EP0224522A1 - Method for metal forming without cutting. - Google Patents

Abstract

Method for forming metals using polymers in the form of homo- and copolymers of 1-olefins, of the oxidants of these homo- or copolymers, or of saponification or esterification products of these oxidants as lubricants. The polymers are solid and preferably have melting points greater than 100oC and melting viscosities greater than 100 mPa.s at 170oC, the acid number of the oxidants being greater than 5. These lubricants are used in solid form pure or else in the form of compositions in which they are mixed with additives and / or suspending agents, dispersants or solvents known per se.

Description

 Process for non-cutting forming of metals and lubricant compositions for this process

Metallic molded parts are often produced by non-cutting shaping, the workpiece being given the desired shape without or with preheating by the action of high external forces. Types of non-cutting metal forming are e.g. wire, bar, tube, profile, deep drawing and ironing, as well as cold extrusion, cold upsetting, pilgrimage, cold and hot rolling or forging.

It is known to use lubricants in non-cutting metal forming to improve results by reducing the friction between the workpiece and the mold. Mineral oils with or without high-pressure additives, animal and vegetable oils, fats and waxes and metal soaps based on fatty acids, in particular based on stearic acid, are used as lubricants.

When using the known lubricants, the non-cutting shaping of metals leads to unsatisfactory results in many respects. The desired high degrees of forming and forming speeds are often not achieved. The desired dimensional accuracy and surface quality of the workpieces as well as a sufficiently long service life of the tools are also not achieved as a result of cold welding and drawing groove formation. In addition, in order to achieve a noticeable lubricating effect, conventional lubricants often require chlorine, sulfur and phosphorus-containing additives, which discolor or corrode the metal surfaces and pollute the environment. The disadvantages mentioned occur in particular in more difficult cases of metal forming, for example in wire drawing, tube drawing, profile drawing, cold extrusion or die forging of steels, especially of higher-alloy steels. In ^'schwie¬ complex cases a metal forming using conventional lubricant is usually only possible if applied layers before forming on the workpiece surface additional separation or Schmiermittelträger¬ at all. The application of the separating or lubricant carrier layers generally has to be carried out in a complex manner chemically by reaction of mostly certain salt solutions with the workpiece surface with the formation of corresponding coatings on the workpiece surface. follow (eg "phosphating", "oxalating"). A physical application by letting salt solutions dry on the surface of the workpiece is only sufficient in less difficult cases, although the physical application often delivers completely inadequate results. The separating layers also often impair the surface quality of the workpieces and require a great deal of effort to remove them before the workpieces are further processed, and wastewater that requires reprocessing also occurs. In addition, the effect of the separating or carrier layers in difficult cases of metal forming is often insufficient to achieve acceptable forming results.

The invention has for its object to simplify the process and improve the results in the non-cutting forming of metals.

This object is achieved according to the invention in that the metal shaping is carried out using a lubricant which is optionally used in conjunction with separating and / or lubricant carrier layers, characterized in that the lubricant is selected from a group consisting of Polymers of 1-olefins, oxidation products of such polymers as well as esterification and saponification products of the oxidation products mentioned and mixtures of the substances mentioned, this lubricant being used in pure form or in a mixture with other, known mixture components of lubricants.

The advantages achieved by the invention compared to known methods consist in particular in that higher degrees of deformation and higher rates of deformation, higher dimensional accuracy and better surface quality of the workpieces as well as longer tool life are achieved. The reshaping can also be carried out with significantly reduced energy expenditure and reduced environmental impact. In addition, in many cases the application of additional separating or lubricant carrier layers can be simplified or eliminated entirely.

Among the polymers of 1-olefins used as lubricants in the process according to the invention are homopolymers of C 1 -C 4. "-Alkenes with a terminal double bond, preferably the C_-C. --Alkenes, especially ethene, propene, 1-butene, 3-methyl-1-butene, 1-pentene, 1-hexene and 1-octene, as well as copolymers of these 1-olefins with one another, and also copolymers of these 1-olefins with up to 50, preferably up to 30, in particular up to 20, but above all up to 15% by weight of oxygen-containing 1-olefins.

Polymers are, for example, the commercially available polyethylenes, polypropylenes, polybutylenes, etc., as are obtained by known processes, for example by high, medium or low pressure polymerization. Copolymers of 1-olefins contain at least two different 1-olefin building blocks at the same time. These include, for example, polyethylenes with a content of up to 30, preferably up to 20, in particular up to 10% by weight of other 1-olefins such as propene, 1-butene, etc. Also the copolymers which have recently become available under the name LLDPE of ethylene with higher 1-olefins are to be expected here. Copolymers of 1-olefins with oxygen-containing olefins are, for example, copolymers of ethylene with vinyl esters of carboxylic acids such as vinyl acetate or vinyl propionate, and also with vinyl ethers or 1,2-ethylenically unsaturated carboxylic acids and their derivatives such as acrylic acid, methacrylic acid, ethacrylic acid, crotonic acid , Fumaric acid, maleic acid, maleic anhydride, itaconic acid, mesaconic acid or the esters of these acids. The polymers used are not subject to any restrictions with regard to their structure and molecular size. For example, polymers with high or low degrees of branching can be used. It is also possible to use low molecular weight wax-like polymers with molecular weights between 200 and 20,000 (melt viscosities approx. 5 to 100,000 mPa s at 160 ° C) and higher molecular weight, plastic-like polymers with molecular weights between 20,000 and 5,000,000 (melt indexes MFI 190/2 , 16 approx. 1000 to 0.001 g / 10 min.). The more low molecular weight polymers with molecular weights between 200 and 100,000, preferably between 500 and 30,000, advantageously between 800 and 20,000, in particular between 1000 and 15,000, but especially between 3,000 and 10,000, are particularly suitable at the same time high melting points (> 100, preferably M IO, especially> 115, especially> 120 ° C), high melt viscosities (> 100, preferably> 500, especially> 1000, especially M0000 mPa s at 170 ° C), and high Crystallinities (> 10, preferably> 30, in particular> 0, especially> 50%) have excellent lubricating properties for the shaping of metals, in particular, for example, during deep drawing or ironing. Copolymers which are also composed of oxygen-containing monomer building blocks are hardly crystalline and have lower melting points, but they have even more due to the polarity given by you - H - ^"

improved lubrication properties.

Oxidation products of the polymers are to be understood to mean products which are generally formed by air oxidation of the polymers. They can be produced by known processes, e.g. from low molecular weight polymers by mixing the polymers in the molten state with air or particularly advantageously from higher molecular weight polymers by treating the polymers at elevated temperatures with air in the solid state or in the molten state, finely divided in an inert dispersion medium. The oxidates have acid numbers between 5 and 150, preferably between 10 and 70, advantageously between 15 and 50, in particular between. 20 and Ψ5 mg KOH / g, and melt viscosities between 5 and 100,000, preferably between 50 and 50,000, advantageously between 100 and 30,000, in particular between 500 and 20,000, especially between 1,000 and 15,000 mPa s at 160 ° C. Their melting points are above 90, preferably above 100, in particular above 110, especially above 115 ° C. The melting points of the oxidates of copolymers are rather in the lower of the ranges given. In particular, oxidates with a high content of dicarboxylic acids (> 10, preferably> 20, advantageously> 0, in particular> 60, in particular> 80% by weight), such as those formed during the oxidation of higher molecular weight polymers (molecular weights> 5000, preferably M0000), and oxidates with comparatively high melting points, high melt viscosities, high crystallinity and high polarities have excellent properties as lubricants in metal forming even in difficult cases.

The esterification and / or saponification products of the oxidates are obtained by partially or completely esterifying or saponifying or oxidizing the oxidates with mono- or polyhydric alcohols or with mono- to trivalent metal ions or with ammonium ions and then partially esterifying and then the free or partially saponified free carboxyl groups.

The following are mainly considered as esterification components: monohydric C 1 -C ₂₂ -alkanols, dihydric alcohols such as 1,2-ethanediol, 1,2-propanediol, 1-butanediol or ether alcohols such as diethylene glycol and higher polyalkylene glycols, and also higher-quality ones Alcohols such as trimethylolpropane or pentaerythritol, optionally in a mixture with one another. Li ⁺ , Na, K, Mg, Ca ⁺ , Ba ⁺ , Zn ⁺ , Pb ⁺ , Al ⁺ , NH are generally used as saponification components. and ammonium ions of organic amines in the form of their hydroxides, carbonates, acetates, stearates and other salts, optionally in a mixture with one another. The esterification or saponification is carried out generally in a known manner by stirring the molten oxides with the esterification or saponification components, if appropriate in the presence of suitable catalysts, to the desired degree of esterification or saponification. The esterification or saponification can also be carried out by intimately mixing the solid powdered, suspended, dispersed or dissolved oxidates with the solid, suspended, dispersed or dissolved reaction partners. When using suspended, dispersed or dissolved reactants, the product formed can be used for the process according to the invention in moist, optionally in suspended or dispersed form, or after drying in powder form. In another embodiment, the saponification products can be prepared by stirring the oxidation products or the partially pre-esterified oxidation products in the molten state, optionally with the addition of emulsifiers, with the saponification component dissolved or dispersed in water. This gives rise to aqueous solutions or dispersions of the saponification products which, as such, can also be used advantageously for the process according to the invention.

The saponification products, less the esterification products, generally have higher melting points and melt viscosities than the underlying oxidates. In the case of the saponification products, the melting points are above 100, preferably above 110, in particular above 120, advantageously above 130, especially above 10 ° C., the melt viscosities above 100, preferably above 500, in particular above 1000, advantageously above 3000, especially over 5000 mPa s at 180 ° C. The lower ranges specified apply to the esterification products. The esterification and / or saponification products have, in certain respects, further optimized lubrication properties compared to the oxidates due to a specially given combination of comparatively high melting points, high melt viscosities, high crystallinities as well as a special balance between polar and non-polar fractions. The saponification products in particular have proven to be particularly advantageous, as they form lubricating films with particularly excellent sliding, adhesive and separating properties, as well as increased tear resistance, and maintain these properties even under extreme pressure and temperature loads. The esterified and especially the saponified oxidation products are therefore particularly suitable for use as a lubricant in difficult metal forming operations, for example in tube drawing, profile drawing, wire drawing, pilgrimage, rolling, cold extrusion, upsetting or Forging, preferably in the case of difficult-to-deform metals such as steels, especially high-alloy steels, also stainless steels, for example acid-proof chrome and chrome-nickel steels.

The polymers, their oxidates or the esterification and / or saponification products of the oxidates can be used for the process according to the invention alone, in a mixture with one another or in a mixture with other substances as lubricants for the shaping of metals. Other mixture components which may be used are, for example, mineral oils, vegetable or animal oils, fats, waxes or resins and also fatty acids, fatty alcohols, beefs, synthetic resins or oils, preferably polyalkylene glycols and their derivatives, very low molecular weight polyethylenes or esters. In addition, customary additives such as high-pressure agents (for example chlorine-, sulfur- or phosphorus-containing substances), pigments and fillers (for example lime, chalk, talc, borax, soda, mica, graphite, molybdenum disulfide) can be added to the lubricants in the process according to the invention. Tungsten disulfide, boron nitride, 3od, glass) emulsifiers, surfactants, wetting agents, thickeners (eg montmorillonite), adhesion improvers, binders, corrosion inhibitors and antioxidants are added to round off the properties.

The polymers, their oxidates or the esterification and / or saponification products of the oxidates can be used for the process according to the invention as lubricants in the form of powders, suspensions, dispersions or solutions. In powder form, the lubricants have good free-flowing properties which are advantageous for use and which, in contrast to conventional lubricants, are retained even at higher atmospheric humidity. In the case of suspensions, dispersions and solutions, water, mineral oils, natural or synthetic oils and chlorinated hydrocarbons are preferably used, if appropriate in a mixture with one another, as suspension, dispersion or solvent. Polyalkylene glycols have proven to be particularly advantageous due to their solution-mediating action both in the preparation of the lubricants according to the invention and in their removal from the metal surface. The suspensions and dispersions can be prepared with the addition of known ionic or nonionic emulsifiers and wetting agents. The lubricants are applied to the workpieces by known methods, for example by powdering, brushing, dipping, flooding, spraying or in a continuous process, if appropriate at elevated temperatures and while drying the workpiece. The method according to the invention can advantageously be used in all types of non-cutting shaping of metals, for example in wire, bar, tube, profile, deep, stretching and ironing, or in cold extrusion, cold upsetting, stamping, reducing, Pilgrimage, rolling, cutting and forging. The method is not limited to the cold forming of metals, but includes the warm and hot forming of metals, for example hot rolling, die forging or extrusion, in particular also for non-ferrous metals. The advantages of the method of operation according to the invention are particularly evident in the more difficult forming processes, for example in tube drawing, profile drawing, wire drawing, tube pilgrimage, rolling, cold extrusion, upsetting or forging.

The method according to the invention is advantageously suitable for the forming of all common metallic materials, e.g. of low-carbon or high-carbon steels, non-alloyed, low-alloyed or high-alloyed steels, stainless steels, galvanized, copper-plated or other metallic coated steels, non-ferrous metals, such as magnesium, aluminum, copper, brass, bronze, zinc, lead, nickel, titanium, Zircon, tungsten and their alloys. In particular, the advantages of the method according to the invention come into play when shaping metals which are difficult to form, e.g. for austenitic and ferritic steels, especially for high-alloy, especially stainless steels, preferably stainless steels, e.g. acid-resistant chrome or chrome-nickel steels, also for galvanized steels. Because of the excellent lubricating effect of the lubricants used, in the method according to the invention, in general, several successive reshapings are possible without the need for relubrication.

Because of the excellent sliding, adhesive, and separating capacity as well as the excellent film strength of the lubricants used, the additional application of a separating or lubricant carrier layer to the workpieces prior to the forming can generally be omitted in the process according to the invention even in the case of difficult forming processes. This results in reduced costs, reduced wastewater problems and improved surface qualities of the end products compared to known forming processes. In the method according to the invention, however, the lubricants used can also be used in combination with known separating or lubricant carrier layers. As a result, additional advantages can be achieved in some cases in the case of particularly difficult metal forming the, for example, when drawing complex shaped profiles from high-grade steel or during cold extrusion. In general, the simpler physical application of the separating or lubricant carrier layers by allowing appropriate solutions or dispersions to dry on the workpiece surface (for example liming, boraxing) is sufficient to achieve excellent results. The more complex chemical application of the separating or lubricant carrier layers by chemical reaction of corresponding solutions or dispersions with the workpiece surface (eg phosphating, oxalation, copper plating) brings additional advantages only in extreme cases.

Because of the excellent lubricating effect of the lubricants used, the method according to the invention generally achieves higher degrees of deformation and higher forming speeds, higher dimensional accuracies and better surface qualities of the workpieces and longer tool life compared to known methods. Cold welding with the associated impairment of the workpiece surfaces by drawing grooves and impairment of the tool life by welding do not occur or only to a greatly reduced extent. The method according to the invention further reduces the energy consumption and the amount of waste water.

The process according to the invention is also distinguished by the fact that lubricants are used which do not contain any substances which are harmful to health and which do not contain any substances such as chlorine, sulfur, phosphorus or boron, by virtue of which the properties of the processed materials, for example as a result of discoloration and corrosion , are adversely affected and the environment is heavily polluted. The lubricants do not have a corrosive effect on metals, but have a protective effect against corrosion. After the shaping, they can be removed from the metal surface without residue, using conventional means and methods, for example by means of conventional alkaline, neutral or acidic cleaners or else by means of organic solvents. A special advantage of the method according to the invention is also that the lubricants used can also be removed from the workpiece surface by evaporation without residue by simple vacuum heat treatment, for example in the preliminary stage of post-heat treatment of the workpiece. Examples 1 to 9

Cups are produced from stainless steel sheet using the deep-drawing process, using the polymers listed in the following table as lubricants.

The polymers are dissolved in xylene and applied with a brush to the sheet in a thin layer. After the solvent has evaporated, cups are drawn from the metal sheets. Bowls with high dimensional accuracy and high surface quality (low roughness, high gloss and light color) are obtained, examples 3, 8 and 9 leading to the relatively best results. When conventional high-pressure agents are added, further improved results are obtained.

The same deep-drawing tests using conventional drawing oils as lubricants require significantly higher stamping forces and deliver products with a significantly lower surface quality. Examples 10 to 17

Bare steel wire with a carbon content of 0.85% is drawn by using the oxidation products of polymers listed in the following table as lubricants.

* Mp = melting point, SZ = acid number, VZ = saponification number, SV = melt viscosity (mPas at 140 ° C)

The lubricants are used in the solid state by running the wire through the powdered lubricant in front of the tool. The wire is reduced in diameter to 1/4 of the original value in 15 passes. The forming results given in the table are achieved.

If the pull test is carried out with conventional lubricants, e.g. based on fatty acid soap, so consistently lower drawing speeds and less good wire surfaces are obtained. In addition, conventional die lubricants show higher die wear.

Examples 18 to 25

Stainless steel wire is drawn by using aqueous alkaline dispersions from oxidation products of polymers as lubricants.

The same oxidation products of polymers as in Examples 10 to 17 are assumed. The oxidation products are first converted into aqueous alkaline dispersions by, in the molten state, together with the amounts of potassium, calculated according to the acid number. hydroxide and together with emulsifiers (5% by weight ethoxylated fatty alcohol, based on oxidate) are dispersed in hot water. Dispersions with the properties listed in the following table are obtained.

The stainless steel wire (Z 2 CN 18-10) is coated with the lubricant dispersions by immersion and subsequent drying, and deformed in 15 passes from the initial diameter of 6.5 mm to the final diameter of 1.2 mm. The forming results given in the table are achieved. The results are consistently significantly better than those obtained under the same conditions with conventional lubricants. With conventional lubricants, the wire becomes scarred and partially breaks.

Similar results are achieved with the lubricants listed above when they are used to pull stainless steel pipes. With conventional lubricants, approximately equally good results can only be achieved if highly polluting and corrosive lubricants based on chlorinated paraffin are used or if the pipes are first pretreated by oxalation and then treated with special fatty acid soaps.

If the lubricants according to the invention are used with the addition of small amounts of polyalkylene glycols, they can be removed particularly easily from the metal surface after the reshaping. Examples 26 to 33

Lubricants are produced by converting the oxidation products of polymers used in Examples 10 to 17 into saponification products. For this purpose, the pulverized oxidation products are saponified by mixing with the equivalent amount of potassium hydroxide solution. The test products listed in the following table are obtained.

Four symmetrically arranged grooves, each 5 mm deep and 5 mm wide, are drawn into the round rods made of austenitic chrome-nickel steel with a diameter of 30 mm, the saponification products of polymers listed in the table above being used as lubricants. The forming results given in the table are achieved. The workpiece surface still contains so much lubricant that further traction is possible without relubrication.

If the drawing tests are carried out with conventional lubricants, for example based on fatty acid soaps, the best results can only be achieved if a separating or lubricant carrier layer based on iron oxalate is chemically treated on the workpieces with appropriate solutions is brought up. Examples 34 to 41

The lubricants from Examples 26 to 33 are each together with

30% by mass of polyethylene glycol, based on the lubricant, in one

2 paraffinic mineral oil with a viscosity of 168 mm / s (20 ° C) at a temperature of 130 ° C dissolved. In this way, 8 lubricants in oil phase are obtained, which are used to pull steel pipes of material quality St 35. The following results are achieved:

Comparable good results can only be achieved with conventional lubricants if a separating or carrier layer based on zinc phosphate is applied to the pipes in a complex manner before the lubricant is added.

Examples 42 to 49

The lubricants from Examples 26 to 33 are each suspended in a liquid polyglycol which is composed of ethylene oxide and propylene oxide units. The liquid lubricants obtained in this way are used to pull stainless steel pipes (= Examples 42 to 49). With low drawing forces, high degrees of deformation (up to 51%) and excellent surface qualities are achieved. The same quality gradation as in Examples 34 to 41 results within the series of tests. The lubricants are also distinguished in particular by being easy to remove from the metal surface after the forming has taken place. _ _

Example 50

A cylindrical steel body of material quality St 35 is converted into a sleeve by cold extrusion. An aqueous dispersion of a polyethylene oxidate with an acid number of 26, a saponification number of 40, a melting point of 118 ° C., a dicarboxylic acid content of 84% and a melt viscosity of 1350 mPas at 160 ° C. is used as the lubricant. The forming takes place with a comparatively low stamping force and minimal ejection force and leads to a dimensionally accurate molded part with a high surface quality. If a lubricant carrier layer based on zinc phosphate is applied to the steel body before the lubricant is added, only slightly better forming results are achieved.

With a conventional lubricant based on fatty acid soap, the cold extrusion process can only be carried out if the steel body has previously been provided with a lubricant carrier layer based on zinc phosphate.

Example 51 A polyethylene oxidate with the acid number 68, the saponification number 99, the dropping point 110 ° C., the dicarboxylic acid content of 93% and the melt viscosity 150 mPas at 140 ° C. is saponified by stirring the oxidate melt with half the equivalent amount of calcium hydroxide. A saponification product with an acid number of 32, a saponification number of 72, a dropping point of 107 ° C. and a melt viscosity of 1500 mPa · s at 140 ° C. is obtained. The saponification product is used in powder form as a lubricant when pulling asymmetrical edges into a square stainless steel rod. A dimensionally accurate profile with sharp edges and a bright surface is obtained.

The experiment is repeated, a separating or lubricant carrier layer based on iron oxalate being applied beforehand to the workpiece surface by chemical treatment with an appropriate solution. Compared to the experiment without a separating or carrier layer, gradually improved conversion results are achieved.

When using conventional lubricants based on fatty acids, pulling the profile without applying a separating or carrier shift not possible. After a separating or carrier layer has been applied, drawing is possible in principle, but significantly worse results are achieved than in the method according to the invention, for example, severe scoring and high tool wear occur.

Example 52

A polyethylene oxidate with the acid number 68, the saponification number 99, the dropping point 110 ° C., the melt viscosity 150 mPa s at 140 ° C. and the molecular weight 1700 is esterified with the corresponding amount of stearyl alcohol to an acid number of 15. A product is obtained with the acid number 15, the saponification number 120, the dropping point 104 ° C. and the melt viscosity 250 mPa s at 140 ° C., which is used in powder form as a lubricant for cold-forming a square rod made of stainless steel into a hexagonal rod by drawing. An end product with excellent dimensional accuracy and high surface quality is obtained.

The experiment is repeated with the difference that the polyethylene oxidate is first esterified with the appropriate amount of stearyl alcohol to an acid number of 30 and then saponified with calcium hydroxide to an acid number of 15. A product with an acid number of 15, a saponification number of 105, a dropping point of 108 ° C. and a melt viscosity of 1700 mPas at 140 ° C. is obtained. When the product is subsequently used as a lubricant for cold-forming the square rod into the hexagonal rod, compared to the above, even better results are achieved in that the forming can be carried out with less effort. Equally good results are achieved if the esterified lubricant used above is used with the addition of fillers (talc, lime).

Claims

Claims

1. A process for the non-cutting shaping of metals using a lubricant, which is optionally used in conjunction with separating and / or lubricant carrier layers, characterized in that the lubricant is selected from a group consisting of polymers of 1-olefins, Oxidation products of such polymers as well as esterification and saponification products of the oxidation products mentioned and mixtures of the substances mentioned, this lubricant being used in pure form or in a mixture with other, known mixture components of lubricants.

2. The method according to claim 1, characterized in that the polymers are selected from a group consisting of

- Homopolymers of C_-C. g-alkenes with terminal double bond, preferably C 1 -C ₇ -alkenes and in particular of ethene, propene, 1-butene, 3-methyl-1-butene, 1-pentene, 1-hexene and 1-octene,

Copolymers of such 1-olefins with one another and copolymers of such 1-olefins with up to 50, preferably up to 30, in particular up to 20 and above all up to 15% by weight of oxygen-containing 1-olefins,

and that the oxidation products are the oxidation products of these polymers and the esterification and saponification products are the esterification and saponification products of such oxidation products.

3. Process according to claims 1 and 2, characterized in that the polymers have molecular weights between 200 and 100,000, in particular between 500 and 30,000, advantageously between 800 and 20,000, preferably between 1,000 and 15,000 and particularly preferably between 3,000 and 10th 000, melting points above 100 ° C., preferably above 110 ° C., in particular above 115 ° C. and above all above 120 ° C., melting viscosities at 170 ° C. above 100 mPa s, preferably above 500 mPa s, in particular above 1000 mPa s and especially above 10,000 mPa s, and degrees of crystallization above 10%, preferably above 30%, in particular above 40% and above all above 50%.

4. Process according to claims 1 and 2, characterized in that the oxidation products acid numbers between 5 and 150, preferably between 10 and 70, advantageously between 15 and 50 and in particular between 20 and 45 mg KOH / g, melt viscosities between 5 and 100,000 , preferably between 50 and 50,000, advantageously between 100 and 30,000, in particular between 500 and 20,000 and especially between 1000 and 15,000 mPa s at 160 ° C., melting points above 90, preferably above 100, in particular above 110 and above all above 115 ° C, and a dicarboxylic acid content above 10, preferably above 20, advantageously above 40, in particular above 60, especially above 80% by weight.

5. The method according to any one of claims 1 to 4, characterized in that the esterification products of the oxidates are esterified with mono- or polyhydric alcohols and the saponification products are saponification products with mono- to trivalent metal ions or ammonium ions.

6. The method according to any one of claims 1 to 5, characterized in that the esterification and saponification products of the oxidation products by mixing the pulverized solid, suspended, dispersed or dissolved oxidation products with the solid, suspended, dispersed or dissolved esterification components or saponification components in solid, suspended, dispersed or dissolved form are prepared and used in solid, suspended, dispersed or dissolved form.

7. The method according to any one of claims 1 to 6, characterized in that the esterification and saponification products melting points above 100 ° C, preferably above 110 ° C, in particular above 120 ° C, advantageously above 130 ° C, and above all 140 C, and melt viscosities at 180 ° C over 100 mPa s, preferably over 500 mPa s, in particular over 1000 mPa s, advantageously over 3000 mPa s and especially over 5000 mPa s.

8. The method according to claim 1, characterized in that the lubricant is used in a mixture with mixture components which are selected from the group consisting of mineral oils, vegetable or animal oils, fats, waxes or resins, fatty acids, fatty alcohols , Soaps, synthetic resins or oils, polyalkylene glycols or their derivatives, high-pressure active ingredients, pigments, fillers, emulsifiers, surfactants, wetting agents agents, thickeners, adhesion promoters, binders, corrosion inhibitors and antioxidants, and also mixtures of two or more of these mixture components.

9. The method according to claim 1, characterized in that the lubricant is used in admixture with a suspension, dispersion or solvent which is selected from a group consisting of water, mineral oils, natural or synthetic oils , Polyalkylene glycols or chlorinated hydrocarbons, and mixtures of two or more of these agents.

10. Lubricant composition for use in a method according to claim 1, characterized in that it contains an actual lubricant which is selected from the group consisting of polymers of 1-olefins, oxidation products of such polymers, Vereste¬ Products of the oxidation products and saponification products of the oxidation products as well as mixtures of two or more of these substances, this lubricant being solid, suspended, dispersed or dissolved in a suspension, dispersion or solvent, and the composition optionally including others known mixture components of lubricant compositions can contain.