DE1198811B - Process for the thermal cracking of hydrocarbons - Google Patents

Description

Process for the thermal cracking of hydrocarbons It is known to split hydrocarbons with two or more carbon atoms by that they can be liquid or gaseous, possibly after separate preheating introduced into a stream of hot combustion gases and after a short reaction time suddenly deterred. The main cleavage products obtained are acetylene, Ethylene and higher olefins. The combustion gases are obtained by in a combustion chamber hydrogen and / or any carbon-containing compound burns with oxygen and the hot gases by adding steam (in the following Called secondary steam) and / or hydrogen cools to the optimal temperature.

Furthermore, cleavage processes are known in which the to be cleaved Hydrocarbons either at the same time in different places or in the same place Body to be fed at different times. For example, with the Working in a regenerative furnace this initially harder to break down hydrocarbons and then supply more easily fissile hydrocarbons as the temperature drops.

It is also known to have heavy oils in a fluidized bed in ethylene and to cleave higher olefins. The reaction mixture is made by adding more Quenched oil, with additional gasoline being formed. According to another Process are hot combustion gases first by adding hydrocarbons, the cracked to condensable products are cooled to 950 to 1200 ° C. Then more hydrocarbons are added to make ethylene and others Olefins are cracked. In all of these cases there are predominantly ethylene and higher olefins in addition to condensable products. Acetylene occurs at most as By-product on.

It is also known to mix methane to carrier gases to split, but the pyrolysis must take place at a higher temperature level than in the case of the higher hydrocarbons, which is due to the different values for the free energy is also to be expected. The deterrent in this case can be with water or aromatic hydrocarbons. The temperature, right up to that down a reaction still takes place (end of reaction temperature) is due to the higher hydrocarbons between 700 and 1250C C, and the higher it must be, the greater the gex desired Acetylene yield is. In the pyrolysis of methane, however, this temperature must be at least 1400 to 1600 "C, if you achieve a reasonably high conversion of methane want. As a result, the amount of heat that by quenching for the chemical Reaction is lost, higher in the fission of methane than in the pyrolysis higher Hydrocarbons. Since this amount of heat is only used to generate steam the high temperature level of the methane pyrolysis has a disadvantageous effect on their profitability.

It is also a process for making acetylene and gas mixtures containing olefins described, in which a two-stage pyrolysis is carried out in such a way that in highly heated rooms or by means of electrical Energy initially pyrolyzed hydrocarbons and those in the hot exhaust gases still contained heat to produce additional quantities of acetylene and olefins Addition of further hydrocarbons is used. There should be an increase the yield of unsaturated hydrocarbons by 20% with the same effort of energy can be achieved. About the possibility of such a two-stage way of working to be carried out in carrier gas pyrolysis, however, nothing is known yet.

A process for the thermal splitting of hydrocarbons has now been developed, in particular for the production of acetylene and ethylene, found, in which one optionally Preheated hydrocarbons for splitting into one hot one in several places Introduces heat carrier and then quench the reaction product, which thereby is characterized in that methane is converted into hot combustion gases in a first stage of temperatures above 20,000 C and after the end of the pyrolysis the Hydrocarbons with 2 or more carbon atoms are still at least 1200 "C hot adds, which in a second stage by the hot exhaust gases of the methane pyrolysis during a reaction time on the order of 10-2 to 10-3 seconds.

In the manner according to the invention, the energy can be made usable up to a temperature level of 700 to 1100 ° C for the thermal splitting of hydrocarbons in carrier gases, with acetylene preferably being obtained in the first stage and ethylene in the second stage. From the examples of the present invention it can be seen that in the two-stage pyrolysis, with the same energy input, considerably more unsaturated hydrocarbons are produced than in the single-stage pyrolysis. This increase in relation to the production of the one-step process is given in the table: example 1 2 3 4 C2H2. . . . . . . . 159% '200 / o 230 / o 130 / o C2H4 ........ 1150 ° / o 8100 / o 1 16400 / o 1 1710 ° / o C2H2 + C2H4 284% 62 ° / o 131 ovo 1040/0 The increase in yield is therefore considerably greater than in the case of the above-cited method of working with electrical energy. The reason for this increase in yield is the combination of two different hydrocarbons in successive stages. The advantage of the pyrolysis according to the invention is therefore an increased economy, which results from the fact that the same energy utilization can be achieved that could previously be achieved with higher hydrocarbons alone, and that these hydrocarbons can nevertheless be partially replaced by the cheaper natural gas. This process can therefore be used both when the energy utilization is increased in a methane pyrolysis by subsequent cleavage of higher hydrocarbons, and in the event that the costs of the input product in the pyrolysis of higher hydrocarbons are increased by upstream methane pyrolysis (with the same Energy utilization). In the latter case, you may also save the costs for the secondary steam and the additional hydrogen, since the methane can replace both completely or partially. Another advantage is that the acetylene content of the reaction product is significantly higher in the present process than in the pyrolysis of methane.

That such a combined cleavage process is possible was after the known state of the art cannot be predicted. Condition for success namely, that the reaction time for the second cleavage is based on a deeper one Temperature level takes place, is still short enough, so that a noticeable decay of the acetylene formed in the first stage is avoided. For this reason may the temperature should not have dropped too low after the first stage, otherwise Residence times are required in which a noticeable proportion of the first formed Acetylene breaks down. On the other hand, it is important, the second hydrocarbon only to be added when the methane has largely been used, otherwise as a result the greater rate of reaction of the higher hydrocarbons is greater Part of the methane is not converted.

The combined cleavage process is carried out in such a way that one first in a conventional combustion chamber by burning any fuel the hot combustion gases generated, being a possible addition of steam or Hydrogen should not exceed 10 0 / o of the combustion gases if possible, so that temperatures of over 2000 "C, particularly advantageously 2400 to 2600" C, are reached. It is particularly economical to use the fuel gas from the cracked gas after separation to use residual gas obtained from unsaturated compounds and carbon dioxide, which consists essentially of water vapor, carbon oxide and methane.

Methane is added at the exit of the combustion chamber, which is advantageous is preheated to 400 to 800CC.

In the subsequent reactor, the size of which is such that the residence time is on the order of 10-3 to 10-4 seconds, the methane becomes mainly split into acetylene and carbon monoxide. The reaction temperature here should be above 1200 C, particularly advantageously between 1400 and 1600 ° C. Then be through several nozzles the higher hydrocarbons for the second stage of the cracking reaction added, which are advantageously also preheated. In a similarly built one These hydrocarbons are reacted in the reactor with a residence time of 10-2 to 10-3 Split seconds, with ethylene being the main product. At a final temperature which, depending on the amount used, is between 700 and 1100 ° C, they are hot Gases quenched as quickly as possible, washed and subjected to the usual gas separation.

For carrying out the method described, for. B. Devices such as those in A b b. 1 and 2 are shown: For generating burns the required high temperature, for example, a metal burner t is used, the fuel gases and oxygen are introduced tangentially or radially at its head will.

Some steam may be added towards the end of the combustion zone will. In the neck of the torch, the methane is released through several - preferably radial - nozzles supplied, the number of nozzles being such that rapid mixing is achieved with the combustion gases so that they do not stick to the wall without being cooled get to the reactor.

The reactors 2 and 3 consist, for example, of cylindrical or conical metal tubes. These can protect against the high temperatures inside lined with a ceramic mass or cooled from the outside, as it is, for. B. in the A b b. 1 and 2 is shown. It can be advantageous to have both reactors, as in A b b. 1 and 2 is shown to be formed as a unitary tube in which at a suitable point the nozzles for the supply of the higher hydrocarbons are appropriate. These can be provided with their own cooling jacket so that they are specially protected against overheating, as shown in A b b. 2 through the cooling jacket of the reactor happens.

The combustion chamber can also be lined with ceramic masses or by external cooling, e.g. B. with water, protected against the high temperatures will.

The principle of combined pyrolysis can also be applied to the process of partial methane combustion. In this case, in one of the well-known Burner burns methane with a deficit of oxygen, so that combustion and methane cleavage of the process described above are combined into one stage, and then, as described above, higher hydrocarbons are added, after their splitting is deterred.

Example 1 28.2 Nm3 / h of hydrogen are generated in a water-cooled burner burned with 12.9 Nm3 / h oxygen and added 8.6 Nm3 / h methane at the end of the burner.

After the methane has been broken down, 5.0 kg / h of light petrol, which has been preheated to 2500 ° C., are added. The second cleavage is followed by quenching with water. This gives 30.4 Nm3 / h of a gas of composition A. If, on the other hand, you stop after the methane pyrolysis without any further gasoline addition, you get 24.6 Nm3 / h of gas of composition B. 29 kg / h (= 284%) more acetylene and ethylene than in single-stage pyrolysis. AWAY Volume volume percent kg / h percent kg / h H2 62.3: 1.70 70.8 1.57 CO2 2.1 1.27 3.5 1.70 CO 9.8 3.73 12.0 3.69 CH4 12.1 2.60 8.5 1.48 C2H2 7.2 2.57 3.5 1.01 C2H 4.9 1.88 0.5 0.15 C3H6 0.3 0.17 0.2 0.09 N3 / Ar 1.3 0.50 1.0 0.31 Example 2 In a test arrangement as in Example 1, 27.2 Nm3 / h of hydrogen are burned with 13.6 Nm3 / h of oxygen, then 15.0 Nm3 / h of methane and, in the second stage, 3.8 kg / h of light petrol are added.

41.5 Nm3 / h of cracked gas are obtained from the composition, compared to 37.9 Nm3 / h of composition B with direct quenching after the methane pyrolysis without the addition of gasoline. In the two-stage pyrolysis according to the invention, 2.21 kg / h (= 630 / o) more acetylene and ethylene are obtained than in the single-stage pyrolysis. AWAY Volume 1 volume percent t kgih percent kg / h H2 62.6 1 2.33 67.9 0 2.31 CO2 1.8 1.48 2.0 1.48 CO 10.7 5.56 11.7 5.53 CH4 11.3 1 2.96 8.7 2.33 C2H2 8.2 1 3.99 7.5 3.32 C2H4 3.3 1.73 0.4 1 0.19 C3H8 0.1 0.08 0.0 1 N2 / Ar 2.0 1 1.04 1.8 1 0.85 Example 3 In a test arrangement as in Example 1, 20.5 Nm3 / h fuel gas (57.90 / 0 H2, 11.80 / 0 CH4, 30.3 0 /, CO) are burned at 13.9 Nm3 / h O2, in addition, 2.0 kg / h of steam are introduced into the burner, then 11.6 Nm3 / h of methane and, in the second stage, 6.2 kg / h of light petrol are added. 39.9 Nm3 / h of cracked gas of composition B is obtained with direct quenching after the methane pyrolysis without the addition of gasoline, 2.75 kg / h (131%) more acetylene and ethylene than when working without the addition of gasoline. AWAY Volume volume percent kglh | percent kglh H2 40.8 1.46 46.2 1.42 CO2 11.0 8.69 12.8 8.67 CO 20.8 10.39 24.3 10.39 CH4 11.9 3.46 8.2 1.98 C2H2 6.0 2.81 5.7 2.29 C2H4 6.1 3.08 0.4 0.18 C3H6 0.6 0.45 0.0 - N2Ar 2.8 1.40 2.4 1.03 Example 4 29.4 Nm3 / h methane and 18.1 Nm3 / h oxygen are preheated to 600 "C, mixed and burned in a ceramic combustion chamber , 2 kg / h of light petrol were injected, which had previously been evaporated and preheated to 300 ° C. After the cracking reaction had ended, the gases were quenched with water.

This gives 63.8 Nm / h3 of exhaust gas of composition A. If you stop after the partial combustion of the methane without adding gasoline, only 55.3 Nm3 / h of exhaust gas of composition B are produced Petrol added 5.41 kg / h (= 104 0 / o) more acetylene and ethylene than without petrol added. AWAY Volume- Volume- kg / h percent kg percent H2 47.7 2.74 54.1 2.69 CO2 3.3 4.15 3.9 4.27 CO 22.4 17.88 26.0 1 17.95 CH4 9.9 7.00 5.3 2.07 C2H2 7.4 5.54 7.6 4.92 C2H4 6.3 5.07 0.4 0.28 C3H6 0.6 0.71 0.0, N2 / Ar 2.4 1.91 2.7 1.86 Claims: 1. A process for the thermal cleavage of hydrocarbons, in particular for the production of acetylene and ethylene, in which optionally preheated hydrocarbons are introduced into a hot heat transfer medium for cleavage at several points and the reaction product is then quenched, characterized in that in a first stage Introduces methane into hot combustion gases at temperatures above 20,000 C and, after the end of the pyrolysis, adds hydrocarbons with 2 or more carbon atoms to the gases that are still at least 1200 ºC -2 to 10-3 seconds.

Claims (1)

2. The method according to claim 1, characterized in that the methane splitting in a temperature range between 2400 and 26000 C on the one hand and 1400 to 1600 "C on the other hand takes place. 3. The method according to claim 1, characterized in that the final temperature the cleavage in the second stage is in the range from 700 to 1100 ° C. 4. The method according to claim 1 and 2, characterized in that the Reaction time for pyrolysis in the first stage of the order of 10-3 up to 10-4 seconds. 5. The method according to claim 1 to 4, characterized in that one prior to the addition of methane, hydrogen and / or water vapor in quantities of up to 10%, based on on the amount of combustion gases added. 6. Modification of the method according to claim 1, characterized in that that according to the known principle of the partial methane compound methane at the same time as a fuel gas to generate the combustion gases and as a hydrocarbon to be split used in the first stage. Considered publications: German Patent Specifications No. 938 844, 806 455; German Auslegeschrift No. 1 009 617; German patent specification No. 160 519 (Austria branch); British Patent Nos. 709 035, 416 957; French Patent Specification No. 947 257; U.S. Patents No. 2,371,147, 2 197 257.