DE1148999B - Process for the production of acetylene - Google Patents

Description

Process for the preparation of acetylene The invention relates to a improved process for the production of acetylene by partial oxidation of saturated Hydrocarbons such as methane.

So far are for the production of acetylene by partial oxidation Numerous methods of hydrocarbons have already been proposed, but they are satisfactory all of these processes are not complete because the acetylene yield is somewhat low and it is difficult to work for long periods of trouble-free time.

In a typical process, a non-stoichiometric (insufficient Oxygen for complete combustion) mixture of a preheated saturated Hydrocarbon gas (natural gas) with oxygen through one with many openings provided plate through and is ignited there. The plate serves to make a Prevent backfire of the flame to the mixing chamber. The hot ones containing acetylene Combustion products are quickly quenched in water and the acetylene becomes away from the other products of combustion. This process sees a gas flow rate during mixing at 91 m per second, but with pre-ignition difficulties often appear.

It has now been found that to achieve high yields in a It is important that the acetylene generation process proceeding with partial oxidation certain requirements are met. These are: (1) Both the hydrocarbon as well as the oxidizing agent should be warmed to a temperature before mixing as high as possible without causing preignition during mixing; (2) If premixed, intimate mixing of the preheated hydrocarbon should be achieved and the preheated oxidizing agent in as short a period of time as possible are to prevent pre-ignition at the mixing point and preheating losses as much as possible to diminish; (3) the partial oxidation reaction of methane or other hydrocarbons to form acetylene should be at a relatively high temperature in a As short a period of time as possible can be effected in order to maintain high acetylene yields.

In particular, it was found according to the invention for a given mixture of reacting substances that the percentage of acetylene in the product is high is influenced by the temperature to which the reacting substances are heated because the volume of acetylene produced is favored by high temperature will. The amount of preheating to be effected is through for practical reasons the temperature is limited in the case of pre-ignition at the mixing point or the mixing point appear.

Should the oxidant stream be preheated to too high a temperature there would be considerable oxidation of the interior of the metallic oxidant lines appear. Should the hydrocarbon be preheated to too high a temperature, Significant pyrolysis would occur to remove harmful carbon deposits on the walls of the device, causing clogging or clogging the preheater pipes leads.

The aforementioned rapid and intimate mixing of the preheated hydrocarbon as well as the preheated oxidant at the highest practical temperature is required for high yields of acetylene in the reaction product. This requirement there are other reasons for the loss of a certain amount of preheat through the device walls to reduce as much as possible that occurs during mixing when the mixer is cooled by water or another coolant.

Pre-inflammatory reactions give rise to many serious problems. Step such reactions, the yield of acetylene from a given amount of the reacting substances are considerably reduced. Not just that a loss generated amount of acetylene exists, but the pre-ignition fractions also interfere the relevant components of the acetylene burner. For these reasons, it is at a process for the production of acetylene by partial oxidation reaction of the utmost importance that pre-inflammatory reactions practically prevented or be reduced.

One used to prevent pre-inflammatory reactions from occurring Method was, the preheat temperature of the hydrocarbon and oxidant stream to diminish. However, this was found to be unsatisfactory because of the amount of acetylene, which is produced from a given amount of the substances that react becomes, decreases as the preheat temperature of the hydrocarbon and oxidant streams decreases.

The present invention relates to a method of production of acetylene by partial oxidation of essentially saturated hydrocarbons, in which a stream of hydrocarbons which is at a temperature below the Pyrolysis temperature was heated and a stream of oxidant, which on a temperature below the temperature at which a substantial Oxidation of the oxidant line occurs, mixed and mixed in a mixing zone the combined streams are fed into a reaction zone in which the partial Oxidation is effected, which is characterized in that in the stream of Hydrocarbons before mixing with the oxidizing stream between 0.1 and 20 percent by volume of a pre-ignition inhibitor can be introduced, consisting of air, oxygen, oxygen-enriched air, water vapor or mixtures thereof.

Pre-ignition reactions are caused by certain reaction-inducing materials caused, which are entrained in the hydrocarbon stream. Examples of such Reaction-initiating materials are carbon, iron oxides and free hydrocarbon radicals. Although the rate at which the pre-ignition reactions occur is a measurable one If the effectiveness of the pre-ignition inhibitors is displayed, the actual one can be seen Do not fully understand the mechanism of inhibition. It is believed that the inhibitors free hydrocarbon radicals which enable premature reactions to be initiated and / or certain reactive materials are in an inactive state convert.

In carrying out the method of the present invention It has been shown that air, commercially pure oxygen, is oxygen-enriched Air and water vapor are useful preignition inhibitors. The amount of the hydrocarbon stream added inhibitor should be sufficient to remove the initiating materials put into an inactive state. When using a hydrocarbon stream from practically pure methane it was also found that between 0.1 and 5 percent by volume of the inhibitor leads to excellent results, but that an additional pre-ignition inhibitor in concentrations up to 20 percent by volume of the hydrocarbon feed supply can be added without seriously reducing the acetylene yield.

Although it was found that preignition inhibitors are in the hydrocarbon stream be introduced at any convenient point upstream of the mixing zone where the hydrocarbon and oxidizer are mixed is preferable introduce the inhibitor before preheating the hydrocarbon stream. this ensures sufficient time for the inhibitor to complete the reaction introductory materials put into an inactive state.

Before using pre-ignition inhibitors, a pure methane stream preheated to about 5000 C. At the same time there was an oxidant stream preheated to about 4500 C.

When the preheated methane and the preheated oxidant are mixed in pre-ignition reactions occurred in the mixing zone every 11 hours on average on. Another increase in the temperature of the methane and oxidant streams would lead to more frequent pre-inflammatory reactions.

Under an essentially pure methane stream, one is closed understand which contains at least 980/0 methane.

The following are pre-ignition inhibitors according to the new invention added to a substantially pure methane stream before the methane and oxidant streams be added. The preheating temperature of the methane stream was increased to 7500 C, while the preheating temperature of the oxidant stream is increased to 6500.degree became. As the preheated methane and the preheated oxidant mixed in pre-ignition reactions occurred in the mixing zone every 36 hours on average on.

In one example of the present invention, atmospheric air was used into the methane storage boiler in the ratio of 0.02382 cbm of atmospheric air per 2.2656 cbm methane entered. The methane and oxygen flows were then brought to a temperature preheated to 750 or 6500 C. After that, the methane and the oxygen flows a mixing zone and fed from there to a combustion chamber, where the partially Oxidation reaction was effected. Entering atmospheric air into the methane stream enabled the process to be carried out at a temperature about 2500 C higher, than was previously possible without their application. Besides, it was practically average Increase of 25 hours of trouble-free operation achieved and the product contained 0.4 ovo acetylene more than from a comparable amount of the same in reaction occurring substances was generated under previous conditions.

Another example of the present invention became commercially available pure oxygen in the methane storage boiler in the ratio of 0.02832 cbm oxygen entered to 3.54 cbm methane. The methane and oxygen flows were on one Preheated to a temperature of 800 or 6500 C. Thereupon the methane and oxygen currents became a mixing zone and fed from there to a combustion chamber, where the partial oxidation reaction was effected. The input of commercially available pure oxygen into the methane stream enabled the process to be carried out at 3000 C higher than would be possible without its use was. The product contained 0.20 / 0 more acetylene than from a comparable amount the same reacting substances was generated under previous conditions. In yet another example of the present invention, water vapor was in the methane feed line was introduced at a rate of 14.16 cbm methane per 0.4536 kg of steam.

The methane and oxygen flows were reduced to a temperature of 750 or 6500 C preheated. Thereupon the methane and the oxygen currents became one Mixing zone and from there a combustion chamber fed where the partial Oxidation reaction was effected. The introduction of steam into the methane stream made it possible the implementation of the process is 2500 C higher than it was before without its application was possible. In addition, an average extension of practically 24 Hours of trouble-free operation achieved and the product contained 0.30 / 0 more acetylene than reacting from a comparable amount of it Substance was generated under previous conditions.

To estimate the upper ranges of the inhibitor associated with a hydrocarbon stream Without harmful consequences, water vapor was added to the methane supply line introduced at the rate of 3.4 cbm methane per 0.609 cbm steam.

Corresponding preheating temperatures for the methane and oxygen flows were 750 and 6500 C.

Under these conditions, namely, at an inhibitor concentration of 18% by volume a slight decrease in the acetylene yield was noted.

It was also noted that there was a slight increase in the oxygen-methane ratio was required to achieve the desired response.

In another attempt to estimate the upper ranges of the Inhibitor was air in the methane feed line in the proportion of 0.148 cbm methane introduced per 0.028 cbm of air. Corresponding preheating temperatures for the methane and oxygen flows were 750 and 6500 C. Under these conditions was viz at an inhibitor concentration of 19 percent by volume, there was a slight decrease in the acetylene yield noticed and a slight increase in the oxygen to methane ratio was required. to get the desired response.

It should be emphasized that the above examples of implementation ments are representative that are carried out under extremely obstructive conditions. In the examples it would if the implementations were made on a 24-hour day basis it will be possible to work at slightly lower preheating temperatures and thereby to achieve longer, trouble-free operating times.

According to German Patent 898 745 it is known in the partial oxidation or splitting of organic substances such as hydrocarbons, in gaseous form in combustion turbines the flowing gases at one or more points Combustion accelerators, such as ethyl nitrite or ethyl nitrate, or such substances, who like z. B. ethylene dibromide the speed, the extent and / or the Influence the nature of the chemical reaction taking place. With these well-known However, additives are not pre-ignition inhibitors. Any conclusions This publication does not refer to the effectiveness of such inhibitors remove.

Although the new invention is practically pure in terms of application Methane has been described, it should be understood that the invention is not limited thereto is. Pre-ignition inhibitors can be, as was further found, successful also with other starting materials, e.g. B. use natural gas of the following composition, in which the heavier hydrocarbons were not removed: 94.40 / 0 CH4, 0.60 / 0N2, 3.3.0 / 0C2H0, 0.7 ° / o C3H8, 0.40 / o CO2 and 0.10 / o butane.

Claims (3)

PATENT CLAIMS: 1. Process for the production of acetylene by the partial oxidation of essentially saturated hydrocarbons, in which a stream of hydrocarbons at a temperature below the pyrolysis temperature has been preheated, and a stream of oxidant brought to a temperature was preheated below the temperature at which substantial oxidation of the Oxidant conduction occurs, mixed in a mixing zone and the combined Streams are passed into a reaction zone in which the partial oxidation is effected is, characterized in that in the hydrocarbon stream before it with the Oxidant stream is mixed, between 0.1 and 20 volume percent of a pre-ignition inhibitor are introduced from air, oxygen, oxygen-enriched air, water vapor or a mixture of these substances. 2. The method according to claim 1, characterized in that the hydrocarbon essentially pure methane is used. 3. Process according to Claims 1 and 2, characterized in that the preignition inhibitor in the hydrocarbon stream prior to preheating the same is introduced. Documents considered: German Patent No. 898745.