rings are dried as in the 1st example.

3rd example:

An aqueous coating agent of the following composition in% by weight is formed, to which a polymeric micropowder is added. Surface-modified layered silicate (kaolin / clay) 3.0% Polyacrylate (as an aqueous dispersion) 2.0% Ethylene-Acryl-Co-Polymer (as an aqueous dispersion) 2.0% Calcium stearate (as an aqueous dispersion) 1.5% Polyamide (as micro powder) 1.5%

The pH value of the coating agent is adjusted to pH 8.7-9.5 with the aid of isobutylamine, the active concentration (total solids content) is 10.0%.
The coating agent is heated to 65 ° C. and a wire wound into rings is coated as in Example 1 or Example 2. The wire can be processed either immediately afterwards or at a later point in time on a multi-stage press. The forming lubricant according to this example is particularly suitable for multi-stage production for medium to high temperatures and for high pressing pressures.

The forming lubricant formed on the wire has 30% by weight of sheet silicate, 15% by weight of calcium stearate, 15% by weight of polyamide, 20% by weight of polyacrylate and 20% by weight of ethylene-acrylic co-polymer.

4th example:

A coating agent concentrate is formed with the following composition in% by weight, from which the coating agent according to the invention listed in the 1st example can be produced by dilution. Surface-modified layered silicate (kaolin / clay) 12.0% Polyacrylate (as an aqueous dispersion) 8.0% Polyethylene-Acryl-Co-Polymer (as an aqueous dispersion) 8.0% Calcium stearate (as an aqueous dispersion) 12.0%

The coating agent concentrate has a total solids content of 40%, a solids content of 30-50% having proven to be particularly favorable with regard to space-saving storage and good applicability. The pH of the coating concentrate is 10.5-11.0 and is adjusted using a mixture of ethanolamine and isobutylamine.
7 parts of water are added to each part of the coating concentrate. The solids content of 5.0% given for Example 1 is obtained in this way. The pH value is checked and, if necessary, corrected to pH 8.7-9.5 with the aid of ethanolamine. The coating and drying are carried out as in the 1st example.

The forming lubricant formed on the wire has 30% by weight of sheet silicate, 30% by weight of calcium stearate, 20% by weight of polyacrylate and 20% by weight of ethylene-acrylic co-polymer.

5. Example:

A coating agent concentrate with a solids content of 40% is prepared, to which a polymeric micropowder with a comparatively large molecular weight has also been added (data in% by weight). Surface-modified layered silicate (kaolin / clay) 16.0% Polyacrylate (as an aqueous dispersion) 5.0% Acrylic-styrene-co-polymer (as an aqueous dispersion) 5.0% Calcium stearate 8.0% UHMW polyethylene micro powder 6.0%

The pH of the coating concentrate is adjusted to 10.5-11.0 using a mixture of ethanolamine and isobutylamine. Other additives added are a preservative and a silane-based anti-setting with max. 0.5% (based on the concentrate).
4 parts of water are added to each part of the coating concentrate. The pH value is checked and adjusted to pH 8.7-9.5 with the aid of ethanolamine. The result is a solids content of 8% or the following composition in% by weight. Surface-modified layered silicate (kaolin / clay) 3.2% Polyacrylate (as an aqueous dispersion) 1.0% Acrylic-styrene-co-polymer (as an aqueous dispersion) 1.0% Calcium stearate 1.6% UHMW polyethylene (as micro powder) 1.2%

The coating and drying are carried out as described above for the 1st example, this composition being particularly well suited for preheating in an oven (Lau warm forming) and for forming processes in which particularly high pressure is used.

6. Example:

An aqueous coating agent of the following composition in% by weight is formed, to which a polymeric micropowder and a stearic acid amide have been added. Surface-modified layered silicate (kaolin / clay) 1.0% Polyacrylate (as an aqueous dispersion) 0.8% Polyethylene-Acryl-Co-Polymer (as an aqueous dispersion) 0.8% Calcium stearate 1.0% Distearyl ethylenediamide 1.8% UHMW polyethylene micro powder 0.6%

The solids content of the coating is 6%. The adjustment of the pH, coating and drying are carried out as described for the 1st example.
The coating has good sliding properties and enables good forming results. At low and medium temperatures, the required pressing pressures can be significantly reduced.

Characterization of the forming lubricant

1. a) The thermal stability and the melting behavior of the forming lubricant, the formation of which was described in the 1st example, were determined using a DSC measurement (Differential Scanning Calorimetry) checked. The measurement was carried out under a temperature gradient of 10 ° C./min. Accordingly, the coating was heated from 25 ° C. to 600 ° C. over a period of one hour (58 min).
   The DSC measurement, the result of which is in Fig. 4 showed the following:
   1. 1. The coating is stable up to 300 ° C. A slightly negative exotherm, which can be seen for a, is formed due to the glass transition temperature (T _g ) of one of the film formers used. A slightly positive heat tone is due to crosslinking reactions.
   2. 2. The melting points of the metal soap used (calcium stearate: approx. 140 - 160 ° C) and the polymeric film formers (acrylate and PE-acrylic copolymer: approx. 125 - 150 ° C) cannot be identified or are completely missing .
   3. 3. A heat change of> 300 ° C to approx. 400 ° C is due to the beginning of the decomposition of individual components of the forming lubricant with pronounced decomposition phenomena at approx. 500 - 550 ° C, which can be seen at b.
   4. 4. By the end of the measurement at 600 ° C, marked with c, the decomposition is not yet complete.
   5. 5. After the measurement, there remains a dark gray residue of pyrolysis products which, in addition to graphite, contain the platelets of the layered silicate.
   If the temperature rises further (> 600 ° C) only graphite and the layered silicate remain, with graphite taking on the main role of the lubricant during forming in this temperature range, since graphite develops its optimal lubricating properties in this temperature range. The thermal stability of the layered silicates contained exceeds 1000 ° C, which means that emergency or reserve lubrication is guaranteed in all cases even at these temperatures.
   As a result, the forming lubricant achieves a sufficient lubricating effect in all relevant temperature ranges.
2. b) Forming tests have shown that the coating according to the invention made from the forming lubricant according to Example 1, especially under cold forming conditions, that is to say at low temperatures, has excellent sliding properties and is markedly superior to commercially available products.

The behavior was measured on the basis of the deformation or a reduction of reference test bodies at room temperature. For this purpose, test specimens previously phosphated and provided with the coating according to the invention (material: 23MnB4, as-rolled) were reduced over a length of 100 mm from 18 mm to 15 mm. In addition to the forming lubricant according to the invention, oil / drawing grease, sodium stearate (reactive soap) and a commercially available polymer-wax forming lubricant were tested as comparative forming lubricants.
How Fig. 6 As can be seen, it has been shown that the forming forces measured when using the forming lubricant according to the invention according to the 1st example are about 30% lower than a drawing fat, are about 20% lower than those when using the sodium stearate, and by at least 10% lower than when using the polymer wax forming lubricant, which is commercially available.

Possible manufacturing processes extend to different applications in the area of cold and / or Lau-hot forming, or in particular to: Pulling from: Wire, tubes, hollow or solid profiles Rolling or deep drawing of: Tape and sheet metal Extrusion, upsetting of: Wire or rod sections to: Bolts, screws, nuts as well as more complex ones Components such as steering columns, gears, etc.

Claims (15)

Lubricant for metal forming, especially for forming steel,
characterized,
that the forming lubricant contains at least one mineral which has a layer structure and an agent for modifying the layer structure. Forming lubricant according to claim 1,
characterized,
that the mineral is swollen, delaminated and / or exfoliated by means of the modifying agent. Forming lubricant according to claim 1 or 2,
characterized,
that the modifying agent is or contains a surfactant, which preferably comprises a soap and / or an amine. Forming lubricant according to one of Claims 1 to 3,
characterized,
that the surfactant comprises a water-soluble soap, preferably an alkali or alkaline earth metal salt of a fatty acid, which preferably has a chain length of at least ten carbon atoms. Forming lubricant according to one of Claims 1 to 4,
characterized,
that the mineral is a sheet silicate, preferably kaolin or a mineral of the mica group. Forming lubricant according to one of Claims 1 to 5,
characterized by a polymeric film former, which is preferably present as a solution or as a dispersion, the polymer dispersion particularly preferably containing a polyethylene-acrylic copolymer to adjust the adhesion of the mineral to the metal and / or an acrylate to increase the hardness of the forming lubricant. Forming lubricant according to one of Claims 1 to 6,
characterized,
that the forming lubricant contains the following substances in the following proportions in% by weight: - Mineral: 2 to 70% by weight, preferably 10 to 50% by weight Modifying agent: 5 to 50% by weight, preferably 10 to 35% by weight - Film former: 10 to 60% by weight, preferably 15 to 50% by weight Forming lubricant according to claim 7,
characterized,
that the forming lubricant contains at least one polymer powder, preferably micropowder, with a proportion of 0 to 50% by weight, preferably 5 to 40% by weight. Body made of metal, in particular steel, which is coated with the forming lubricant according to one of Claims 1 to 8. Use of the forming lubricant according to one of Claims 1 to 8 for forming a body made of metal, in particular steel. Use according to claim 10,
characterized,
that the surface of the body is covered with an agent for forming a coating from the forming lubricant, preferably by dipping the body into the coating agent and / or spraying the body with the coating agent, and the forming lubricant preferably after application on the body a solid coating on the Body forms. Method for producing a forming lubricant, in particular the forming lubricant according to one of claims 1 to 8,
characterized,
that a mineral, which has a layer structure, is mixed with an agent for modifying its layer structure. Method according to claim 12,
characterized,
that the mineral is exfoliated by means of the modifying agent, preferably with mechanical, in particular shearing, processing, preferably by kneading and / or stirring. Method according to claim 12 or 13,
characterized,
that the mineral is a sheet silicate, preferably kaolin or a mineral of the mica group. Method according to one of Claims 12 to 14,
characterized,
that the modifying agent is or contains a surfactant, which preferably comprises a soap and / or an amine.

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