DE3336649A1 - Process for the combined preparation of methanol and ammonia - Google Patents

Abstract

A process for the combined preparation of methanol and ammonia by catalytic vapour cracking of light hydrocarbons, preferably methane, is to enable the stripping gas from the methanol synthesis not to be simply burned nor to be converted to ammonia synthesis gas in an expensive process. Simple processing expedient in terms of cost to give ammonia synthesis gas is desired. According to the invention this is achieved in that the hydrogen-containing stripping gas from the methanol synthesis is purified in a known manner to synthesis gas quality and the addition of nitrogen is carried out by burning hydrogen at elevated pressure with air in a hydrogen stream. <IMAGE>

Description

Method of co-manufacturing

of methanol and ammonia The invention relates to a method for Production of methanol and ammonia from light hydrocarbons, in particular Methane.

By desulfurization and catalytic steam reforming of the light Hydrocarbons in a heated tube reformer first becomes a synthesis gas generated, which consists essentially of a hydrogen / carbon monoxide mixture, but also carbon dioxide, methane and other components in the dry gas, which were introduced into the mixture with the feed gas.

This synthesis gas is compressed to the required pressure between 50 and 150 bar fed into the methanol synthesis and on suitable catalysts converted to methanol.

The synthesis gas obtained in catalytic steam reforming contains for stoichiometric reasons an excess of hydrogen compared to the Requirements of methanol synthesis, as can be seen from the basic reaction equations of the Steam reforming can be seen: CH4 + H20 = CO + 3H2 (1) A synthesis gas is produced with an H2: CO ratio of 3, while for methanol synthesis an H2: CO ratio of 2 would be required: CO + 2H2 = CH3OH (2) Parallel to the reaction equation 2 runs the formation of methanol from C02. However, this does not affect the excess hydrogen, as long as the carbon dioxide was created during the steam reforming, since that is a Mols per mole of methanol produced also increased the hydrogen requirement of the synthesis hydrogen production increased by one mole per mole of C02 in the reformer process.

CH4 + 2H20 = C02 + 4H2 (3) C02 + 3 H2 = CH3OH + H20 (4) To reduce the excess hydrogen in methanol synthesis can be converted into methanol synthesis gas a carbon dioxide stream can be fed in during the processing of the from the methanol synthesis repelled gas is obtained into ammonia synthesis gas. This makes the H2: (CO + C02) ratio in the synthesis gas improved. A stoichiometric ratio becomes but not achieved thereby.

It is state of the art to use the non-stoichiometric synthesis gas in feed the methanol synthesis, the excess hydrogen accumulate there to leave this excess by separating off a partial flow of the circulating gas to be removed and fed to the furnace of the steam reformer. Besides Hydrogen at the same time methane and undesirably also carbon oxides from the Circuit removed.

Furthermore, it is according to DE-OS 29 43 356 prior art, from the stripping gas the synthesis of methanol to obtain essentially pure hydrogen from air by means of an air separation plant to obtain essentially pure nitrogen, this both To mix gases in a ratio necessary for the ammonia synthesis and the Add ammonia synthesis.

It is also according to US-PS 43 15 900 prior art, the stripping gas the methanol synthesis a repeated steam reforming process with secondary reformer subject to, in which the methane content is broken down and by supplying air of the nitrogen necessary for ammonia synthesis is introduced into the gas.

The synthesis raw gas obtained in this way must be carried out in a known manner by means of CO conversion, C02 cleaning and fine cleaning on the analysis quality for the ammonia synthesis be processed.

According to the known method, the processing of the Stripping gas from methanol synthesis expensive in terms of investment costs and consumption figures.

The invention is based on the object from the hydrogen, the was obtained in a known manner from the stripping gas, in an inexpensive form to obtain an ammonia synthesis gas.

According to the invention, this object is achieved in that the addition of nitrogen takes place by burning hydrogen under increased pressure with Air in a hydrogen stream.

To make the method according to the invention particularly simple and effective to operate, procedural developments are according to the subclaims intended.

The advantages achieved with the invention are in particular: that the waste product stripping gas from the methanol synthesis after cleaning by means of a simple partial combustion process with the addition of the appropriate Amount of air converted into a full-fledged synthesis gas for ammonia production can be. The heat released by the combustion is not waste heat, but can be fully utilized energetically due to the high temperature level, e.g. for generating drive steam for compressors.

The method according to the invention is shown in the drawings and is described in more detail below. It show: F.g. 1 the process as a schematic Flow diagram for the simultaneous production of methanol and ammonia. FIG. 2 is a flow diagram of the ammonia synthesis strand with at least two-stage combustion, FIG. 3 Flow diagram of the ammonia synthesis strand with admixture of ammonia synthesis gas the combustion hydrogen According to Figure 1, natural gas is under pressure to the common Manufacture of methanol and ammonia through line 1 and steam through line 2 mixed in a suitable ratio in line 3 and after heating in the Waste heat section 4 of the primary reformer 5 is fed to the reformer tubes 6. Simultaneously a natural gas-air mixture is fed to the burner of the primary reformer via line 7, the heat of reaction required for the catalytic cracking in the reformer tubes to deliver. An appropriate use of waste heat in the flue gas vent of the primary reformer is not shown in FIG. The one emerging from the reformer tubes Methanol synthesis gas with the usual analysis is via line 8 with the necessary heat exchangers 9 cooled to lower the temperature, in order to then be fed to the compressor 10.

After the compressor 10, the synthesis gas has the required pressure for the methanol system and enters the synthesis cycle via line 11. The circulator 12 effects the necessary gas circulation in the synthesis circuit. The conversion takes place in the methanol synthesis reactor 13 by means of the synthesis catalyst to methanol instead. The pressure of the methanol synthesis is in the range of 50-150 bar depending on the type of catalyst used. The gaseous reaction mixture passes over Line 14, through a cooling stage, not shown, to the separating vessel 15. Not converted synthesis gas is returned from the separation vessel via line 16, upstream of the circulator 12. The production methanol is drawn off via line 17 and Purified to the desired quality in a distillation.

Since the synthesis gas supplied to the methanol synthesis is not the stoichiometric one Ratio corresponds, but contains too much hydrogen, the cycle must constantly A stripping stream of gas can be withdrawn via line 18. This stripping stream, which is mainly hydrogen, unreacted methane, carbon oxides, nitrogen and contains traces of methanol, dimethyl ether and water, is a purification stage 19 supplied, for cleaning to essentially pure hydrogen. The severed ones Gas portions are discharged via line 20.

The pure hydrogen gas is obtained from the purification stage via a line 21 guided into the reaction chambers 22, into which at the same time air via line 23 is directed to the combustion of a hydrogen component. The combustion will be like this led that the complete implementation of the atmospheric oxygen is guaranteed and a Ammonia synthesis gas is obtained, with a necessary for the ammonia synthesis Hydrogen to nitrogen ratio.

The ammonia synthesis gas emerging from the reaction chamber 22 is out in a known manner through one or more heat exchangers 24 and on the permissible inlet temperature for the synthesis gas compressor 26 cooled. On the Syngas compression 26 can be omitted if the syngas is a for the ammonia synthesis has sufficient pressure.

Depending on the gas analysis and the need, any unwanted To remove gas components such as CO, C02 and 02, a methanation 25 in interposed in a known manner. There is also the option of using the Air prior to introduction into the combustion reactor in a known manner from the C02 portion to clean completely.

The further processing of the synthesis gas leaving the compressors takes place in a known manner via the circulator 27 in the ammonia synthesis plant 28 of any structure.

According to Figure 2, the combustion of part of the hydrogen is off the cleaning stage is carried out in two stages. After the first reaction chamber 29, in which mixed in part of the required amount of air and reacted with hydrogen is, the gas mixture is largely cooled in a heat exchanger section 30.

Then it enters the second reaction chamber 31, in which the remainder Nitrogen is burned in the form of air. Even after this reaction it will Gas mixture cooled down to the intake temperature for the synthesis gas compression. The further processing of the synthesis gas leaving the compression takes place according to Figure 1.

According to FIG. 3, part of the cycle gas is obtained from the ammonia synthesis passed via line 32 to lower the temperature in the reaction chambers 29, 31.

The advantages of the method described are that ammonia is produced with very low energy consumption.

The capital cost of producing ammonia is very high low compared to the conventional production of ammonia.

The following numerical example serves to illustrate the invention for a plant for the joint production of methanol and ammonia according to the described Procedural concept.

The capacity of a methanol plant is 2,500 t / d methanol.

In addition, approx. 950 t / d ammonia can be produced from the stripping gas will.

The consumption of raw materials and energy for the production of In this case, methanol and ammonia are 25 GJ / t ammonia.

The capacity of the tube reformer of the methanol plant remains the same unchanged.

Claims (5)

Claims f process for the production of methanol and ammonia under increased pressure from light hydrocarbons, preferably methane a) catalytic cracking of hydrocarbons under pressure and in the presence of Steam to synthesis gas b) catalytic synthesis of the synthesis gas to methanol in one Synthesis cycle c) Separation of the methanol and a stripping stream from the Synthesis cycle d) Purification of the hydrogen-containing stripping stream for quality for the ammonia synthesis and addition of nitrogen in the synthesis ratio thereby characterized in that nitrogen is added by burning hydrogen under increased pressure with air in a hydrogen stream. 2. The method according to claim 1, characterized in that the addition of nitrogen takes place in at least two stages and after each partial combustion or after a group of partial burns, the product gas is cooled. 3. The method according to claim 1, characterized in that the air before they are burned in a purification stage on their carbon dioxide content is released. 4. The method according to claim 1, characterized in that the in the System introduced carbon oxides are removed from the synthesis gas by methanation will. 5. The method according to claim 1, characterized in that the hydrogen stream part of the synthesis gas produced is admixed.