RU2710425C1 - Device for air cleaning from fine solid particles - Google Patents

Abstract

FIELD: water and air purification technology.SUBSTANCE: invention is intended for consolidation and further trapping of solid fine particles during cleaning of ventilation and process emissions from different dust particles, with dispersion of 0.1 to 10 mcm and more, and can be used in food, light, chemical, textile industry. Technical result is achieved due to that in device for air cleaning, containing separator of fine particles with two perforated plates, perforations of plates are made in form of longitudinal vertical slots, at that, axes of slotted holes of first and second plates are offset relative to each other. Decrease of dimensions of device is ensured by installation of fine particles separator inclined from vertical line, and coagulation of finely dispersed dust particles is ensured by fine water irrigation of dusty air flow with the help of nozzles. Using the separator made of two plates located at an angle from the vertical allows to reduce power consumption during cleaning of dusty air.EFFECT: increase the efficiency of the dust collecting device, improve the quality of the air to be cleaned and reduce energy costs when cleaning dusty air.4 cl, 4 dwg

Description

The invention relates to devices for wet cleaning of gases and can be used in chemical, textile, food, light and other industries for cleaning ventilation and technological emissions from various dust particles that are formed as a result of condensation, other reactions and technological processes, with a dispersion of 0 , 1 to 10 microns or more. The principle of operation of the device is based on the enlargement and subsequent capture of solid fine particles.

The closest, in technical essence and the achieved result to the proposed one, is an air purification device, including contaminated inlet and purified air outlet nozzles and a droplet generator with two perforated plates installed perpendicular to the direction of air movement, in which the diameter of the perforation of the second plate is equal to two diameters of perforation of the first plates, and the centers of perforation of the first plate are located in the middle of the intercenter distances of the second plate. The distance between the plates is 1.5 times the diameter of the perforation of the first plate, while the first perforated plate is made with a live cross-section, which ensures the jet movement of the flow and its run on the last plate at an angle of 90 °. /cm. Copyright certificate No. 980780 of the USSR MKI V01, D45 / 08, 1982 / Accepted as a prototype.

The disadvantages of this device is the impossibility of obtaining a high degree of purification from dry fine dust, due to its particles bouncing off the surface of the first and second perforated plates and their entrainment by air currents, high energy consumption, due to a significant increase in aerodynamic drag, as a result of dust accumulation on the surface the second, along the air flow, plates, as well as the bulkiness of the device, due to the insignificant living section for the passage of cleaned air through the perforated layer us.

The technical result of the invention is to improve the quality of purified air and the efficiency of the device for cleaning air from fine particles, simplifying the design of the separator of fine particles, reducing the size of the device for cleaning air, increasing the reliability of its operation, reducing aerodynamic drag and energy consumption during air cleaning, as well as recycling cleaning products for ventilation and technological emissions.

The specified technical result is achieved by the fact that in the known device for air purification, comprising a housing with inlet and outlet nozzles, inside of which there is a separator with two parallel perforated plates, the axis of the openings of which are offset from each other, and a louvre droplet eliminator located behind the separator at the outlet moreover, the first plate is made with a live section, providing a jet movement of a stream of dusty air and its running on the second plate at an angle of 90 °, excellent characterized in that it is additionally equipped with at least one nozzle installed in the inlet pipe with the possibility of irrigation with water the flow of dusty air in the direction of its movement, and a sump for sludge, which is attached to the lower part of the housing and has a drain device; while the perforated plates are located at an angle of 30-60 ° and have holes in the form of longitudinal slots with the location of the axes of the slotted holes of the first plate along the center axis of the slotted holes of the second plate. The slotted holes of the second plate have a width of 2.0 ÷ 2.5 relative to the width of the slotted holes of the first plate. The distance between the plates is equal to 1.5 ÷ 2.0 of the width of the slit hole of the first plate b1. The dispersed composition irrigated by a water nozzle is 2 ÷ 10 microns.

. Значение

при осаждении частиц на пластины для круглых струй, соответствующее полному их извлечению из двухфазного потока, составляет по данным исследований, около 0,58; для прямоугольных струй - 0,82. Осаждение частиц не наблюдается при

меньшем 0,2 для круглых струй (как в выбранном прототипе) и

меньшем 0,3 для прямоугольных (как в заявленном устройстве).The efficiency of the air purification device depends to a certain extent on the specific mechanisms leading to coagulation and deposition of aerosols in it, due to the design features of the trapping element. /cm. Ranz WE, Wong JB, Ind. Eng. Chem., 44, 137 (1952). The efficiency of deposition of aerosol particles from jets (rectangular and round) running onto the plates (impactors of jets, impact separators), on cylindrical and spherical collectors located in aerosol flows (fiber filters, gas scrubbers), due to inertial mechanisms, is determined as a function of the Stokes number:

. Value

when particles are deposited on plates for round jets, corresponding to their complete extraction from a two-phase flow, according to research, is about 0.58; for rectangular jets - 0.82. Particle deposition is not observed at

less than 0.2 for round jets (as in the selected prototype) and

less than 0.3 for rectangular (as in the claimed device).

Studies on determining the efficiency of aerosol capture at an air velocity in openings (slots) of 10 ÷ 180 m / s also found that changing the distance from the opening in the first plate to the surface of the second plate, in the range from 1 to 3 equivalent hole diameters, does not affect the obtained results.

Coagulation of aerosols in the claimed device for air purification from fine particulate matter with their subsequent capture is based on numerous studies of the authors of the proposed technical solution in the field of air purification. The result of these studies was the theoretical foundations of the processes of coagulation, and the capture of dust particles / Tyurin N.P. Highly efficient devices for cleaning ventilation emissions from fine particles: monograph / N.P. Tyurin. - Samara: SSASU, 2015 .-- 124 p. /.

When a three-phase flow passes through the slots of the first separator plate of the claimed device, turbulent coagulation (mutual) of dust particles and sprayed water nozzle (s) occurs due to turbulence of the stream in trickles with a small scale of turbulence, which leads to enlargement of particles and an increase in their inertial deposition in device separator, as theoretically η (efficiency) increases in proportion to the particle diameter d ² .

The minimum particle diameters d _min , which will be removed from the stream, will be smaller due to their coagulation (enlargement and subsequent inertial deposition) and are determined using the calculated criteria St _cr :

where ν _in - the speed of the flow running onto an obstacle, m / s;

- характерный размер препятствия, м.

- characteristic size of the obstacle, m

The similarity criterion for inertial particle deposition, the Stokes criterion, is determined by the well-known formula:

where ν _in - the speed of the flow running onto an obstacle, m / s;

ρ _h - the density of the material of the particles, kg / m ³ ;

d _h - particle diameter, m;

With _to - Keningem-Milliken amendment;

μ _in - dynamic viscosity, Pa⋅s;

- характерный размер препятствия, м.

- characteristic size of the obstacle, m

, для ее повышения необходимо создать условия, способствующие увеличению турбулентности воздушного потока, которая окажет большее влияние на коагуляцию частиц.For all considered cases of inertial particle deposition, the capture efficiency is proportional to the square of the particle diameter

, to increase it, it is necessary to create conditions conducive to an increase in turbulence of the air flow, which will have a greater effect on the coagulation of particles.

The speed of turbulent coagulation - a value that contributes to the number of particle encounters per unit volume per unit time, 1 / m ³ s - occurring due to the so-called “acceleration mechanism”, is determined by the formula of V. Levich:

where n ₀ is the initial concentration of particles, 1 / m ³ ;

- величина, характеризующая турбулентный поток, м²/с³;

- the value characterizing the turbulent flow, m ² / s ³ ;

- линейный параметр (для трубы

равен ее диаметру), м;

- linear parameter (for pipe

equal to its diameter), m;

ν _in - kinematic viscosity of air, m ² / s;

β is the coefficient characterizing the size distribution of particles;

dч _cf - average particle size, m.

The figure 1 shows a longitudinal section of a device for cleaning air from fine particulate matter, where the following notation is accepted: inlet pipe 1, outlet pipe 2, housing 3, separator 4, louvre droplet eliminator 5, nozzle 6, sludge tray 7.

The figure 2 shows the location of the plates in the separator, where: the first plate 8, the second plate 9.

The figure 3 shows the layout of the plates in the separator, where: the first plate 8, the second plate 9, pin 10.

The figure 4 shows a cross-section of the separator plates with a diagram of the movement of the dusty air flow, which shows: the first plate 8, the second plate 9. W∞ is the speed of the dusty air flow in the device body in front of the first plate, V ₁ is the speed of the dusty air flow in perforation of the first plate, V ₂ is the flow velocity of the purified air in the perforation of the second plate.

равно (6÷8)⋅b1. Ширина щелей второй пластине 9 b2 составляет (2,0÷2,5)⋅b1. Оси щелевых отверстий первой пластины 8 и второй пластины 9 смещены относительно друг друга и оси щелей первой пластины 8 проходит между осями щелей второй пластины 9. Расстояние между пластинами равно 1,5÷2,0 ширины отверстий первой пластины 8 b1.The device consists of a housing 3 with an inlet pipe 1 and an outlet pipe 2, inside of which there is a separator 4 and a louvered drop catcher 5 located behind the separator 4 at the outlet pipe 2. A nozzle (or several nozzles) is installed in the inlet pipe 1 for irrigation of the incoming dusty air flow in the direction of its movement. The housing 3 is provided with a sump for sludge 7, which is attached to the lower part of the housing and has a drain device to remove trapped sludge. The finely divided particles separator 4 consists of two perforated plates parallel to each other, located at an angle of 30-60 °: the first plate 8 and the second plate 9 connected by a stud 10. The plates have perforations in the form of longitudinal slots. In the first plate 8, the width b1 of the slots is 4 mm, the distance between the centers of the slit holes

is equal to (6 ÷ 8) ⋅b1. The width of the slits of the second plate 9 b2 is (2.0 ÷ 2.5) ⋅ b1. The axis of the slit holes of the first plate 8 and the second plate 9 are offset relative to each other and the axis of the slits of the first plate 8 passes between the axes of the slits of the second plate 9. The distance between the plates is 1.5 ÷ 2.0 of the width of the holes of the first plate 8 b1.

A slot width of 4 mm in the first plate 8 is adopted to form dusty air streams running onto the second plate 9, as well as to create the effect of mutual coagulation of fine particulate matter (d2 from 0.1 μm to 10 μm) contained in the stream of dusty air, and particles of water (d2 from 2.0 μm to 10 μm) sprayed through the nozzle 6. The first plate 8 is made with a live cross-section, providing a plane-parallel jet flow movement and its running on the second plate 9 at an angle of 90 °. The number of nozzles 6 depends on the volume of cleaned air. Elements of the proposed device can be interconnected, for example, by welding.

The device operates as follows.

Polluted air enters the device through the inlet pipe 1, where the nozzles 6, in the direction of air movement, irrigate the polluted air stream with water. A three-phase flow, consisting of air, dust particles and irrigation water, enters the housing 3 and passes through a separator 4 of fine particles. In the separator 4, the air flow breaks off from the sharp edges of the slit openings of the first plate 8, is compressed and at a high speed, with a small scale of turbulence commensurate with the size of the jet width, runs onto the inter crevice areas of the second plate 9. When a three-phase jet consisting of air, particles dust and water particles, and coagulated agglomerates, on the second plate 9, a boundary layer is formed, which has an increased viscosity to the components of the jet. Viscosity is formed due to sedimentation of water particles on the surface of the second plate, “mixing” of water particles with dust particles and impact of the dusty three-phase flow on the surface of the second plate, on which particles of dust, aggregated agglomerates and water are deposited. This leads to mutual coagulation of solid dust particles and droplets of water sprayed by nozzles. Further aggregated agglomerates, mainly due to inertial forces, fall on the second plate 9 of the separator 4.

Coagulation of aerosols is carried out mainly on the second plate 9 due to the impact of individual streams on the area between the slotted holes of the second plate 9. The selected width of the slotted holes of the second plate 9 excludes the secondary formation of aerosols and droplets.

Large droplets disrupted by the air flow from the second plate 9 are captured by a louvre droplet eliminator 5 and flow into the sludge tray 7, equipped with a drain device, by which the sludge formed during air cleaning is removed. The purified air is removed through the outlet pipe 2.

The proposed device allows you to remove from the stream of dusty air particles of fine dust with a dispersed composition of 0.1-10 microns or more. In this case, the deposition of particles on the first plate of the separator practically does not occur. The first plate only contributes to the formation of individual plane-parallel streams with a small scale of turbulence, which contributes to the mutual coagulation of dust particles and water sprayed by nozzles, and also ensures the coagulated aerosols to run onto the second plate at a speed.

Improving the reliability of the claimed device and the efficiency of air purification is achieved through perforation of the separator plates in the form of longitudinal vertical slots and irrigation of polluted air with water through a nozzle (nozzles) with a dispersed composition of water particles from 2.0 microns to 10 microns., Which allows to capture dust particles, precipitate them and dispose of them, increasing the quality of purified air. Caught coagulated particles moistened with water particles, under the action of gravity, drain into the sludge pan and are removed through a drain device. Due to the draining of coagulated particles, the separator plates self-clean, which do not clog and do not require frequent shutdown of the device to clean them.

Perforation of the separator plates, made in the form of longitudinal vertical slots, and their installation at an angle of 30-60 ° reduces aerodynamic drag, and, therefore, reduces the energy consumption of the device during its operation.

Claims (4)

1. A device for air purification, comprising a housing with inlet and outlet nozzles, inside of which a separator is installed with two parallel perforated plates, the axis of the openings of which are offset from each other, and a louvre droplet eliminator located behind the separator at the outlet pipe, the first plate being made with living section, providing a jet movement of a stream of dusty air and its run on the second plate at an angle of 90 °, characterized in that it is additionally equipped with at least one the second nozzle installed in the inlet pipe with the possibility of irrigation with water the flow of dusty air in the direction of its movement, and a sump for sludge, which is attached to the lower part of the body and has a drain device; while the perforated plates are located at an angle of 30-60 ° and have holes in the form of longitudinal slots with the location of the axes of the slotted holes of the first plate along the center axis of the slotted holes of the second plate. 2. The device according to p. 1, characterized in that the slotted holes of the second plate have a width equal to 2.0 ÷ 2.5 relative to the width of the slotted holes of the first plate. 3. The device according to p. 1, characterized in that the distance between the plates is equal to 1.5 ÷ 2.0 of the width of the slit hole of the first plate b1. 4. The device according to p. 1, characterized in that the dispersed composition of the irrigated nozzle of water is 2 ÷ 10 microns.

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