DE3116409A1 - Process for the preparation of higher hydrocarbons - Google Patents

Abstract

Process for the preparation of higher hydrocarbons, in particular for the preparation of ethane from methane, in which, after sufficient temperature increase for a dissociative chemisorption at a catalyst surface, a catalytic cooling is carried out to a temperature at which C-C recombination occurs. A surface intermediate formed during this, which is composed for the most part of chemisorbed C2 hydrocarbons, can be desorbed in an H2 stream at constant temperature, in order, with the use of a platinum catalyst, to generate an end product which is composed for the most part of ethane.

Description

Process for the production of higher hydrocarbons

The invention relates to a process for the production of higher hydrocarbons, especially for the manufacture of ethane from methane.

A method of the type mentioned is basically from the U.S. Patent 2,195,227 is known. In this known method, methane and oxygen are used separately preheated to a temperature of about 600 oC uad in a ratio of about 1: 0.6 mixed. Then part of the methane is released in a flame burned, so that the heat of reaction released in this case on the one hand to cover the heat demand of the endothermic C2H2 formation from CH4 and on the other hand for Heating the reaction mixture to about 1,500 Oc is consumed. The education of acetylene takes place in this known process at a temperature of about 1 500 00.

So it is basically known by thermal splitting of methane to produce higher hydrocarbons such as acetylene or ethylene. Appropriate However, methods can only be carried out with an extremely high outlay in terms of equipment and require a lot of energy. From the temperature dependence of the free Enthalpy of formation of the hydrocarbons, however, can be seen that, for example Acetylene from methane only above a temperature in the range from 1,400 to 1,400 oC can form.

Another difficulty in performing the known method results from the fact that all hydrocarbons are at the temperatures mentioned are unstable and that the thermodynamic equilibrium is on the side of the stable End products carbon and hydrogen.

A dwell time must therefore be observed during heating, which is sufficient to ensure a sufficient concentration of higher hydrocarbons to get, but it is too short that the C2 hydrocarbon is not yet in Carbon and hydrogen continue to break down. Suitable residence times are included the known method at about 0.001 to 0.05 seconds.

The production of longer-chain or higher hydrocarbons from methane not only requires considerable amounts of energy, but also an extraordinary amount high temperatures and very short residence times, so that such processes because of the technical effort associated with an exact implementation on an industrial scale are hardly economically feasible.

The invention is based on the A u f g a b e, a method for Production of higher hydrocarbons, especially for the production of ethane to create from methane, of the type mentioned in more detail at the beginning, which with special low energy consumption in an extremely simple and economical way is. The method according to the invention should also be feasible on an industrial scale.

To solve this problem, the invention provides that methane on a sufficiently high temperature brought about a dissociative chemisorption to bring about on a catalyst surface, and that the catalyst with the substance chemisorbed on its surface is cooled, so that a C-C recombination occurs and a higher, chemisorbed hydrocarbon is formed, which with H2 is desorbed.

The invention thus makes use of the knowledge that a technical a cooling process that can be carried out easily and is unproblematic in practice is sufficient, which is hereinafter also referred to as catalytic cooling for short, in order to be relatively low temperatures chemisorbed dissociation products from methane to higher ones Recombine hydrocarbons.

According to the invention, the essential technical progress is achieved, that an extremely essential raw material for the plastics industry such as Ethylene in an amazingly simple way from an abundant and inexpensive one available substance such as methane can be produced.

A particularly preferred embodiment of the method according to the invention provides that platinum is used as the catalyst. It can be advantageous a platinum powder catalyst can be used. Basically rhodium also come or rhenium and possibly also oxide catalysts for carrying out the invention Procedure under consideration.

A particularly preferred embodiment of the invention Process provides that when using a platinum catalyst for dissociation and chemisorption of methane at a temperature in the range of about 180 to 300 oC is produced. It should be added that those for chemisovption or chemosorption the most suitable temperature, inter alia, on the activity of the catalyst depends. The temperature also depends on the type of manufacture and the surface of the catalyst. Greater activity of the catalyst means one lower temperature.

Another advantageous embodiment of the method according to the invention provides that the temperature is brought to at least a level at which after sufficient dissociation of methane reduces the binding forces between the catalyst and the hydrogen are greater than between the carbon and the hydrogen and / or between carbon atoms with one another.

It should preferably be provided that the temperature on a value is limited at which a hydrocracking reaction has not yet reached carbon formation goes.

Another advantageous embodiment of the invention is distinguished characterized in that a catalyst with a platinum surface structure is used and that the dissociation of methane is continued until that from the dissociated methane formed carbon atoms and the hydrogen atoms in the Chemisorbed manner on the catalyst surface that at least no steric There is an obstacle to recombination.

The method according to the invention can also be particularly advantageous as a result be controlled that for the unstable, chemisorbed intermediates a Residence time is observed, so that although a predeterminable hydrocarbon concentration is formed, but no further decomposition into carbon and hydrogen arises.

Although for the catalytic cooling provided according to the invention and in particular no exact limit values for the temperature profile that occurs are to be given because the most favorable procedure of the various Depending on the influencing variables mentioned, it can preferably be provided that the Use of a supported platinum catalyst a Cooling down is brought about to a temperature in the range of about 120 to 150 OC. By Such a cooling decrease the binding forces between the catalyst and the C-Qtoms so far that a C-C recombination is possible and a higher, but chemisorbed or chemosorbed hydrocarbons are still formed.

A particularly advantageous device-related embodiment of the basic idea According to the invention, the catalytic cooling is carried out in a fluidized bed and that the temperature in the fluidized bed is locally set to a value that can be specified in each case is set. There are also various other constructive structures within the scope of the invention Arrangements are conceivable, taking into account the respective decisive influencing variables carry out catalytic cooling on a large scale particularly economically.

In order to obtain the desired end product after the catalytic cooling to achieve, it is expediently provided that after the catalytic cooling is flushed with H2 in order to desorb the chemisorbed intermediate product and thereby at the same time to form longer-chain hydrocarbons. When using a strapless Platinum catalyst, this desired end product consists of ethane.

The invention is never further described below with the aid of examples.

Methane is fed to an active catalyst, for example on a carrier-free, platinum catalyst.

In addition, the temperature is increased to such an extent that CH4 is removed from the catalyst is strongly and dissociatively chemisorbed With a strapless Corresponding temperatures for platinum powder catalysts are in the range of approx 180 to 220 ° C. Depending on the activity, surface properties and type of production of the catalyst can also temperatures up to the order of 300 oC for a corresponding chemisorption come into consideration.

When using other catalysts such as rhodium, rhenium or even when using oxide catalysts are the most favorable temperatures to determine experimentally for a suitable chemisorption. Basically means however, the higher the activity of the catalyst, the lower the temperature.

The temperature may only rise so high up to the surface of the catalyst the methane is adsorbed dissociatively. The temperature shouldn't be that far be increased so that the catalytic hydrocracking reaction goes to coal formation.

If the catalyst has a surface structure in which the C-atoms and the H-atoms from the dissociative chemisorbed methane favorably next to each other are arranged so that there is no longer any steric obstacle to recombination is present, but at most only an energetic threshold is present, succeeds through the catalytic cooling according to the invention, the recombination to form higher hydrocarbons especially good. That which arises on the catalyst surface after the chemisorption Surface intermediate has basically the same structure as a dissociative chemisorbed ethane or propane molecule.

The surface intermediate product could be built up from methane as well as from higher hydrocarbons.

When such a surface intermediate product on the catalyst surface is present, according to the invention, the catalyst with the chemisorbed The substance is cooled down until the bonding forces between the carbon atoms again become greater than the binding forces between the carbon and the catalyst. In the case of a carrier-free platinum powder catalyst, cooling takes place down to a temperature in the range of about 120 to 150 OC. According to the explanations above the optimal temperatures are always based on the type and manufacture as well as the Activity of the catalyst dependent and easy to determine experimentally.

In the catalytic cooling according to the invention, hydrocarbon recombination occurs on, in which the expansion of the C-C bonds sterically and energetically opposite C-H recombination occurs preferentially. This process creates a Surface intermediate, which for the most part consists of chemisorbed C2 hydrocarbons consists.

At the temperature in question there is a saturated hydrocarbon desorbable like ethane; however, it can be easily removed from it by dehydrating substances like acetylene or ethylene.

This intermediate surface product can be found in an H2 flow Desorb at a constant temperature.

Thus, according to the invention, it takes place after the catalytic cooling flushing with H2. In this way it is produced using a platinum catalyst a product that consists mainly of ethane.

Not just the temperature for chemisorption or chemosorption depends on the catalyst, including the catalytic cooling, i.e. the temperature profile during the cooling process depends on the activity, the surface quality, on the type of production of the catalyst and also on other properties of the catalyst. On cooling, however, means greater catalyst activity a stronger cooling.

The procedure described above can be followed by virtually any suitable one Perform equipment arrangement, for example in a fluidized bed, in which the local temperature for carrying out the individual process steps accordingly can be adjusted.

Claims (11)

Claims 1. ' Process for the production of higher hydrocarbons, especially for the production of ethane from methane, thus g e k e n n n z e i c h n e t that methane is brought to a sufficiently high temperature to be dissociative Induce chemisorption on a catalyst surface, and that the catalyst is cooled with the substance chemically isorbed on its surface, so that a C-C recombination occurs and a higher, chemisorbed hydrocarbon is formed, which is desorbed with H2. 2. The method according to claim 1, characterized in that g e k e n n -z e i c h n e t, that platinum is used as a catalyst. 3. The method according to claim 2, characterized in that g e k e n n z e i c h n e t, that a platinum powder catalyst is used, which is preferably a carrier Has. 4. The method according to any one of claims 1-3, characterized in that g e -k e n n z E i c h n e t that when using a platinum catalyst for dissociation and chemisorption of methane produces a temperature in the range of about 180 to 300 ° C will. 5. The method according to any one of the preceding claims, characterized g e no indication that the temperature is at least brought to a level in which after sufficient dissociation of methane the binding forces between the The catalyst and the hydrogen are larger than between the carbon and the Hydrogen and / or between carbon atoms among themselves. 6. The method according to any one of the preceding claims, characterized g e it is not indicated that the temperature is limited to a value at which a hydrocracking reaction does not go as far as carbon formation. 7. The method according to any one of the preceding claims, characterized g e it is not stated that a catalyst with a platinum surface structure is used and that the dissociation of methane continues until the carbon atoms formed from the dissociated methane and the hydrogen atoms are chemisorbed in such a way on the catalyst surface that at least none steric recombination barrier exists. 8. The method according to any one of the preceding claims, characterized g e I do not note that for the unstable, chemisorbed intermediates a residence time is observed, so that although a predeterminable hydrocarbon concentration is formed, but no further decomposition into carbon and hydrogen arises. 9. The method according to any one of the preceding claims, characterized g e I do not note that when using a carrier-free platinum catalyst brought about a cooling to a temperature in the range of about 120 to 150 OC will. 10. The method according to any one of the preceding claims, characterized g e it is not noted that the catalytic cooling is carried out in a fluidized bed and that the temperature in the fluidized bed is locally set to a value that can be specified in each case is set. 11. The method according to any one of the preceding claims, characterized g e no indication that flushing is carried out with H2 after the catalytic cooling, to desorb the chemisorbed intermediate product and at the same time longer-chain To form hydrocarbons.