DE1180131B - Process for the production of oxygen-containing wax raw materials by oxidation of polyolefin waxes - Google Patents

Description

Process for the production of oxygen-containing wax raw materials Oxidation of polyolefin waxes In addition to the classic wax raw materials beeswax, Carnauba wax, candelilla wax, raw montan wax, etc. as well as those made from the latter by chromic acid oxidation and subsequent esterification with mono- or polyvalent ones Wax raw materials obtained from alcohols and possibly subsequent liming occur recently new raw materials based on natural or synthetic hydrocarbons.

Products have gained a certain importance here as they are made from microcrystalline hydrocarbons or Fischer-Tropsch paraffins by introduction of oxygen, e.g. B. by the already known oxidation of microcrystalline Waxes or Fischer-Tropsch paraffins with oxygen or gases containing oxygen wins, with as oxygen-containing gases in addition to air and air-oxygen mixtures z. B. also the nitrogen oxides are to be considered.

Another process is used to produce wax raw materials that the paraffin hydrocarbons mentioned are chlorinated, dehydrochlorinated, on the olefins obtained catalytically add water gas to the obtained Aldehydes are then hydrogenated to alcohols and these are oxidized by means of alkali melt or converted into carboxylic acids with chromic acid. Be according to a different procedure the chlorinated and dehydrochlorinated hydrocarbons directly by oxidation converted into carboxylic acids with chromic acid. Those made by this process Wax raw materials contain the introduced oxygen in the form of carboxyl groups, as in the case of the products made via chlorination and dehydrochlorination or additionally in the form of ester, hydroxyl and carbonyl groups, as in the case of oxidation with oxygen or gases containing oxygen. It turned out, however, that the after The above-mentioned classic wax raw materials produced by this process To replace wax raw materials only partially and often only in mixtures with them are able to give them some properties that are important for the wax area are inferior. It is also the manufacture of oxidation products from polyolefins z. B. by treatment with oxygen or oxygen-containing gases, optionally in the presence of ozone, already known. However, this is either about the oxidation of high molecular weight, plastic-like polyolefins, some of which high-molecular, plastic-like products with modified properties, partly higher molecular acids can be obtained, or especially the oxidation of higher melting acids Polyolefins, but waxes with high melting points unsuitable for processing can be obtained.

It has already been described, air-oxidized polyethylene, possibly mixed with air-oxidized synthetic paraffins, together with raw montan wax to subject to chromic acid bleaching. The air oxidation of mixtures was also used microcrystalline waxes with polyolefins have already been described, but have not been used in any Case so far given more detailed information on how to generally low molecular weight waxy Polyolefins thereby treatment with oxygen or oxygen-containing gases Convert into generally usable wax raw materials with special properties can (see US Pat. No. 2,471,102).

While the air oxidation of natural or synthetic paraffinic hydrocarbons poses no particular difficulties, it is not with the polyolefin waxes so easy to do. So when blowing the polyolefin wax with air in the when blowing normal paraffinic hydrocarbons, the usual temperature range of about 120 to 160 "C the oxidation only after a much longer induction period and then runs considerably more slowly than with the paraffinic hydrocarbons. Another in the air oxidation of the common paraffinic hydrocarbons in the generally not appearing in the production of oxygen-containing ones However, polyolefin waxes have a very disruptive effect from the Occurrence of viscosity increases in the course of the oxidation. That affects, for example so that at reaction temperatures above 130 ° C the viscosity of the oxidation products gradually or very suddenly, depending on the conditions, and even at a proportionate rate low acid numbers rise to high values until the products finally gel, d. H. become infusible and insoluble. This undesirable effect is caused by the heavy metal compounds usually used as catalysts in paraffin oxidation, z. B. the heavy metal stearates, still favored.

The invention relates to a process for the production of oxygen-containing Wax raw materials by oxidation of polyolefin waxes with a molecular weight from 1000 to 8000 and a melting point below 130 ° C with molecular oxygen or gases containing these in the liquid phase at temperatures above the melting point the polyolefin waxes, optionally in the presence of ozone or peroxides as oxidation catalysts, characterized in that polyolefin waxes at temperatures above the Melting point of the polyolefin waxes and not more than 130 ° C, up to an acid number oxidized by not more than 100, taking into account the viscosity of the reaction mixture by regulating the oxygen supply, which is at least 2 liters / hour / kg wax, holds at a value that does not exceed the viscosity value of the polyolefin waxes used is at the same temperature.

For the purposes of this invention, polyolefin waxes include products understand how to make them by high pressure or preferably low pressure polymerization of olefins, such as ethylene, propylene and / or butylene, preferably ethylene, or those produced accordingly by catalytic or thermal degradation high molecular weight plastic-like polyolefins wins, insofar as they are substances of represent waxy character and a molecular weight of 1000 to 8000 and have a melting point below 130 ° C. Such waxy polyolefins continue Called polyolefin waxes, they differ from the higher molecular weight polyolefins with plastic character, among other things due to their low melt viscosity. the Viscosities of such products are generally in the range between 50 cP as lower limit and 30,000 cP, preferably 15,000 cP, as the upper limit. The molecular weights such polyolefin waxes are in the range between 1000 and 8000. The melting points lie z. B. between 100 and below 130 "C, for example with high-pressure polyethylene waxes in the range from 100 to 1100 C, preferably 104 to 107 "C, for low-pressure polyethylene grow in the range from 110 to below 130.degree. C., preferably 115 to 125.degree. C., however also be lower or below 130 ° C. The densities of the polyolefin waxes have values in the range from 0.90 to 0.98, e.g. B. the high pressure polyethylene waxes at 0.92, the low-pressure polyethylene waxes at 0.94 to 0.96.

The influence of the reaction temperature on the oxidation of polyolefin waxes show A b b for two typical representatives of this product class. 1 and 2, and although A b b. 1 for a high pressure polyethylene wax of approximate molecular weight 3000 with a viscosity of about 1200 cP, A b b. 2 for a low pressure polyethylene wax with an initial viscosity of about 100 cP. As you can see, the viscosity becomes of High pressure polyethylene wax relatively quickly at higher reaction temperatures is greatly reduced and already rises to high again at acid numbers between 20 and 35 Values. At a lower reaction temperature, on the other hand, the viscosity drops significantly slower and to lower values, and the increase is also slower. At an oxidation temperature of 120 to 1300C, on the other hand, there are also acid numbers far above 100 no more increase in viscosity can be detected. The conditions are analogous in the case of the low-pressure polyethylene wax, in which the low initial viscosity at higher reaction temperatures relatively quickly and even at an acid number of about 10 increases, while at a low reaction temperature the viscosity practically remains constant up to high acid numbers. So you can see that products with low Melt viscosities can be obtained even with a high degree of oxidation if the Oxidation at sufficiently low temperatures, namely at temperatures not above 1300C performs.

The use of ozone or peroxides as oxidation catalysts is, as is generally the case with blowing paraffinic hydrocarbons, also here for Acceleration of the oxidation process is very useful. As peroxides are z. B. Benzoyl peroxide, lauroyl peroxide and di-tert-butyl peroxide are called.

These oxidation catalysts do not promote the increase in viscosity. So you can in the presence of such catalysts at 120 to 130 ° C with satisfactory Reaction acceleration work.

The influence of the oxygen supply affects the viscosity curve during the oxidation of a polyolefin wax in such a way that for example the melt viscosity of a high pressure polyethylene wax with an initial value of about 1200 cP (120 ° C) with high oxygen supply is lowered during it would increase with low oxygen supply. With a low-pressure polyethylene With a melt viscosity of around 100 cP (140 ° C), on the other hand, there is a high oxygen supply the per se low value is at most only slightly reduced, with a low oxygen supply however, the viscosity would also increase. The influence of the oxygen supply is naturally very dependent on the test conditions. For example affects in the above-mentioned high pressure polyethylene wax, the stirring speed to the The rate of oxygen uptake in the wax when working without pressure is as follows from: maximum oxygen uptake in wax a) simple passage of oxygen through the wax without stirring ........................... 0.15% / h b) introduction of Oxygen with normal stirring ............ 0.2 to 0.3% / h c) Introduction of oxygen with vigorous stirring, formation of a foam ............... 0.5 to 0.60 / h under Condition c) when a foam phase is formed, there is a reduction in viscosity achieved when the oxygen supply is greater than 2 l / h / kg wax, against it would an increase in viscosity occur if the oxygen supply is less than that specified Value. An increase in temperature or working under increased pressure result in a higher one Oxidation rate and therefore require a higher supply of oxygen. Is working If the stirring conditions are less favorable, this can lead to a reduction in viscosity Increase the required oxygen supply to a multiple of the specified values.

Taking into account the options explained in detail you have the power to manufacture products with a wide variety of properties.

Oxygen-containing products made from high pressure polyethylene wax having an acid number of about 15 and a melt viscosity of about 10,000 cP (120 ° C) have the property of being processed in certain shoe creams and polishing compounds, To form pastes with a particularly good glossy surface.

The oxidation of polyolefin waxes with molecular oxygen or oxygen-containing gases according to the invention are obtained depending on the products the chosen working conditions white to light yellow or dark yellow to brown. So are z. B. by blowing with molecular oxygen or oxygen-containing gases products obtained at 120 to 130 ° C up to medium acid numbers white to light yellow, while at higher acid numbers the products are increasingly darker in color. the The hardness of the oxygen-containing polyolefin waxes obtained depends on the starting material, very different depending on the reaction temperature and the acid number achieved. To the Example have the products made from low-pressure polyethylene wax with acid numbers up to about 35 to 40 penetrometer numbers below 3, while at higher acid numbers, in particular acid numbers from 50 to 100, significantly higher penetrometer numbers up to to 50 to 60 and above can be obtained.

The oxidation products of the polyethylene waxes obtainable by thermal degradation of low-pressure polyethylene still have the special property that their hardness initially increases with increasing degree of oxidation, while the oxidation products of synthetic paraffins and high-pressure polyethylene waxes are consistently softer than the starting material. This is explained by the table below, which shows how the hardness of such an oxidate increases compared to the starting product with an increasing degree of oxidation expressed by the acid number: Sz hardness, kglcm2 0 435 to 445 9 544 to 555 25 625 to 650 36 625 to 690 (The hardness measurement used here is described in Example 2.) This increase in hardness makes the oxidates of the low-pressure polyethylene waxes particularly valuable products.

Those made from polyolefin waxes according to the process of this invention Oxygen-containing products are compared to the previously known ones Introduction of oxygen into higher molecular weight paraffin hydrocarbons available Products as well as a step forward compared to the oxygen-free polyethylene waxes in the field of wax raw materials. With them you have fully synthetic ones at your disposal Wax raw materials that have many properties equivalent to classic hard waxes are.

This is shown above all by the fact that when they are processed together with other hard waxes such as natural waxes or those based on montan wax acid based, possibly also metal soap-containing ester waxes, the properties the latter can be modified in many ways.

Example 1 A by thermal degradation of high molecular weight low-pressure polyethylene Polyethylene wax obtained with a flow hardness of 435 to 445 kg / cm2 and a melt viscosity of 150cP (140 ° C), a molecular weight of 1400 and a pour point Ubbelohde 116/117 "C was under with an oxygen flow of 3.51 / h / kg at 120 ° C Stirring is oxidized until the acid number has reached 25. The product had a melt viscosity of 140 cP (1400 C) and a hardness of 625 to 650 kg / cm2.

Comparative example In contrast, a Fischer-Tropsch hard paraffin from Flow-dropping point 112/113 ° C a hardness of 330 to 340 kg / cm2, while the result produced oxidate with the acid number 23 a flow-drop point of 95/96 ° C and has a hardness of 135 to 175 kg / cm2.

Example 2 A by thermal degradation of high molecular weight low-pressure polyethylene Polyethylene wax obtained with a flow hardness of 500 to 520 kg / cm2 and a melt viscosity of 350 cP (140 ° C), a molecular weight of 3000 and a flow-drop point according to Ubbelohde 117.5 / 118.5 ° C was with an oxygen flow of 6 l / h / kg at 130 ° C blown with stirring until the acid number 60 was reached.

A product with a melt viscosity of 110 cP (140 "C) resulted.

The hardness values given above were determined in the following way: A test specimen poured into a small steel pot is pressed through a stamp by means of a pneumatically operating device at 20 "C with gradually increasing Pressure charged. With this method, the hardness of the wax is the pressure load expressed in kg / cm2, at which the stamp breaks into the test specimen.

Example 3 A high pressure polyethylene wax of molecular weight is oxidized of about 5000, a melting point of 120 ° C and a melt viscosity of 1171 cP (120 ° C) with rapid stirring with formation of a foam phase in the presence of 0.2% lauroyl peroxide at 125 ° C with a different oxygen supply up to to an oxygen content of 3.5%, the viscosity of the oxidates is: Sz a) with an oxygen supply of 2 to 3 l / h / kg .......... about 1200 cP 15 b) at an oxygen supply of more than 3 l / h / kg approx. 400 cP 15 c) with an oxygen supply less than 2 l / h / kg (comparison test) ................... to. about 1900 cP

Claims (2)

Claims: 1. Process for the production of oxygen-containing Wax raw materials by oxidation of polyolefin waxes with a molecular weight from 1000 to 8000 and a melting point below 130 ° C with molecular oxygen or gases containing these in the liquid phase at temperatures above the melting point the polyolefin waxes, optionally in the presence of ozone or peroxides as oxidation catalysts, d a -characterized in that polyolefin waxes at temperatures above the Melting point of the polyolefin waxes and not more than 1300C, up to an acid number of not more than 100 is oxidized, taking into account the viscosity of the reaction mixture by regulating the oxygen supply, which is at least 2 1 / hour / kg wax, holds at a value that does not exceed the viscosity value of the polyolefin waxes used is at the same temperature. 2. The method according to claim 1, characterized in that the Oxidation when viscosity values between 1000 and 10 000 cP are reached, but not above those of the polyolefin waxes used, breaks off. Considered publications: German Patent Specifications No. 818 427, 915 741.