DE388363C - Process for the production of carbonic acid and nitrogen from combustion gases - Google Patents

Description

Process for the production of carbon dioxide and nitrogen from combustion gases. The present invention relates to a process for the production of carbonic acid and nitrogen from combustion gases, both of which are gases for complete combustion its combustible components of a flameless combustion and then: a separation be subjected to carbon dioxide and nitrogen. The invention aims to be as highly concentrated as possible Obtaining products at a low cost. To this end will as raw material in .dem process in a known manner any combustion gases Origin used, especially those like those used during combustion in the cylinder of an explosion engine. This does not necessarily mean that the achievement of the Suitable for this purpose because it does not consist exclusively of carbonic acid and nitrogen According to the invention, '\ "nebulization gases are finely divided with a small amount Fuel and, if necessary, with that to achieve complete combustion The air required is mixed and then subjected to a flameless combustion of highly heated air subjected to refractory material. The admixture of fuel to the combustion gases has the consequence that the flameless combustion only using Refractory material as a catalyst can easily be carried out in continuous operation lets, whereby all flammable substances actually get to the combustion, which not That would be the case if one were to use the combustion gases as they would from normal combustion processes are available immediately for flameless combustion by contact with wanted to bring heated refractory material. The admixture of fuel too the combustion gases caused by the flameless: combustion sufficient Heat is generated to keep the refractory material at such a high temperature all the time Preserve that the process of flameless combustion is uninterrupted can go. - On the other hand, the heating of the most refractory material remains at the same time within the bounds of the process and it will be any over-excessive Avoid excessive heating, as occurs when one is muffled up alone fuel and air formed; combustible mixture the process of a flameless Subjects to incineration. Compared to such a method of using one alone consisting of fuel and air (remisches as a starting material also consists The advantage of the greater cheapness of the process, since worthless waste products, namely from?: Combustion gases originating from any combustion process, usable are made and only small amounts of fuel are required:! m the condition of the To change combustion gases under I: use of flameless combustion so that that carbon dioxide and nitrogen can be extracted from it in high concentrations.

After the combustion gases have been converted into a The mixture practically only consists of carbon dioxide and nitrogen Separation of these two components according to a further part of the invention in the Way that the gases are sequentially absorbed in water under high pressure preferably with simultaneous cooling and expansion under low Pressure are preferably subjected to simultaneous heating.

A facility for performing the procedure is on the enclosed Drawing illustrated in Fig. I.

Fig.2 shows a cooling coil with a compressor for liquefying the Carbon dioxide and separation of nitrogen.

Fig. 3 shows another embodiment of a device for compression, Absorption, ionization and expansion treatment.

Fig.q. Fig. 3 is a detailed view for explaining the cooling and heating treatment the (gases.

2 denotes a closed chamber, which is expediently with .einem refractory lining is provided and the one filling 3 made of refractory material, such as B. fragments of bricks, etc., which is intended to be in In a highly heated state, there is complete combustion of what is present in the combustion gases bring about flammable components. The combustion gases to be treated in chamber 2 are taken from a machine r 6 with internal combustion, the explosive mixture through a mixer i; is fed. The combustion gases flow through the exhaust pipe 18 and pass through the pipe 2o into the chamber 2 after they are on their way through additional reducing gas, which is fed to them through the branch pipe i9, have been enriched. The chamber 2 is supplied with air in such an amount through the pipe 21 fed as they are for perfect combustion of the in the combustion gases contained flammable components is required. The pipe 8 leads the resulting Gases to the lower part of a washing chamber 9. The chamber 9 contains porous materials io, like crushed coke. It is her through a pipe i i a drizzle of water fed. 12 is a drain pipe for the water and 13 is a from the washer a after a second washer 1q. leading prevention pipe. The washer 14 is also included porous material io 'charged and with a shower i i' and a drain pipe 12 ' Mistake. 15 denotes a drain pipe through which gases leave the washer 14.

When the gas mixture coming out of chamber 2 after washing has taken place is to be cooled and compressed, the pipe 13 is connected to a snake 22 (Fig. 2) connected, which is connected to a compressor 23, to the carbonic acid liquefy and thereby separated from nitrogen.

The process is as follows: The fresh gas enriched 'Combustion gases of the. j ## can be found at the Durchgange_ through the 1 er. 2 by te- i leadership. with your liöclierli-itzten refractories Material 3 a complete consultation then get through the tube 8 after Waschar 9, where they are cooled -, digest - and vvö a Part of the Unreirii @ alteneiten zürückge'hälte3i wind. When passing through the washer 14. käim the carbon dioxide retained. will, by putting a spray through the tube rain of alkali carbonate, e.g. sodium wastes IZaliumlcarbonät or also lime water, a = leads. This gives the I-constituents of the oleic acid and: nitrogen- desiccated only 'gas mixture .separated for itself and can -'in further process in any way. . ". - With the one shown in Fig. 3 Facility . will. worked as follows: That from Chamber 2 heta: executing Tube g11 with flap g; which also was shear ioa. leads, is to a trigger 811 with Throttle valve 8b connected: Through the exhaust ztiä 811, the combustion products can be the start of the operation are discharged into the air the,. until the fire-resistant material 3 on the the desired temperature would be brought. The throttle valves = 8b, gb are then placed so that the compound products. mit'telbar from the lower part of the chamber 2 get after the container röa. - '- The Verbteririungsrodukte, which the pour the glowing mass 3 into your container 2. flow and get into the container ioa, loading are made up of water vapor, carbonic acid and Nitrogen. The in the hot gases contained-moisture with- by means of a spray of rain. from - the tube i ob dejected it. condensation occurs, and carbonic acid - and nitrogen are left behind. These get out of the chamber iö'ä through the Pipe i i11 'to an absorption vessel zA where- aiin- they carried by the compressor iza be who they on` about. iö atmospheric 'd_ icht. ' The Gases in contact with water that passes through it one. High pressure pump i611 in the spray is shared. The. Pump 16a maintains the water circulation between the absorption vessel r311 .. and the low pressure tank i5 @ 11T Die Pump 16- sucks the water out of the 1 pressure container y511 by ääs - Roht_ i-Sb an, press 'it through ijb' @ in the. Container iy and drives it from here through 9/14 and the spray pipes id.b after I511. ` Under ordinary circumstances, ie at Atmospheric pressure and a temperature of around 15 ° C, the water dissolves in a room is about one unit of carbon dioxide, so that against only 0.075 spatial units of nitrogen. However, if the gases come into contact with water , see at the same @ Teiriperatrtx of about 5 ° C, but under .one. Pressure from iö. Aüüosplrären -be brought in, where you wiM .. about the time- multiple UM units of space from everyone: clex beicfien Gases in eifier: kauinerriheit @ ä: sser leäst. _ @ - Under the. Bediiibungen`: des vörliegeüden If Xäturbas, as B "renn- stöff verbtxrint v @ rird ,. a GaAmisfhmnr- liälten, .die äniieherrid. iö rozent.Kölileüstöff- dioxide. contains üüd gö percent nitrogen. So when the mix is up. i-ö Atmosä- ren compressed. will, .däiiü leaves a couple tialdruck von i Atmösphaxe Carbonüstö9diöxyd and 9 atmospheres Sticksiöff, un@d_.die. Gas- the amount of water taken from i Rätiiizenlieit is resolved, is iauineiiheitIöhle-nstöff -dioxyd and 0.15'-75 units of nitrogen. - The water which these released guests'erit holds, goes through the tube rq_d into the low pressure vessel i5ä; its IVJrhrderdrucl rlufh the sucking pulse r8d is maintained. That whole carbon dioxide and nitrogen emerge from the solution, with Aüsnahtne the Amounts that prevail in z.5'11 Partial pressures and the teriipereture solved will hold. Exists under ordinary circumstances the gas that the water. in the container i511 leaves, out approximately. 8.Prözeiit Köhlen- substance dioxide and nitrogen. Dftse Gas mixture is then zsa through the container Pump i8a = take in and. then under high Pressure., In the 1I-ochdmck container. 2ö11 eA- led; where the just described Vörgäug is essentially repeated. At your high Pärtiäldruck..dss I <-ohlensioff- dioxyds and the low partial pressure .des Sticksfoffes exist, which in the absorption vessel 2ö11 dissolving. Gases approximately from 99.5 percent carbon dioxide, yd and -küm ö, 5 percent. Stfelrstofh The solution - this one , Gases gell .from the A1xserptiön container zba through the Zia pipe to the low pressure ter z211 w11 under your diminished Dtuek der grä9te. Part of desolate I <ohlefistuffdoxyds from the Water escapes from the container .Pipe 22a is removed and then compressed. The water in your spring pressure vessel 22a is placed in - the liochdrtrcle container 269. by Pttinpe 23a pushed back; the ö) ire.2ia arid tob tiiünderi in spray nozzles. The um-, deloste gas io = the high pressure absorber 'tiörisgefä @ i311; cläs at @ s nfiäefälzr g8,5 @ '' rozent Nitrogen and 1.5 percent carbon dioxide exists, goes through the tube 24a; the from -the upper part of the container into the height- rlruckabsorptionsbehälter_a5a leads; through which Solution in water more carbon dioxide from the nitrogen is separated; and flows : tann through the pipe 26a to the low-pressure container 27a closed. . If the gas mixture is successively subjected to absorption by water under pressure and expansion, the content of carbon dioxide is reduced more rapidly than the nitrogen content, because the carbon dioxide is absorbed more quickly.

The circulation of water between container 27a and absorption vessel 2111- is maintained by pump 28 "and pipes 27b and 25a opening into nozzles. The nitrogen under about 8 to 9 atmospheres pressure, which then contains less than 1 percent carbon dioxide , goes through pipe 29a into the washer 3o11, which is partially filled with absorption material such as lime or caustic soda, Ya and provided with an atomizing nozzle 32a. In this container the last traces of carbon dioxide are removed and the nitrogen passes through the outlet 33 " to a suitable collection container.

The pressures in the low-pressure containers 15d 22a 27a can, if desired, be obtained by vacuum pumps at a very low level and the gas mixtures from the container 2o11 and 27a can either. can be returned through pipe 3q.11 to the pump iäa to recirculate, or they can be drained through valve 3511.

In practice it has been found to be advantageous in the absorption container 13 "a pressure of about 10 atmospheres and in the container 25.1 such a _ maintain from about 8 to 9 atmospheres; however, it can also be higher or lower pressures are applied. There can also be apparatuses that control the pressure take advantage of how turbines are turned into tubes 142a, Zia and 2611, thus the pressure drop between the containers connected by them made usable can be. In this way you can get a large part of the time needed to operate the pumps gain the necessary strength. There can also be automatic valves between the different Containers are arranged to keep the desired pressures as constant as possible obtain. The gaseous products coming from an internal combustion engine can, depending on their composition, either alone or with a sufficient number Amount of gases mixed with a carbonaceous fuel. Instead of the used water from the low pressure tanks repeated after the high pressure tanks To pump, it can be drained from the low-pressure tanks and the high-pressure tanks fresh water can be supplied through the various pumps. .

The process can also be used for the separation of carbon dioxide from other gases, such as nitrogen, carbon monoxide, etc., can be used.

Regarding the absorption of the gases by water under high pressure and their escape from the water under low pressure, it is noted that, j The lower the temperature of the water, the greater the solubility of the carbon dioxide is in the high pressure vessel 130; the reverse is the solubility of carbon dioxide the lower, the higher the temperature in the low-pressure vessel 1511 is until the solubility is reduced to zero when the boiling point is reached. So is in Fig. 4. High-pressure container z311 shown, with a cooling coil 36d is provided, which is connected to any device that has a circulation pressure generated, creating a refrigerant such as alkali or ammonia; be set in motion can to lower the temperature of the water in the container. The low pressure tank i511 is equipped with a similar coil 37d through which a heating means, like steam or hot water, is conducted to raise the temperature of the water.

Claims (1)

PATENT ANSPRUci3: Process for the production of carbonic acid and of Nitrogen from combustion gases, in which these gases are used for complete combustion their combustible components of a flameless combustion and then a separation in carbon dioxide and nitrogen, characterized in that the Combustion gases obtained by an ordinary combustion process, preferably Exhaust gases from explosion engines before going over to preserve the flameless Combustion serving highly heated refractory material are passed, finely divided Fuel, preferably combustible gas, and optionally those to achieve the air required for complete combustion is added.