RU2473383C2 - Sorbent to refine air of water vapors, acid gases and microorganisms in cabins of motor vehicles and premises - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: sorbent is made by mixing fine Portland cement 500 in flask with sodium chloride and water. Pellets are formed from said mix, heated at 105 degrees Centigrade and cured for three days at 20 to 40 degrees Centigrade. Cured pellets are damped in tap water to genitive reaction to chloride ions, dried to moisture content of 2%, held in 10%-solution of diethanolamine containing up to 1% of cetyl pyridine chloride, and dried to moisture content of 8%.

EFFECT: simple production of efficient sorbent.

Description

The invention relates to sorbents for air purification in the salons (cabins) of vehicles, as well as in residential premises from acid gases, water vapor and microorganisms.

A known method and device for air purification in the inhabited compartments of vehicles. A device for air purification consists of inlet and outlet pipes, between which an air heater is arranged in series and sections are connected in series with cassettes filled with chemisorbents and a catalyst for purifying the supply air of organic, nitrogen and sulfur compounds, as well as carbon monoxide [RU 94017415 A, B60H 3 / 06.1996].

The main disadvantages of this invention are: only the supply air is supplied and cleaned in the inhabited compartment; the device has very large dimensions and mass; a large amount of electricity is consumed for air purification; the device is characterized by insufficient air purification; not cleaned in recirculation mode. When you turn on ventilation, heating, air conditioning systems with high performance in supply air, the use of the device loses its meaning.

A known method and device for air purification, in which air purification in rooms and salons is carried out in recirculation mode using chemisorbents, low-temperature catalytic and adsorption filters [RU 2161567 C1, B60H 3/06, 2001]. The main disadvantages of the device are: the inefficiency of the use of ventilation, heating and air conditioning systems due to the multiple differences in air flow, which is much less in the cleaning system; the same with the open position of doors, windows, etc .; the same with a large leak in the room, interior. Other disadvantages of this device are: lack of cleaning from dust, ozone, nitric oxide, etc., lack of technical solution for supplying purified air to the breathing zone of a passenger, driver, as without this, considerable time is required to clean the air in the entire volume of the room, after which the necessary conditions will be achieved for people to be in the room in favorable conditions.

A known system of air purification from harmful substances, operating in recirculation mode, mainly in salons, cabins of vehicles, rooms, inhabited compartments, consisting of a housing with inlet and outlet windows, an electric motor, a fan blocked with a drive, means of air purification, including at least one air purification unit, with one filter-cleaning layer [RU 2173639 C1, 2001]. The disadvantages of the device are the lack of air purification from dust, nitrogen oxides, ozone, there is no thorough and optimal study of the selection of filter materials, sorbents, catalysts, and other components that provide more efficient air purification taking into account a very wide variety of designs, for example, automobiles, their systems the performance of salons and cabins, the degree of their leakage, the variety of outdoor air pollutants, both in concentration and in the composition of harmful substances.

A device is known for purifying air from harmful substances in a recirculation mode, mainly in inhabited compartments, for example, in salons and cabins of vehicles, domestic and industrial premises, including air intake from rooms, air pumping by means of a supercharger through a cleaning system with harmful air purification units substances and, finally, the supply of purified air back to the cabin, and along with the purification of the air in the cabin in the recirculation mode, a part of the supply air is additionally taken and pumped through it about through the air purification system from the passenger compartment, and purified air is supplied to the passenger compartment, and a fraction of the passenger compartment air, proportional to the amount of fresh air supplied to the passenger compartment, is thrown out of the passenger compartment, and the supply and cleaning of the supply air is carried out depending on air pollution. Before cleaning from the most harmful substances to reduce carbon dioxide in the air and restore oxygen from them, air is pumped through an additional oxidizing filter element consisting of alkali metal peroxide compounds, and to remove additional moisture from calcium chloride and / or silica gel. To remove nitrogen oxides from air, nitric oxide is first oxidized with potassium permanganate (or calcium, or barium, or magnesium). Purification of carbon oxides is carried out by a low-temperature catalyst using platinum group metals, for example, palladium or its oxides, or hopcalite, or zeolites, or a photocatalyst, or coal impregnated with hydrophilic salts of calcium chlorides, or lithium, or lithium bromide, or by production and supply into the ozone air stream. Air purification from carbon compounds, all hydrocarbon groups, including carcinogens, is carried out on granules of coal, or coal, modified with alkali metals, or copper oxide, or salts of copper, chromium, silver, which are fixed on the surface of activated carbon by impregnation, followed by heat treatment at a temperature 110-150 ° C, and coal is pre-activated by steam-gas activation, for example, at a temperature of 800 ° C. Purification of air from ammonia, hydrogen sulfide and organic impurities is carried out by passing it through a water-ammonia solution containing catalytic additives, or absorbers from potassium iodide or soda lime [RU 2319622 C2, 2006].

The disadvantage of the existing device is primarily the complexity of the used composition of air-purifying substances. Chemical reactions can occur between the components introduced into the purifier, resulting in a sharp decrease in the activity of the absorber.

We propose a new sorbent obtained by mixing finely ground 25 g of Portland cement - 500, 25 g of flasks of the Astrakhan region with 5 g of NaCl and 45 g of water and the formation of granules of the required size (5-7 mm in diameter). The product is heated at 105 ° C for 6 hours, incubated for another three days at a temperature of from 20 to 40 ° C, after hardening, soaked in tap water until a negative reaction to chloride ions. Dry to a moisture content of about 2% at 95-100 ° C. The finished product is soaked in a 10% solution of diethanolamine (DEA) containing up to 1% cetylpyridinium chloride (CCP), and dried to an air-dry state (humidity up to 8%).

The resulting sorbent contains, (wt.%): Calcium oxide (CaO) - 50.0; silicon dioxide (SiO ₂ ) - 30.0; aluminum oxide (Al ₂ O ₃ ) - 11.4; diethanolamine (NH (CH ₂ ) ₄ OH ₂ ) - 0.5; cetyl pyridinium chloride - 0.01; water (H ₂ O) - 8.0; the rest is impurities.

Sorbent Test

Experiments were conducted on the purification of atmospheric air from acid gases, water vapor and microorganisms on the claimed sorbent. In order to study air purification in bottles with a capacity of 5 dm ³ , a small vacuum was created using a vacuum pump (residual pressure 0.6–10 ⁵ N / m ² ) and gases were passed through a special nozzle, which were obtained by the reaction of copper with sulfuric acid (obtained SO ₂ ), by the reaction of sodium sulfide with sulfuric acid (obtained H ₂ S) or by the reaction of calcium carbonate with hydrochloric acid (received CO ₂ ). Then air was let into the bottle to bring the total pressure to 1.02-10 ⁵ N / m ² and a mixture of air and test gas from the bottle was passed through sorbent granules with a diameter of 2 cm, creating a vacuum at the outlet of this tube.

S, где m_исх - содержание H₂S, или SO₂, или СО₂ в воздухе до очистки, мг/м³, m_кон - содержание H₂S, или SO₂, или СО₂ в воздухе после очистки, мг/м³.Table 1 shows the results of experiments on the purification of atmospheric air into which certain toxicants were added. The degree of purification S was calculated by the formula

S, where m _ref is the content of H ₂ S, or SO ₂ , or СО ₂ in the air before purification, mg / m ³ , m _con is the content of H ₂ S, or SO ₂ , or СО ₂ in the air after purification, mg / m ³ .

From the results given in table 1, it can be seen that the claimed sorbent can be used for air purification in the salons (cabins) of vehicles, as well as in residential premises. The possibility of purifying atmospheric air from groups of toxicants has been studied. For this, the simultaneous generation of several toxicants was used. The results of air purification from a mixture of hydrogen sulfide, carbon dioxide and sulfur are given in table 2.

table 2 The results of sorption purification of atmospheric air from a mixture of hydrogen sulfide, carbon dioxide and sulfur Contact time, s The concentration of the substance before purification, mg / m ³ , the air contains a mixture of substances, the concentration of each of which is indicated by numbers Cleaning results Found, m _con mg / m ³ S,% 5,0 SO ₂ -20.0 0.002 ± 0.0002 99,99 5,0 CO ₂ -20.0 0.002 ± 0.0002 99,99 5,0 H ₂ S-10.0 0.001 ± 0.0001 99,99

As can be seen from table 2, the sorption purification of atmospheric air using the claimed sorbent is highly effective and can be recommended everywhere in cases where only chemisorption purification has a noticeable effect.

Experiments show that not only SO ₂ , H ₂ S, CO _{2 is} deactivated, but also all pathogens are destroyed. Table 3 shows the results of air purification from microorganisms. The air in the boxes was cooled by BK - 2500 air conditioners, but in one case the air was cleaned by the claimed sorbent, located in a canister and located along the flow of exhaust air.

Table 3 Comparative characteristics of atmospheric air dissemination by natural microflora without use (control) and using the claimed sorbent. The number of experiments is 6. Object of study - air Temperature ° C Relative humidity% The number of colonies of natural microflora in a Petri dish before experiments after experiments Boxing 1 (control) 25 ± 2 80.0 ± 2.0 80.0 ± 2.0 56.0 ± 5.0 Box 2 (using sorbent) 25 ± 2 80.0 ± 2.0 40.0 ± 1.5 4.0 ± 1.0

Thus, the sorption purification of atmospheric air from acid gases, pathogens using the claimed sorbent is highly effective.

Claims (2)

1. A method of producing a sorbent for air purification in the salons (cabins) of vehicles, as well as in residential premises from acid gases, water vapor and microorganisms, which is obtained by mixing finely ground 25 g of Portland cement - 500, 25 g of flasks of the Astrakhan region with 5 g of NaCl and 45 g of water, the formation of granules with a diameter of 5-7 mm, heating the granules at 105 ° C for 6 h, keeping the granules for three days at a temperature of 20 to 40 ° C, after hardening, the granules are soaked in tap water until a negative reaction to chloride ions, dry to a moisture content of 2% at 95-100 ° C, maintained in a 10% solution of diethanolamine (DEA) containing 1% cetylpyridinium chloride (HTSP) and dried to a moisture content of 8%. 2. Sorbent for air purification in the salons (cabins) of vehicles, as well as in residential premises from acid gases, water vapor and microorganisms, obtained by the method described in paragraph 1.