HU182593B - Process for purifying contaminated gases, and/or vapors or air - Google Patents

Abstract

The present invention relates to a method for purifying contaminated gases and / or vapors or air, gases and / or vapors emitted from technological equipment, or to the organic compounds of water-soluble and aerobic microorganisms that can be used as a nutrient source, and which are flammable and / or toxic to health. washing with water. The process according to the invention is carried out by supplying to the water flowing into the gas scrubber - living and absorbing sludge adapted to the biodegradation of the organic pollutants of the gas, while the gas to be cleaned is continuously fed into the gas scrubber, the washing liquid is flushed with a liquid. they are fed into the post-reactor space, where the decomposition is carried out under known conditions of aerobic biological processes, and the wash liquid exiting the post-reactor is returned to the gas scrubber, if necessary after separation of the resulting fluffy sludge mass by known physical operations 20. 182593 -1-

Description

The present invention relates to a process for the purification of contaminated gases and / or vapors or air. The solution involves the removal of flammable and / or health-toxic organic compounds of gases and / or vapors or exhaust air from process equipment that can be used as nutrient sources by water-soluble and aerobic microorganisms.

According to the invention, activated sludge is adapted to and / or adapted to biodegrade the organic pollutants of the gas into the water flowing into the scrubber, while the gas to be purified is continuously introduced into the scrubber, and the washing liquid is then vented. where the decomposition is continued under conditions well known in the art of aerobic biological processes and the washing liquid from the post-reactor is recycled back to the scrubber, if necessary, after separation of the excess fluffy sludge mass produced by known physical operations.

It is known that in the chemical industry - and often in the technological processes of other industries as well - it is a very important job and environmental task to efficiently decontaminate the organic compounds in the air leaving the equipment and / or in the protection of workplaces to prevent atmospheric pollution. (Chemical Wastewater and Air Pollution. Grade 6, pp. 78-90, Budapest, 1973).

Depending on the frequency and variety of air pollutants that are harmful to the environment, various technical solutions are known for the removal of pollutants. [Chemical wastewater and air pollution. 3rd year No. 3 32-41. She. Budapest, (1970); Chemie Ingenieur Technician, 45k. No. 1 21. (1973); Ifedi, C.N .: Sereeníng study'to development baokground information and determining the significance of air contaminant emissions frorn pesticide plants. Environmental Protection Agency Office of Pesticide Programs Strategies Studies Unit. National Technical Information Service Washington (1975).]

Known solutions include combustion, catalytic oxidation, filtration, adsorption, absorption with water or organic solvents, chemical separation with, for example, acidic, basic and / or oxidizing reagents. Water washing is often used. Aqueous scrubbing of contaminated gases is generally effective when the contaminants to be removed are water soluble and the contaminant concentration of the gas phase in equilibrium with the aqueous phase falls below the limits specified in the Air Pollution Regulations.

It is known that the concentration of contaminants remaining in the exhaust gas can be reduced, inter alia, by increasing the amount of washing water, the number of units connected in series and preferably countercurrent, or by improving the material transfer characteristics. [V. M. Ranrm: Absorption Methods in the Chemical Industry, Budapest (1953); R. E. Treybal: Diffusion Chemical Operations. Budapest (1961); No. 163343 Hungarian patent specification.]

For example, when washing gases is intended to remove impurities of an acidic or alkaline nature, the addition of an alkali (e.g. acetic acid) or an acid (e.g. ethanolamine) to the wash water increases the capacity of the absorbent fluid and the efficiency of the gas purification.

However, known methods for increasing the efficiency of water washing also present numerous operational and environmental problems. Increasing the amount of washing water, for example, is counter to the increasing efforts to save water. Although the absorption capacity of acidic or alkaline washing liquids by salt formation is greater than that of certain organic compounds than pure water, it also has several disadvantages. Beyond chemical demand and corrosion, it is difficult to place concentrated solutions where they cannot be utilized in production technology or regeneration. It is noted, however, that in the latter case, high salinity solutions are usually drained as secondary contaminants, which are also undesirable from an environmental point of view.

The main object of the present invention is to provide a process for the separation of organic compounds that can be utilized as a nutrient source in exhaust air, water soluble and aerobic microorganisms to be used as a nutrient source for exhaust gases and / or vapors from process equipment, optionally to prevent contamination of work areas. it ensures a constant efficiency, that is, no enrichment can occur.

Surprisingly, it has been found that the cleaning efficiency of the washing liquid containing activated or activated sludge is more favorable than that of pure aqueous washing liquid used under the same conditions.

According to the invention, the gas to be purified which, as an organic contaminant, is a water-soluble and biodegradable compound or compounds such as methanol, ethanol, formic acid, acetic acid, methyl acetate, ethyl acetate, acetone, methyl ethyl ketone, monoethanolamine, formaldehyde, phenol , xylene, cresol, etc. containing, contacted with an aqueous wash liquid inoculated with adapted microorganisms in a wash tower.

For this purpose, activated or activated sludge from municipal wastewater, from sewage treatment or settling basins, can be used. Microscopic examination of the activated sludge showed that it consisted of a colloidal mass populated with an infinite amount of microorganisms. Microbiological analyzes have shown that the activated sludge contains many bacteria. In one gram of dry sludge their number reaches 10 ¹³ . The species distribution is also significant and the sludge contains a great variety of microorganisms. Even the most demanding organisms, such as nitrifying bacteria, contain about 30 million per gram.

The activated sludge may optionally be used directly in the present invention or in the use of coal

Depending on the material used, it will be used after pre-adaptation.

Adaptation refers to the process of combining the aerated active sludge with the contamination to be removed, whereby, over a period of time, the bacteria that degrade that contaminant proliferate to the detriment of the others, thereby improving the efficiency of the sludge. During adaptation, the bacterial mass present in the system forms an enzyme suitable for the degradation of a substance that has not been degraded or degraded. During adaptation, the cells move from the inactive state to the highly active reproductive state within a few hours (incubation period). (Logarithmic proliferation stage). the incubation period is delayed, and the bacteria begin to reproduce at full speed immediately.

Contacting the gas to be cleaned with the washing liquid containing activated sludge is, for example, a grid or screen, venturi, agitator, turbine spray or bubbling chamber, etc. and the liquid thus formed is introduced into an aeration reactor space where the initial decomposition of the organic matter is completed. This is where the nitrogen and phosphorus nutrient supplementation needed to provide the aerobic biological process itself is carried out, preferably e.g.

NH ₄ OH, (NH _{4) 2} HPO _4, (NH ₄₎ H ₂ PO _4i (NH ₂₎ CO .., H ₃ PO ₄ addition - and optionally also to make the necessary pH adjustment. The pH should preferably be in the range of 6-8,5. The aqueous slurry suspension containing the aerobic microorganisms thus obtained is returned directly or optionally, for example, after settling or centrifugation, depending on the type of scrubber. The process according to the invention ensures that the removed organic materials do not become concentrated in the washing liquid even when recirculating water is used, and thus, in continuous operation, a gas purification can be provided in a constant and efficient manner.

In addition to its high efficiency, the process according to the invention has the great advantage of operating with minimal use of water and chemicals, and the organic compounds isolated during gas purification can be oxidized to carbon dioxide and water by known biochemical processes; can be removed from the recirculated washing liquid. Thus, the method according to the invention is also very advantageous in terms of preventing the formation of sewage in addition to the effective elimination of air pollution.

If solid impurities (eg fine sand, coal, etc.) get into the scrubbing liquid during gas cleaning, the wet sludge obtained by filtering them is practically free of organic impurities in the gas. This is particularly relevant if the pollutant is toxic (eg phenol, cresol, etc.); Thus, the disposal and / or further treatment of the filtered sludge does not involve any additional work or environmental task.

A particular advantage of the process according to the invention is that the binding and elimination of impurities in myuran at a near neutral pH and a low temperature range (10-40 ° C) does not require special corrosion stress. The following examples are intended to illustrate the scope of the invention.

Example 1 Air containing mg / m ^{3 of} phenol, 5 mg / m ^{3 of} formaldehyde, which corresponds to the composition of the air extracted in the production of mold sand using "NOVOFEN", for example, in the order of quality and concentration of organic pollutants. purification apparatus and a 4 liter useful volume aeration reactor connected thereto. 3600 ml of water, 400 ml of a 15 g / l dry sludge suspension adapted for the biological decomposition of phenol and formaldehyde, 1.0 ml of a 35% solution of ammonium hydroxide and 0.25 ml of a phosphoric acid solution (70%) were charged into the air-blown reactor.

The adapted sludge suspension can be obtained, for example, by taking an aqueous suspension from a municipal aerobic biological purification aeration basin, cultivating its microorganisms by adding 500 mg / L of phenol and 50 mg / L of formaldehyde to the aerobic microorganism. does not increase by 50%. The dosing medium is controlled so that the min. With aeration of 1.5 mg dissolved oxygen, the phenol content of the aqueous phase should be in the range of 1-10 mg / liter. The resulting slurry slurry is used after settling for the example experiment.)

The resulting washing solution, pH 7.6-8.1, temperature 20-22 ° C and containing at least 1.5 mg / liter dissolved oxygen, is fed to the top of the wash column by means of a pump [feed rate 3 liters / hour]. Intensive contact of the downward wash liquid and the contaminated air added at a rate of 1.5 m ³ / h occurs on the work surface with an average residence time of 1.2 to 1.6 minutes per liquid phase.

The washing liquid discharged from the scrubber is returned to the aeration reactor to effect the gas purification in the recirculation system. The purified gas has a phenol content of less than 1 mg / m ³ and a formaldehyde content of less than 0.2 mg / m ³ , thus satisfying the conditions for release to air.

A characteristic of the gas purification described in the example is that the efficiency of purification in the recirculation system is constant over time. If gas purification is carried out continuously for several days (weeks), the nitrogen and phosphorus supplementation is repeated every 24 hours. In continuous operation, 5-10% of the specific sludge accumulation per day is preferably recovered in batches by centrifugation of a portion of the recirculated washing liquid (5-10% daily sludge uptake), the aqueous phase being returned to the washing liquid. and condensed excess sludge as a by-product of gas purification, free of toxic substances. Exhaust gas from the scrubber is released into the atmosphere.

Example 2

Air containing 650 mg / m ^{3 of} methanol contamination, which is a model of emissions from methanolic processes such as centrifugation, drying, extraction of instrument wells at a rate of 100 liters per hour through a perforated tube, feeding into the lower part of the scrubber and dispersing it. The overflow of the scrubber is fed into a 100-ml aeration volume of aeration aeration.

A 0.5 liter useful settler is connected to the reactor, whereupon the excellent concentrated sludge (gravitationally) returns to the aeration post-reactor and the water from the settling 25 is circulated to the scrubber.

Prior to the start of gas purification, the experimental equipment connected to the closed liquid circulation circuit is first filled with clean water. At commissioning of the aeration after reactor 30, 200 ml - obtained from the urban biological wastewater purification post-settler - - approx. A live slurry slurry containing 10 g / l of suspended solids is added and the fluid circulation and reactor air supply is started, which is controlled throughout the experiment to provide a dissolved oxygen concentration of 2-4 mg / l.

After an initial fluid circulation of 0.5 liters per hour for 1.5 hours, during which the rennet slurry is decomposed, air containing 650 mg / m ^{3 of} methanol contamination is started at 100 liters / 40 hours.

After the second operating hour, the feed of contaminated gas is temporarily interrupted for 1 hour to provide the time necessary for the intensive biodegradation of methanol (adaptation).

The gas purification is then continued without interruption, which is characterized by the fact that the methanol content of the purified gas does not rise above 25 mg / m ³ even after several hours or daytime operation, thus satisfying the conditions of release into the air.

Note that if the plant is operated over several days, the excess nitrogen and phosphorus ingested by the slurry will be consumed, as provided in Example 1.

In the event that the pH of the washer fluid differs from 6 to 8.5 during continuous operation, the addition of alkaline or acidic compounds will provide the necessary correction. The excess sludge formed is removed by filtration as described in Example 1.

Claims (1)

Claim: A process for purifying contaminated gases and / or vapors or air by washing water and organic compounds of flammable and / or health-toxic organic compounds utilizing water-soluble and aerobic microorganisms as a source of water-soluble and aerobic microorganisms, delivering live sludge adapted to and / or adaptable to the biodegradation of the organic pollutants in the gas to the flowing water flowing into the gas scrubber while continuously flowing the gas to be purified to the gas scrubber; under known conditions, then washing the effluent from the post-reactor - if necessary by separating the excess fluffy sludge mass produced by known physical operations n - recirculation to the scrubber.