DE3422067A1 - Process and apparatus for eliminating SO2 and/or nitrous gases from exhaust gases - Google Patents

Abstract

To eliminate SO2 and/or nitrous gases from exhaust gases, the exhaust gas is treated with nascent hydrogen and/or nascent oxygen, the hydrogen and oxygen used for the treatment being generated by electrolytic decomposition of water. For this purpose, at least two zones electrically polarised in pairs are provided in a housing one above the other, through which the exhaust gas to be treated successively passes.

Description

Method and device for removing SO,

and / or nitrous gases from exhaust gases The invention relates to a method for removing SO2 and / or nitrous gases from exhaust gases. Also affects the Invention an apparatus for performing this method.

With firings that are operated with fossil fuels, arise exhaust gases containing sulfur oxide. Even in the large-scale production of sulfuric acid exhaust gases containing S02 are produced.

Furthermore, nitrous gases are produced during combustion processes with air (NOx) depending on the combustion temperature and the length of time in the combustion or furnace chamber. In concentrated form, nitrous gases are produced in the production of nitric acid and in all pickling processes in which nitric acid is used alone or in a mixture will.

Exhaust gases containing sulfur oxides and nitrous oxide form a considerable burden on the environment, especially in inversion weather conditions. In addition to the health hazard to humans and animal - inflammatory reaction of the mucous membrane of the respiratory tract with restriction lung function - Accelerate exhaust gases containing sulfur oxide Corrosion and destruction of metals, paper, textiles and building materials. The nitrogen oxides Along with sulfur oxide, they are among the most unpleasant air pollutants. Too high concentrations lead to complaints in humans and animals and to damage to plants.

More than 80 ~ of the flue gas desulphurisation systems work according to the Washing principle, whereby the neutralizing agent is almost always a milk of lime suspension is used and calcium sulfite is formed. Because calcium sulfite is water-soluble and toxic it must be oxidized to calcium sulphate (CaSO4) in special processing plants, deposited and thickened. It should be noted that the formation of Gypsum (CaSO4 2H20) only by adding an additional acid before and during the oxidation process is possible by reducing the pH to the water-soluble and oxidizable Ca (HSO3) 2 is obtained. There is hardly any use for the calcium sulphate sludge, like that that this is almost always deposited as hazardous waste under extensive protective measures must become.

Rees reported in 1957 ("Air pollution: causes, effects, Countermeasures, issued by the World Health Organization 1961) over the Fulham Simon Carves ammonia process, in which the sulfur dioxide is made with ammonia water Gas works and coking plants are washed out of the exhaust gases. As the end product arise Ammonium sulfate and sulfur. Because of the high expenditure on equipment, the operating costs are this process is considerable, so that it is only economical if that Sufficient ammonia water in the immediate vicinity of the flue gas desulfurization system and a reasonable price can be obtained for the ammonium sulfate.

Recently the nuclear research facility Jülich GmbH reported that there a process has been developed according to which gases containing SO2 have a high detoxification performance can be cleaned. The process is based on certain catalysts Electrochemical oxidation and reduction processes simultaneously without external power supply expire. The end product is created. Sulfuric acid.

So far there is no such thing as separating nitrous gases from combustion exhaust gases Process known that works with sufficient efficiency and with economical reasonable means can be operated.

In the manufacture of nitric acid, nitrocellulose and others Explosives, diazzo dyes and all pickling processes in which nitric acid Used alone or in a mixture, nitrous gases (emergency) are produced in concentrated form Shape. These nitrous gases, as well as in the combustion exhaust gases, exist predominantly from a mixture of NO and N02.

While nitrogen dioxide (NO2) in an alkaline aqueous solution can be washed out with satisfactory efficiency, nitrogen monoxide (NO) -Solubility approx. 5 before =% in H20 - hardly reduced by such a treatment. Recently, multi-stage systems have been used for absorption systems, e.g. behind pickling systems recommended, in which one or more washing stages oxidizing with the addition of ozone or other oxidizing chemicals. The multi-stage systems improve the scrubbing effect for nitrous gases, but can be sufficiently efficient cannot be achieved with an economically justifiable effort.

The invention is based on the object of showing a way how SO2 and / or nitrous gases with economical means and satisfactory efficiency can be eliminated from exhaust gases.

This object is achieved according to the invention with a method that has the features of the characterizing part of the main claim. Also will this object is achieved with a device having the features of claim 4. Beneficial Refinements of the invention are the subject of the respective subclaims.

The separation of nitrous gases takes place according to the invention 1. by reducing the NO and N02 to NH3 and / or N2 using nascent hydrogen, 2. by oxidizing the nitrogen oxide (NO) using oxygen in statu nascendi to NO2 according to the following simplified formulas: Gl. 1) NO2 + 14 H + 2 NH3 + 4 H20 Gl. 2) 2NO + 4 H 4 N2 + 2 H20 Gl. 3) 2N02 + 8 H # N2 + 4H20 Gl. 4) (NO + N02) + 0 -> 2 NO2 Gl. 5) 2NO2 +2 Me ++ 2 OH-> MeNO3 + MeNO2 + H2O Gl. 6) 2 NO2 + 2 NH4OH> NH4NO3 + NH4N02 Gl. 7) 2NO + ° 2> N2O4 Gl. 8) N2O4 + H20> HNO3 + HNO2 Gl. 9) 3 HNO2> HNO3 + 2 NO + H20 The above formulas are idealized. NO can also be reduced directly to NH3. The nascent gases (H and O) are generated by the electrolytic decomposition of the water.

Jander-Spandau's textbook on inorganic chemistry is on page 197 (5th edition) mentions that hydrogen in statu nascendi is capable of nitrates to reduce to ammonia. However, this textbook gives no indication of how this process is to be implemented in industrial practice.

The separation of gases containing sulfur oxide from exhaust gases takes place according to the invention 1. by washing with water and neutralization with NH3, 2. by oxidizing the ammonium bisulfite 5 obtained during the neutralization to ammonium sulfate (artificial fertilizer) by means of oxygen in statu nascendi according to the following simplified formulas: Equation 10) x S02 + y S03 + (x + y) H20> H2SO3 + y H2SO4 Equation 11) x H2SO3 Y H2SO4 + (x + y) NH3 # x (NH4) HSO, + y (NH4) 2SO4 Equation 12) (NH4) HSO, + 0 + NH3> (NH4) 2 SO4 The above formulas are idealized. The sulphurous acid can also be oxidized directly to sulfuric acid.

The nascent oxygen is beneficial through electrolytic Decomposition of the wash water generated.

The separation of gases containing sulfur oxide takes place from combustion exhaust gases according to the invention on the same principle, but in this case the required NH3 partially recovered through the separation of nitrous gases, # provided the combustion takes place with air.

The exhaust gases to be cleaned are in one or more pairs arranged anodically and cathodically polarized areas washed. The watery one Electrolyte solution is created by the kinetic energy of the exhaust gases on the floors of the Washer kept. The gas speed is to be selected or the bottoms are to be dimensioned in such a way that rain is avoided (floating bed).

Such a washer is advantageous when the amount of exhaust gas fluctuates operated according to the washing bottle principle, with the exhaust gas passing through one or more pipes distributed is passed into the electrolyte solution and then one or more flows through areas arranged in pairs.

Other types of washer can also be equipped according to the invention.

Are there any other pollutants in the exhaust gas, e.g.

F and Cl, or dusts, is an upstream cleaning stage for the end product beneficial. If slightly in the deposition of sulfur dioxide Fluoride penetrates through the upstream cleaning stage and these in the purification stage according to the invention get into the electrolyte as ammonium fluoride, can do this by adding lime stoichiometric to the non-toxic fluorspar implemented.

Are only nitrous gases, e.g. in the production of nitric acid or are formed during pickling, converted into NH3 by this process, the ammoniacal aqueous solution used for the neutralization, e.g. of old stains will.

Provided that the exhaust gas contains both nitrous gases and those containing sulfur dioxide Gases are contained, neutralizes that obtained by converting the nitrous gases Ammonia the sulphurous acid and sulfuric acid.

If there is a deficit of ammonia, NH3 gas or ammonia water is appropriate Add amount.

Advantages of the invention: a. The invention can both eliminate Nitrous and sulfur dioxide-containing gases from exhaust gases can be used. she is particularly advantageous if both harmful gases are present in the exhaust gas, because then wholly or partially that required for the neutralization of the gases containing sulfur oxide NH3 is generated by the separation of the nitrous gases.

b. Because of the high solubility of the ammonium sulphate, there is no accumulation in the washer, pipes, etc. This results in a very high availability the system or a very good efficiency.

c. When eliminating gases containing sulfur dioxide, the end product is In contrast to the processes used so far, no waste product, but artificial fertilizer (Ammonium sulfate).

d. In a heat exchanger connected upstream of the exhaust gas cleaning system the waste heat from the flue gases can be used to evaporate the ammonium sulphate brine.

e. With appropriate dimensioning, an absorption efficiency for sulfur dioxide and nitrous gases of well over 90% can be achieved.

f. The adaptation of the system to fluctuating pollutant gas concentrations is by regulating the current strength and by the NH dosage during the separation easy to control of sulfur dioxide.

The invention produces exhaust gases containing sulfur dioxide and / or nitrous (NOx) that occur in combustion processes, in nitric acid production, in pickling, Yellow burning or similar technical processes are caused by oxygen and hydrogen in statu nascendi, which is advantageously produced by the electrolytic decomposition of water are cleaned so that harmful environmental influences are avoided.

The nitrous gases (NOx) in aqueous solution become NH3 and / or N2 reduces and becomes the poisonous obtained from the neutralization of sulfur dioxide Busulfite is oxidized to sulfate, so that when using NH3 as a neutralizing agent the end product is not waste, but artificial fertilizer. It can be both nitrous as well as sulfur dioxide-containing constituents or both are removed from exhaust gases will. The nascent gases used for this purpose are advantageously by one or Generates several anodically and cathodically polarized areas arranged in pairs, in particular as bubble trays, sieve trays or perforated trays or similar.

can be trained.

The drawing shows schematically an embodiment of an inventive Washing device to remove sulfur dioxide and / or nitrous gases Exhaust gases shown in side view.

The device contains in a standing housing 1 over a closed one Floor 2 a. Gas distribution system 3, two intermediate floors 4 and 5, which sieve or Perforated bottoms or bells can be, above several washing nozzles 6 and above them one across over the housing 1 extending droplet separator 7th

The exhaust gases to be treated will be just above the floor 2 arranged nozzle 8 introduced, while the treated exhaust gases the housing 1 through a further connecting piece 9 attached to the upper end of the same as indicated by the arrow 17 leave.

The intermediate floors 4 and 5 each have an electrical connection 10 and 11 provided and each consist of two sub-floors arranged in pairs 4a and 4b or 5a and Sb. Via the electrical connections 10 and 11, respectively the intermediate floors 4 and 5 can either be anodically or cathodically poled.

The exhaust gases to be treated are shown in the gas distribution system 3 evenly distributed over the base of the housing 1 before going up flow through the intermediate floors 4 and 5. These intermediate floors form reaction zones and through the washing nozzles 6 arranged above them with a washing liquid, preferably an aqueous electrolyte solution, sprayed. Through the kinetic energy of the exhaust gases flowing upwards, the washing liquid is permeable to the Intermediate floors 4 and 5 held, the gas velocity being chosen so that in connection with the dimensioning of the intermediate floors or those contained therein Holes prevents the washing liquid from raining through the intermediate floors. With the washing liquid in the area of the intermediate floors, a so-called Floating bed formed.

Excess washing liquid can be poured through an above the intermediate floor 5 connected overflow 12 run into a storage tank 13 for washing liquid.

On this storage tank for washing liquid is a pump 14 and a Line 15 leading to the washing nozzles is connected.

Washer fluid retained on the droplet separator 7 can be transferred to the Intermediate floor 5 drip or run down and thus also comes back in the circuit of the washing liquid.

Claims (7)

Claims: Method for removing SO and / or nitrous Gases from exhaust gases, that is, that the exhaust gas with in statu nascendi and / or with in statu nascendi Oxygen is treated. 2. The method according to claim 1, characterized in that the for the treatment used hydrogen and oxygen by electrolytic decomposition generated by water. 3. The method according to claim 1 or 2, characterized in that the nitrous gases in aqueous solution can be reduced to NH and / or N2. 3 4 Device for performing the method according to one of the claims 1 to 3, characterized in that they are in a housing (1) one above the other at least has two electrically polarized zones (4, 5) in pairs, which are successively from the exhaust gas to be treated flows through. 5. Apparatus according to claim 4, characterized in that the individual Zones of intermediate floors built into the housing (1) and diverting the flow of exhaust gas (4 and 5) exist. 6. Apparatus according to claim 5, characterized in that over the Intermediate floors (4, 5). a washing device (6, 15) is arranged. 7. Apparatus according to claim 5 or 6, characterized in that above the intermediate floors (4, 5) and the washing device (6, 15) in the housing (1) Droplet separator (7) is arranged.