RU2035664C1 - Apparatus for thermocatalytic burn-up of waste gases - Google Patents

Abstract

FIELD: industrial environment control. SUBSTANCE: apparatus has cylindrical chamber accommodating infrared radiation source installed along its axis and helical catalytically active component mounted coaxially with the former and provided with turn increasing in thickness towards periphery, at least one of its contour sides being arranged along line complying with equation describing set of curves differently illuminated by linear light source. EFFECT: eliminated overheating of developed surface of catalyzer, improved quality of gas cleaning. 20 cl, 7 dwg

Description

 The invention relates to apparatus for the afterburning of waste gases by the thermocatalytic method and can be used in industrial ecology for cleaning ventilation emissions and in the food industry for drying food products with flue gases.

 A known apparatus for thermocatalytic afterburning of waste gases, comprising a cylindrical chamber with a catalytically active element made in the form of a film deposited on the wall of the chamber, and an infrared source located along the axis of the chamber.

 The disadvantages of this apparatus are the undeveloped surface of the catalyst and its uneven illumination with a source of infrared radiation, leading to local overheating and failure of the catalyst.

y²-x²+

-y′·

+

(y³-1)

y³-x²+
+

-4a

0, где х и y координаты;
а задаваемая константа, определяющая условия работы катализатора, м².In the proposed apparatus for thermocatalytic afterburning of waste gases containing a cylindrical chamber with a catalytically active element and an infrared radiation source located along the camera axis, according to the invention, the catalytically active element is made in the form of a coaxial helicoid chamber with at least one side of the coil increasing to the periphery of the coil which is made along a line that satisfies the equation in elliptical coordinates with the center of coordinates on the camera axis:
y ′ ² · (1-x ² )

y ² -x ² +

-y ′

+

(y ³ -1)

y ³ -x ² +
+

-4a

0, where x and y coordinates;
and a given constant that determines the operating conditions of the catalyst, m ² .

 This allows you to develop the surface of the catalyst and create its uniform illumination, which eliminates the possibility of local overheating and failure for this reason.

 In a preferred embodiment, the turns of the catalytically active element are made adjacent to the inner surface of the chamber. This reduces the material consumption of the apparatus.

 In another embodiment, the turns of the catalytically active element are made adjacent to a source of infrared radiation. This reduces the material consumption of the apparatus, increases the efficiency of the use of infrared radiation and the reliability of gas purification by eliminating the possibility of a breakthrough of the axial gas flow not processed on the catalyst.

It is preferable that the surface of the coil furthest from the axis of the chamber be inclined to it no more than 85 ^° . This increases the efficiency of using infrared radiation.

Also preferably perform inclination surface coil at the proximal region to the axis of the chamber in the range of ^about 5-85.

An increase in the angle of more than 85 ^° leads to a sharp increase in the hydraulic resistance of the apparatus, and a decrease of less than 5 ^° to a decrease in the efficiency of using infrared radiation and a sharp increase in material consumption.

 To simplify the manufacturing technology of the catalytically active element, it is possible to make a thickness of the coil increasing in one direction.

 In order to equalize the temperature on the surface of the catalyst and increase the efficiency of using its surface, it is possible to make a coil symmetrical with respect to the midline perpendicular to the axis of the chamber.

 To reduce the material consumption, increase the specific surface area of the catalyst per unit length of the chamber and increase the efficiency of using infrared radiation, it is possible to perform a helicoid step equal to the maximum thickness of the coil.

 Another preferred option is to provide the apparatus with at least one additional catalytically active element, made with the opposite direction of the helicoid winding and installed behind the previous one in series and coaxially.

 This allows you to increase the efficiency of gas purification due to the intensification of mass transfer processes in the gas stream during its turbulization.

 Installation of catalytically active elements in removable cartridges is possible.

 This allows you to reduce the material and laboriousness of repair work.

 Another preferred option is the implementation of the catalytically active elements of the mesh, perforated or porous. This allows you to develop a catalyst surface.

 It is possible to perform a helicoid with a step decreasing towards the exit from the chamber.

 This allows you to intensify the mass transfer processes in the gas stream, especially when performing a catalytically active element mesh, perforated or porous, due to the turbulence of the gas stream.

 It is also possible to supply the apparatus with at least one removable flat catalyst cartridge made of a mesh, perforated or porous, mounted behind the helical catalytically active elements that completely overlap the section of the chamber.

This allows you to completely eliminate the possibility of a breakthrough of the gas stream jets untreated on the catalyst, thereby improving the quality of gas cleaning. In this case installation plane desirable catalyst cartridge at an angle ^of 5-85 to the chamber axis.

 This allows you to increase the turbulization of the gas stream without a significant increase in the length of the chamber, than to improve the quality of gas purification.

 In the same case, it is possible to supply the apparatus with additional sources of infrared radiation combined into removable cassettes installed before and / or after the flat catalyst cassette, preferably parallel to the latter. This increases the efficiency of gas cleaning.

 It is also possible to perform a flat catalyst cartridge from a catalytically active mass with conductive filler connected to a current source and serving as a source of infrared radiation. This improves the reliability of gas cleaning.

 In this case, it is possible to supply the apparatus with ultraviolet radiation sources combined in removable cartridges installed before and / or after the flat catalyst cartridge, preferably parallel to the latter.

 This allows you to improve the quality of gas purification due to the expansion of the range of toxic substances burned during photocatalytic oxidation of a dusty pollutant.

 The last option is to provide the apparatus with an ultrasound source connected to at least one catalytically active element.

 This improves the reliability of the apparatus by lengthening the life of the catalyst during the oxidation of sorbed toxic substances.

 Figure 1 presents the apparatus, a General view; in Fig.2 a fragment of a helicoidal catalytically active element with a coil thickness increasing in one direction; Fig.3 is the same, with a symmetrical coil; figure 4 is a General view of the apparatus with three helical catalytically active elements with the opposite direction of winding; figure 5 apparatus with porous helicoidal catalytically active elements, additional flat catalyst cassettes, made mesh, and additional sources of infrared radiation, General view; Fig.6 apparatus with flat catalyst cassettes, serving as sources of infrared radiation, General view; Fig.7 is the same with sources of ultraviolet radiation.

 The apparatus for thermocatalytic afterburning of waste gases contains a cylindrical chamber 1 with a catalytically active element 2, made in the form of a coaxial chamber of one (Figs. 1, 6, 7) or several (Figs. 4, 5) helicoids with a turn thickness increasing to the periphery, one ( figure 2) or two (figure 3) side of the profile of which is made along a line that satisfies equation (1), and the infrared radiation source 3 located on the camera axis.

The turns of the catalytically active element 2 are made (Fig. 2,3) adjacent to the inner surface of the chamber and the infrared radiation source 3, and their surface at the edge far from the axis is inclined to it at an angle φ ₁ not exceeding 85 ^° , and at the edge closest to the axis tilted to it at an angle φ ₂ selected in the range of 5-85 ^about . The turn of element 2 can be made (FIG. 2) with a thickness increasing in one direction or (FIG. 3) symmetrical with respect to the midline perpendicular to the axis of chamber 1. Step P of the helicoid of element 2 is equal to the maximum thickness S of its turn.

 When performing the apparatus with several helicoidal elements 2 (Fig. 4, 5), the winding direction of adjacent elements 2 is performed in the opposite direction, while it is advisable to mount (Fig. 5) the catalytically active elements 2 in removable cartridges 4.

In FIG. 5 shows the implementation of the porous elements 2 with a decreasing step towards the exit from the chamber with the flat mesh catalyst cassettes 5 installed behind them, completely overlapping the chamber section, before and after which additional infrared sources 7 are installed in the cassettes 6 parallel to them. Cassettes 5 and sources 7 are installed at an angle to the axis of the chamber 1, preferably in the range of 5-85 ^about . The catalytically active elements 2 and 5 are connected in series with an ultrasound source 8.

 6 and 7 show the implementation of the catalyst cassettes 5 from a catalytically active mass with conductive filler and their connection with the current source 9, when the cassettes 5 serve as sources of infrared radiation. In this case, it is possible (Fig. 7) to install before and after them in the cartridges 10 parallel to them sources 11 of ultraviolet radiation.

 Apparatus for thermocatalytic afterburning of exhaust gases works as follows.

 A gas stream containing toxic impurities is fed into chamber 1 into the helical channel of the helicoidal catalytically active element 2, where the molecules of toxic impurities are activated by infrared radiation of source 3 and oxidized on the catalyst surface of element 2. Local overheating of the surface of element 2 does not occur due to uniform radiation heating by source radiation 3 surfaces with a profile made along a line that satisfies equation (1), which simultaneously provides an equal probability of oxidation of toxic IMES across the element length equal to the rate of the chemical reaction of oxidation and equal exotherm.

 When installing several elements, the opposite direction of helical winding provides a change in the direction of twisting of the gas stream and its turbulence, which increases the likelihood of oxidation of toxic impurities. Also, the turbulization of the flow is enhanced by decreasing the pitch of the helicoid of element 2, especially when it is mesh, perforated, or porous, when part of the gas stream has the ability to pass through the element, which increases the quality of gas purification by increasing the likelihood of contact of toxic impurity molecules with the catalyst.

 The installation of mesh, perforated, or porous flat catalyst cassettes 5 that completely cover the cross section of the chamber 1 eliminates the possibility of breakthrough of individual gas jets without contact with the catalyst, which improves the quality of gas cleaning, especially when they are installed at an angle to the axis of the chamber 1, when these cassettes 5 additionally the gas stream, accelerating mass transfer processes in it, and is irradiated with infrared radiation of additional sources 7 in cassettes 6, or emit independently when passing current through them from source 9. V the last one if installation between cassettes 5 cassettes 10 with sources 11 of ultraviolet radiation it provides the activation and on the catalyst surface oxidation cassette 5 is not only gas, but also toxic pulverulent impurities, improving the quality of gas purification.

 The toxic impurities sorbed by the catalyst of elements 2 and 5 are oxidized directly in the catalyst mass to harmless substances when activated by the ultrasound of source 8, which reduces the likelihood of catalyst poisoning and increases the reliability of the apparatus.

 When several catalytically active elements 2 and / or 5 are installed in the apparatus and their failure occurs, repair work is carried out by replacing the corresponding removable cartridges 4 or 5 while maintaining the cartridges 4 and / or 5 with a working catalyst, which reduces the material consumption of the repair work.

 The gas stream processed on the catalyst, the toxic impurities of which are oxidized to harmless substances, is removed from chamber 1 and, if the apparatus is used in the food industry for drying food products with flue gases, is supplied to the drying chamber, and if it is used in industrial ecology to detoxify ventilation emissions, the atmosphere.

 Thus, the proposed apparatus by ensuring uniform illumination of the developed surface of the catalyst ensures the absence of local overheating of the catalyst and increase the efficiency of gas purification.

Claims (20)

1. APPARATUS FOR THERMAL-CATALYTIC RELEASING OF RELEASE GASES, comprising a cylindrical chamber with a catalytically active element and an infrared radiation source located along the axis of the chamber, characterized in that the catalytically active element is made in the form of a coaxial helicoid with at least one revolution thickening to the periphery of the coil from the sides of the profile of which is made along a line that satisfies the equation in elliptic coordinates with the center of coordinates on the camera axis

where x and y coordinates;
a predetermined constant that determines the operating conditions of the catalyst, m ² .  2. The apparatus according to claim 1, characterized in that the turns of the catalytically active element are made adjacent to the inner surface of the chamber.  3. The apparatus according to claims 1 and 2, characterized in that the turns of the catalytically active element are made adjacent to the source of infrared radiation. 4. The apparatus according to claims 1 to 3, characterized in that the surface of the turn edge farthest from the camera axis is inclined to it by no more than 85 ^° . 5. The apparatus according to claims 1 to 4, characterized in that the angle of inclination of the surface of the coil at the edge closest to the axis of the camera is 5-85 ^o .  6. The apparatus according to claims 1 to 5, characterized in that the thickness of the coil increases in one direction.  7. The apparatus according to claims 1 to 5, characterized in that the coil is made symmetrical with respect to the midline perpendicular to the axis of the camera.  8. The device according to PP.3 to 7, characterized in that the pitch of the helicoid is equal to the maximum thickness of the coil.  9. The apparatus according to PP.1 to 8, characterized in that it is equipped with at least one additional catalytically active element, made with the opposite direction of the helicoid winding and installed behind the previous one in series and coaxially.  10. The apparatus according to claims 1 to 9, characterized in that the catalytically active elements are mounted in removable cassettes.  11. The apparatus according to claims. 1 to 10, characterized in that the catalytically active elements are mesh, perforated or porous.  12. The apparatus according to claims 1 to 11, characterized in that the helicoid is made with a decreasing step towards the exit from the chamber.  13. The apparatus according to claims 1 to 12, characterized in that it is equipped with at least one removable flat catalyst cartridge made of a mesh, perforated or porous, mounted behind the helical catalytically active elements and completely overlapping the section of the chamber. 14. The apparatus according to item 13, wherein the flat catalyst cartridge is installed at an angle of 5 85 ^o to the axis of the chamber.  15. The apparatus according to claims 13 and 14, characterized in that it is equipped with additional sources of infrared radiation, combined in removable cassettes installed before and / or after the flat catalyst cartridge.  16. The apparatus according to p. 15, characterized in that the cassettes with additional sources of infrared radiation are parallel to the flat catalyst cassette.  17. The apparatus according to claims 13 and 14, characterized in that the flat catalyst cartridge is made of a catalytically active mass with conductive filler, connected to a current source and serves as a source of infrared radiation.  18. The apparatus according to 17, characterized in that it is equipped with sources of ultraviolet radiation, combined in removable cassettes installed before and / or after a flat catalyst cassette.  19. The apparatus according to p. 18, characterized in that the cassettes with sources of ultraviolet radiation are parallel to the flat catalyst cassette.  20. The apparatus according to claims 1 to 19, characterized in that it is equipped with an ultrasound source connected to at least one catalytically active element.

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