DE1494807A1 - Regeneration process for gas washing to clean fuel or synthesis gases - Google Patents

Description

Regnerierverfabren for gas scrubbing For cleaning fuel or synthesis gases The process for the purification of technical fuel and synthesis gases as z. B. off solid or liquid fuels produced, obtained as natural gas or by conversion gaseous fuels are obtained, are used primarily to remove the acidic components, sulfur compounds and unsaturated hydrocarbons from the raw gas. As a rule, carbon dioxide takes the largest part in terms of volume and hydrogen sulfide.

There are numerous methods for solving the cleaning task mentioned become known, technical importance have ZZZ including in particular the absorption methods obtained, according to which the gas of a single or multi-stage scrubbing with liquid Absorbent is subjected to the Gaaverimpurities according to their Absorb solvency from the gas at the same time or one after the other, on it then regenerated and released the absorbed gas components then be fed into the GasuäsOha circuit. One can do this absorption method Divide roughly into two groups: those with chemically acting absorption agents and those with physical effects.

The first group includes, in particular, those with aqueous solutions of inorganic or organic Baaen or alkali salts of weak inorganic or organic acid washing processes. They are subject to the stoichiometric Laws, usually also have one of the selected set of acidic components prop @ tional Steam consumption for regeneration and are therefore primarily suitable for removal of weakly to moderately concentrated acidic impurities in the raw gas as well as for Cases where cheap heat is available.

If, on the other hand, it is a matter of cleaning large amounts of gas with high Keeping the acidic components to be removed, eo one uses in increasing Physical washing process dimensions.

Unlike the chemically acting absorbents, it is attached given amount of raw gas is the amount required to remove a single component Amount of detergent for a physically active absorbent other than the temperature-dependent one Solubility coefficients in the first approximation only depend on the total pressure under which the Washing done, from. The solubility of a gas in the washing liquid increases with falling temperature and rising pressure. The regeneration takes place accordingly by reducing the pressure (relaxation) and / or by increasing the temperature. The advantages the physical washing process in terms of capacity and energy requirements occur the more pronounced, the higher the pressure Bes of the gas to be cleaned, because On the one hand, as the gas pressure rises, the amount of detergent required for cleaning decreases and on the other hand, the regeneration can to an ever greater extent by pure Relaxation of the detergent can be accomplished.

The oldest and probably also the simplest gas scrubbing process with one physically acting absorbent is the leaching of carbon dioxide with Water under pressure.

Newer processes use organic solvents. For use Simple organic substances such as methanol, acetone, heptone, toluene, xylene are low-temperature washing processes have been developed in which the absorption at temperatures from -10 ° to about -50 oC takes place. Higher-boiling detergents, of which, for example, dimethylformamide, Propylene carbonate, simple polyglycol ethers and also Qykol selbet, N-methypyrrolidone, Butyralactone and some other widespread uses allow one Absorption at ambient temperature.

In the case of the physical absorption of gas impurities can only a limited selectivity towards the valuable useful components of the raw gas be achieved. When removing the troublesome raw gas components, etets a, if usually a very small part of the useful components CO, H2, CH4 are also absorbed. Man you can partially recover it by removing the detergent after leaving the Absorption tower is only moderately relaxed at first, so that primarily only the im Detergent, little useful components escape and then back into the Compressed gas can be recompressed. Only after this preliminary relaxation does the actual regeneration of the loaded absorbent through further relaxation to normal or sub-atmospheric pressure and / or heating and / or, or Drifting with a stripping gas.

The energy expenditure for the recompression of the e * en pre-relaxation Recovered useful gases is increased, however, that one with as possible extensive recovery of the useful components also a more or less large one Ballast of acidic gases, which also occur during the partial expansion of the detergent must become free, must condense. When recovering z. B. 90% of the co-absorbed Useful gases are often desorbed with a multiple of acidic gas components, so that the gas to be recompressed only about 20% from these useful gases, but 80% consists of acidic gases, mainly C02. That's why you have this pre-relaxation gape often also burned as lean gases in an underfiring.

It is known that these pre-expansion gases are also desorbed acidic gas components in a special wax stage with fully regenerated absorbent can largely wash out again.

This way of working has generally proven to be too expensive, because the effort usually bears no relation to the success achieved.

It was found that the recovery of the addition of acidic gas components with absorbed useful gases can be significantly simplified, and that the sur recirculation Recompression work required of the recovered useful gases in the raw gas flow can be significantly reduced if the useful gas-containing exhaust gas of the first before relaxation gewasohen with a partial flow of the partially regenerated absorbent is washed out and only a considerable proportion of the acidic gas components are washed out again will.

It is sufficient to check the acidic component content of the pre-expansion gas initially from, for example, 80 vol. to 20 tol. to belittle. This is the initial volume of the useful gas-containing expansion gas is reduced to a quarter and is accordingly also the work of recompression is smaller.

For the method of operation according to the invention, it is sufficient in the relaxation tower, in which the first pre-relaxation is carried out, above the actual relaxation zone to arrange a reabsorption zone in which the rising expansion gases in the Counter-atom with partially regenerated absorbent trickling down for mass transfer been brewed. The partially regenerated absorbent takes a considerable amount Part of the acidic gas components and then combines in the relaxation zone with the pre-relaxed absorbent of the hemp washing cycle.

The enriched useful gas flows through the reabsorption zone Pre-expansion gas and is preferably returned to the raw gas by a compressor.

However, this pre-expansion gas enriched in useful gas can also be given for heating purposes. This is how its calorific value is due to the C02 leaching high that it can be added to the usual supply gases such as town gas or long-distance gas can.

In the two figures are the flow diagrams of two embodiments of the method according to the invention, for example.

Fig. 1 is the flow diagram of a plant in which the fine regeneration the loaded absorbent by boiling after relaxation to ambient pressure he follows.

Fig. 2 is the flow diagram of a system in which the fine regeneration the absorbent is carried out by stripping it with a stripping gas.

Both flow schemes are correct with regard to the absorption tower and the Main regeneration of the h @ adenous absorbent by detachment to ambient pressure completely agree. With regard to the xein regeneration, they differ in their execution of the regeneration tower. Accordingly, the same parts are shown in the two figures provided with the same reference numerals. The fine regeneration towers, which are only different in design are with 3 baw. 4 designated.

Both systems essentially consist of the absorption tower 1, in the gas to be washed out of the gas to be cleaned under pressure be absorbed in an organic solvent, from a multi-stage expansion tower 2, in which the loaded absorbent gradually relaxes to ambient pressure and is degassed, from a regeneration tower 3 or 4, in which the expanded absorbent is finely regenerated by boiling or stripping and from the recompressor 5, the the useful gas recovered in the preliminary expansion and enriched according to the invention promoted back into the raw gas stream.

The absorption tower 1 stands for a gas cleaning system which, as shown, one or more absorption towers operated with the same absorption medium May contain absorption towers.

At 6, the raw gas occurs at increased pressure, e.g. B. 90 - 80 at, in the Washing tower 1 a. Be in countercurrent exchange with the detergent applied at 8 here the impurities, mainly acidic components such as 002 and H2S, from the compressed gas taken up by absorption in the detergent. The purified gas leaves the washing tower through line 7, the loaded detergent through line 8. Via the Relaxation device 10, it reaches the relaxation stage 1i, in the corresponding Part of the dissolved gases is released under the reduced pressure.

The upper part of the expansion stage is designed as a reabsorber, in which at 12 abandoned, coarsely regenerated detergent part of the ascending detergent Flash gas contained backwashes acidic components. Of the The remainder of the expansion gas, which mainly consists of valuable gases, is used by the recompressor 5 brought to the raw gas pressure and via the line 13 and the cooler 14 in the Wash tower 1 out. After the preliminary relaxation in chamber 11, the detergent arrives via lines 15 and 19, and expansion devices 16 and 20 below further pressure reduction in the depressurization chambers 17 and 21. The escaping here Gases are discharged through lines 18 and 22. From the last stage of relaxation which is usually operated at around atmospheric pressure, is the detergent promoted by the pump 33 through the line 23. It is then so largely degassed that there is again a noticeable solvency @ for those in the relaxation stage 11 has ascending ballast gases.

Is z. B. the pre-expansion stage 11 operated at a pressure of 8 ata the expansion gas escaping from the detergent at 10 has a C02 content of 75%, so that its partial pressure is 6 ata, and one can further assume that in the last expansion stage 21 only CO2 at a total pressure of around 1 ata degassed, so in the borderline case also in the upper part of the pre-expansion stage ii the C02 partial pressure can be lowered to about 1 ata, resulting in a volume reduction of the pre-expansion gas by around 70%.

The amount of detergent required for reabsorption is determined a partial flow branched off from line 23 and over the control device 24 directed to the reabsorber. The rest of the detergent goes through the heat exchanger 25, in which it is warmed up by fully regenerated detergent, to the regeneration column 3. In this column, which with the heating device 29 and the cooling device 27 is provided, the detergent is boiled out of the remnants of the still dissolved Gases released. These leave the system via line 28. The regenerated detergent is withdrawn via line 90 and from pump 31 via the heat exchanger 25 and the cooler 32 again conveyed to the head of the Wasohturm 1.

A very similar pattern emerges if you add the detergent relaxation not by boiling, but completely regenerated by stripping. The regeneration column 3 with the associated heat exchangers is in this pallet Replace 25, 26 and 29 with a stripping column see below.

Figure 2 shows a special variant of a gas cleaning system shown with Btrip regeneration of the detergent.

With regard to the pre-expansion, the system according to Figure 2 is the same as the one practically identical according to Figure 1, so that only the path of the detergent according to Leaving the last stage of relaxation needs to be followed closely. In the wide For example, it is assumed that the solution is based on management 23 Wasohmittel leaving the relaxation tower 2 is not yet sufficient to im Reabsorption part of the chamber 11 has a sufficiently high proportion of ballast gases to be able to remove the expansion gas. This is 8. B. then the Case when the cleaning of the raw gas takes place at less high pressure, so that too the pressure of the chamber 11 must be correspondingly largely reduced to a sufficient extent to recover a large part of the value gases that are also absorbed. Since usually the The pressure of the chamber 21 is close to atmospheric pressure, can then be su small Pressure difference between the chambers 11 and 21 and a corresponding small load compartment ability of the detergent. One can use the absorption capacity of the reabsorption Increase the detergent required without adding the pain regeneration level burden by subdling the further regeneration of the detergent as it Figure 2 testifies. The fan 40 pushes the inert gas through the two exchange stages 39 and 34, which are connected to one another with the gas transfer 41 and then together with the tripped gases into the exhaust pipe 35. On the head of the upper exchange stage the relaxed detergent is conveyed by pump 33 and by the rising gas partially regenerated by stripping. The detergent is taken from the bottom of the stripping stage 34 withdrawn through line 36. Part of it is turned upside down by pump 37 at 12 the first relaxation stage, while the rest via the control device 38 reaches the second stripping stage 39, in which the detergent is as completely as possible being tripped off. The pump 31 then sucks in the regenerated detergent via the line 30 and springs it back onto the washing tower 1.

From the two figures 1 and 2 it can be seen that the Zur Reabsorption In the first expansion stage (11) the detergent did not go through the fine regeneration (3 or 39) is performed. This additionally circulated detergent therefore causes almost no additional consumption of resources.

In case 1, the increase in investment costs is limited to an insignificant one Enlargement of the pump 33 and the flow cross-sections of the expansion tower 2.

In case 2 there is also the pump 37 and a slight enlargement the flow cross-sections of the regeneration stage 34 required.

Claims

Claims (1)

P A T E N T A N S P R Ü C H E 1) Remaining for the regeneration of a organic solvent that acts as a physically active absorbent in one Process for cleaning pressurized burning and Sythesegaee with the su absorbing Gas impurities are loaded, through multi-stage relaxation and heating and / or stripping the relaxed absorbent, characterized in that that escaping from the loaded absorbent in the first expansion stage Gas mixture in a arranged above the feed line of the loaded absorbent Reabsorption zone with further relaxed absorbents from a subsequent one Relaxation stage is washed and that the at the head of the first relaxation @ en @ Derived washed expansion gas to the pressure of the raw gas to be cleaned compressed and fed back into dieaes or released as high-value gas. 2) Method according to Ansp @@ ch 1, characterized in that the into the Reabsorption zone as scrubbing liquid contains absorbent at atmospheric pressure is relaxed and by means of a pulp to the pressure of the erate relaxation stage is promoted. 5) Method according to claims 1 and 2, characterized thereby, that the absorbent expanded to atmospheric pressure before the return is further exl @ g @ st on the reabsorption sone by stripping.