RU2147527C1 - Method of and device for cleaning contaminated gas - Google Patents

Abstract

FIELD: mechanical engineering; scrubbing of gases. SUBSTANCE: proposed invention relates to cleaning of gases from suspended particles, dust and other admixtures, and cleaning air and/or waste gases in different industries. According to proposed method several water curtains are formed. Curtains are arranged one after the other and are directed from top to bottom. Contaminated gas is positively delivered to curtains in longitudinal direction square to direction of water curtains. Thickness of curtains and their number are found to provided their engagement with contaminated gas flow with formation of supersaturated steam and further condensation with core in from of particle of gas contaminating substances. EFFECT: enhanced quality of cleaning, simplified design of device, economy and convenience in operation. 14 cl, 2 dwg

Description

 The invention relates to techniques for wet cleaning of gases from suspended particles, dust and other impurities and can be used to clean dusty air and / or industrial exhaust gases in various industries, including for cleaning air entering the cab or passenger compartment.

 Known methods and means for wet cleaning of contaminated gas, where it is cleaned by contact with a liquid, as a result of which dust particles are wetted, heavier and removed from the gas and dust stream under the influence of gravitational and centrifugal forces or captured by the liquid and removed from the apparatus in the form of sludge. Typically, water is used as a cleaning fluid.

 RU 2102118 describes a method for purifying contaminated gas and a device for implementing this method, in which the gas is contacted with a finely divided liquid in the form of droplets to separate particles or adsorb gaseous pollutants. A finely divided liquid in the form of droplets is supplied in the form of umbrella-shaped shells or linear curtains with the correct arrangement, distributed in two or more planes, essentially perpendicular to the direction of the main stream of contaminated gas. The means for supplying a finely divided liquid are spray nozzles of a special design located in the lattice structure of the device. These known method and device for purifying contaminated gas have disadvantages, which are associated primarily with the fact that the principle of their action is based on the interaction of the trapped gas polluting particles with droplets of its irrigating liquid, which does not allow the purification of contaminated gases with high efficiency under different conditions, depending on the ratio of the sizes of the gas-polluting particles and the droplets of the cleaning liquid, since when, for example, the sizes of the liquid droplets and the particles are comparable, the particle will be repelled from the droplet water, which in this case loses its ability to “stick”, which leads to an incomplete cleaning process. The use of nozzles for spraying liquid complicates the design of the device and reduces the reliability and efficiency of gas cleaning, which are directly related to their work, while it is necessary to constantly monitor nozzles that spray liquid and constantly clean them, which in turn leads to inconvenience in operation.

 A known method and device for cleaning contaminated gases described in the international application PCT WO / 03843, where the contaminated gas is washed with liquid sprayed into vertical channels through nozzles from a tank located above the cleaning chamber. Vertical channels are formed by dividing walls. The main disadvantages of these known methods and devices for cleaning contaminated gas as well as those mentioned above are associated with the use of drops of cleaning liquid, which complicates the design of the device, reduces the efficiency of cleaning, and does not contribute to ease of use.

 In a. with. SU 546364 describes a known method and device for capturing harmful exhaust impurities, providing for a preliminary wet saturation of a gas stream with water vapor as a result of its passage between partitions covered with a film of hot water, followed by a humidified supersaturation of the stream by passing it between the surfaces of the narrow channel nozzle cooled with cold water at the gradients of water vapor and temperature between the gas-vapor stream and the irrigated cold surface, respectively, 100-150 g / mm and 14-20 degrees / m. The disadvantages of this known method are as follows. Saturation of the gas stream with water vapor by evaporation from the surface is not efficient enough, which does not allow for its high-quality cleaning. It is technically difficult to ensure the creation of films of uniform thickness on the surface of the partition walls, which leads to an excessive consumption of water. The cleaning of the gas stream in a known manner depends on certain temperature ratios of this gas stream and the water that purifies it, which does not allow to find all the optimal parameters of the method and the device that implements it.

 The technical result of the invention obtained by its use is a reliable and efficient purification of contaminated gas, adaptive to different temperatures of the contaminated gas and its cleaning water. The design of the proposed device is simple, compact and small in size. In operation, the proposed device is convenient, does not require constant attention and high energy costs. A quick readjustment of the device is possible if the operating conditions change (for example, the degree of pollution and / or the power of pollution of the contaminated gas).

 The specified technical result is ensured due to the fact that the device for purifying contaminated gas contains a purification chamber, an inlet for contaminated gas and an outlet for purified gas, a liquid reservoir located above the purification chamber and separated from it by a horizontal partition, means for supplying liquid from the reservoir into the cleaning chamber for its interaction with the contaminated gas, a container for waste liquid, means for forcing the contaminated gas into the cleaning chamber, while the liquid supply from the reservoir to the cleaning chamber is configured to form several continuous water curtains parallel to each other, which can be located at some distance from each other, the direction of the continuous water curtain in the cleaning chamber is perpendicular to the direction of flow of the contaminated gas supplied thereto, and the length L corresponds to the width of the cleaning chamber, and their thickness and quantity are determined from the conditions for ensuring the formation of a supersaturated steam when interacting with the cleaned dust and gas Monsieur.

 Purification of contaminated gas during its interaction with several continuous water curtains formed in the indicated way along its path greatly simplifies the design of the device and at the same time allows purification of contaminated gas with a high degree of accuracy, since in this case, the contaminated gas gradually saturates with water vapor until it is completely moistened with the formation of a supersaturated vapor, after which it condenses with the core in the form of a particle of a gas polluting substance and the droplets formed precipitate. In this case, the complete moistening of the contaminated gas occurs gradually during its passage through continuous water curtains, the formation of droplets and their precipitation occurs in the spaces between them. The thickness of the continuous water curtains is selected so as to allow the flow of contaminated gas to pass through them. The advantage of using continuous water curtains compared to spray curtains is that obtaining supersaturated steam is difficult because the evaporation process is difficult, because the smaller the droplet of liquid, the more difficult it is to evaporate due to the need to overcome the surface tension, which increases with decreasing liquid droplet size.

 The use of the proposed device does not require additional attention to the cleaning process during operation. It is necessary to adjust the required thickness of the water curtains and to monitor the constant availability of water. There is no need to use any special monitoring devices and devices.

 Means of formation of several continuous water curtains are several sections made, for example, in the form of plates placed in a horizontal partition and forming through longitudinal slots, the length and width of which corresponds to the length and thickness of the formed water curtains.

 Obviously, such an implementation of these tools is extremely simple and does not require large expenses in the manufacture.

 The sections can be made sliding in width to provide the ability to control the width of the slots and, accordingly, the thickness of the continuous water curtains, which reliably allows the formation of water curtains continuous in any various operating conditions.

 Continuous water curtains can be formed both inseparably in height and having small local breaks provided for in them, which can reduce the gas-dynamic resistance during the cleaning process, which will occur more smoothly and gradually, but no less reliably.

 Means for the formation of local discontinuities of continuous thin water curtains of liquid can be made in the form of tabs placed in the slots of the horizontal partition sections. In this case, alternation of breaks in the water curtains can be provided, which will ensure the labyrinth passage of gas, and therefore, will accelerate the process of its purification and reduce the dimensions of the device.

 The bottom of the cleaning chamber can be made with a slope for the flow of spent liquid into the tank designed for it by gravity.

 The waste liquid tank can be equipped with a filter for cleaning it, which will allow you to use the same liquid repeatedly using a pump to supply the purified liquid to the cleaning chamber.

 As a means of forced supply of contaminated gas to the purification chamber, an exhaust fan can be used located on the side of the purification chamber opposite to that on which the nozzle for introducing contaminated gas into the purification chamber is located. This ensures the principle of operation of the device at negative pressure.

 Fig. 1 shows a general view of a device for purifying contaminated gas; Fig. 2 is a plan view thereof (FIG. 1).

 A device for cleaning a dust-gas mixture includes a cleaning chamber 1, an inlet pipe 2 through which the contaminated gas is forcibly supplied to the cleaning chamber 1, an outlet pipe 3 through which the purified gas leaves the cleaning chamber 1, a cleaning liquid reservoir 4 located above the cleaning chamber 1 and separated from it by a horizontal partition 5, a tank 6 for spent liquid, means for forcing the dust and gas mixture into the cleaning chamber 1 — an exhaust fan 7, means for supplying liquid from the tank 4 to the cleaning chamber kiosks 1 are made with the possibility of forming several thin continuous water curtains 8 parallel to each other and located at some distance from each other, the direction of the curtains 8 in the cleaning chamber 1 is perpendicular to the flow direction of the contaminated gas supplied thereto, and the length L of the continuous water curtains 8 corresponds to the width In the cleaning chamber 1, and their width t and their number are determined from the condition of the possibility of ensuring the formation of a supersaturated steam when interacting with the cleaned gas of continuous water curtains 8.

 Means of forming several continuous water curtains in the cleaning chamber include several sections 9 in the horizontal partition 5, which form through it longitudinal slits 10, the length and width of which corresponds to the length and thickness of the continuous water curtains 8 formed with their help and the width of the cleaning chamber 1.

 Section 9 can be made with the possibility of regulating the width of the slots 10 and, accordingly, the thickness of the continuous water curtains 8.

 The possibility of the formation of continuous water curtains 8 is inextricable in height.

 Solid water curtains 8 can also be formed with discontinuities in height.

 To form the provided gaps in the continuous water curtains 8, tabs 11 can be used, placed in some places of the slots 10 of the sections 9 of the horizontal partition 5 and overlapping these places of the slots 10.

 In the cleaning chamber 1, its bottom 12 can be made with a slope for the flow of spent liquid into the tank 6 intended for it by gravity. To clean the spent liquid, the container 6 may be equipped with a filter 13.

 The device may be equipped with a pump 14 for supplying purified liquid to the cleaning chamber 1.

 Preferably, the means 15 for the forced supply of contaminated gas to the cleaning chamber 1 is placed on the side opposite to that where the inlet 16 is placed for its entry into the cleaning chamber 1.

 The means 15 for forced supply of contaminated gas to the cleaning chamber 1 can be made in the form of an exhaust fan.

 Purification of contaminated gas by the proposed method, which is implemented using the proposed device, is as follows.

 Previously, a cleaning liquid is supplied to the tank 4, which is usually used as water. They try to choose the width of each slit in the horizontal partition in such a way that a water curtain is formed in the cleaning chamber in the form of a continuous stream of water, which can have local gaps in the height of the water stream either from above or from below. The water curtains formed through the slits in the cleaning chamber contribute to the formation of water vapor. The contaminated gas is forcedly, with the help of an exhaust fan, fed through the inlet pipe 2 to the cleaning chamber 1 and, going to the first water curtain, enters into interaction with it, breaking through it and moistened with water vapor up to 100% or more. In this case, large particles of gas-polluting substances are washed off by the flow of water, and smaller particles between the water curtains are saturated with water vapor, and liquid droplets with a condensation core in the form of a particle of gas-polluting substances form. These drops in the form of rain precipitate, which by gravity enters the intended container. To reduce the gas-dynamic resistance, breaks are provided in the water curtains. During operation, a film of water forms on the inner walls of the cleaning chamber and the horizontal partition, which also participates in the process of cleaning the polluted gas, trapping some gas-polluting particles.

 The process of generating the supersaturated steam necessary to clean the contaminated gas from the smallest particles in the present invention is simple, does not require any additional effort and cost. Operation does not require constant attention of maintenance personnel. There are no control devices. Purification of contaminated gas is of high quality.

Claims (14)

 1. A device for purifying contaminated gas, comprising a purification chamber with an inlet for contaminated gas and an outlet for purified gas, a water tank located above the purification chamber and separated from it by a horizontal partition, means for supplying water from the reservoir to the purification chamber, a container for waste water, means for forced supply of contaminated gas to the treatment chamber, characterized in that the means for supplying water from the reservoir to the treatment chamber are configured to generate several waters of the curtains in the form of a continuous stream of water located in the cleaning chamber parallel to each other and at some distance from each other, the direction of the formed water curtains in the cleaning chamber is perpendicular to the flow direction of the contaminated gas supplied thereto, while the width L of the formed continuous water curtains corresponds to the width of the chamber purification, and their thickness and quantity are determined from the condition that they can interact with the flow of contaminated gas with the formation of a supersaturated water vapor in the purification chamber and the subsequent condensation with the core in the form of particles of gas pollutants.  2. The device according to claim 1, characterized in that the means for forming several water curtains respectively comprise several sections located in a horizontal partition with the possibility of forming through longitudinal slits, the length and width of which corresponds to the width and thickness of the formed water curtains and the width of the cleaning chamber.  3. The device according to claim 2, characterized in that the sections are configured to control the width of the slots and, accordingly, the thickness of the water curtains.  4. The device according to any one of paragraphs. 1 to 3, characterized in that the height of the formed water curtains corresponds to the height of the cleaning chamber.  5. The device according to any one of claims 1 to 3, characterized in that the formed water curtains have through-through local discontinuities in height.  6. The device according to p. 5, characterized in that the means for the formation of through-through local ruptures of water curtains are made in the form of tabs placed in the slots of the horizontal partition sections.  7. The device according to any one of paragraphs.1 to 6, characterized in that the bottom of the cleaning chamber is made with a slope for the flow of waste water into the designated container by gravity.  8. The device according to any one of claims 1 to 7, characterized in that the waste water tank is equipped with a filter for cleaning it.  9. The device according to any one of claims 1 to 8, characterized in that it is equipped with a pump for supplying purified water to the treatment chamber.  10. The device according to any one of paragraphs.1 to 9, characterized in that the means of forced supply of contaminated gas to the cleaning chamber is made in the form of an exhaust fan.  11. The device according to claim 10, characterized in that the exhaust fan is placed on the side of the cleaning chamber, opposite to where the inlet for the contaminated gas is located.  12. A method of purifying a contaminated gas, including its interaction with water to separate particles of gas pollutants, characterized in that it preliminarily forms several water curtains sequentially spaced at a distance from each other in the form of continuous streams of water directed from top to bottom, contaminated gas for interaction they are forcibly served in a longitudinal direction perpendicular to the direction of these water curtains, while their thickness and quantity are determined from the condition of ensuring their interaction Via a flow of contaminated gas to form a supersaturated vapor, with its subsequent condensation nucleus in the form of particles of polluting substances and the gas formed, followed by deposition of droplets in the precipitate in the form of rain.  13. The method according to p. 12, characterized in that the water curtains in the form of a continuous stream of water form with localized breaks or from the bottom, or at the top of these flows.  14. The method according to p. 13, characterized in that during the formation of adjacent continuous flows of water, their localized gaps are not organized opposite each other to ensure a labyrinth passage through them of contaminated gas.

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