RU2163835C1 - Honeycomb foal apparatus - Google Patents

Abstract

FIELD: heat and power engineering; chemical industry. SUBSTANCE: apparatus may be used for performing the processes of gas cleaning and mass and heat exchange during endothermal and exothermal reactions with participation of liquid and gaseous media in any branch of national economy. Honeycomb foam apparatus can operate at height of foam layer from 80-100 mm to 3-4 m and more. Size of height may be limited either by sufficiently optimal conditions of said process performance or by power of draught equipment. Apparatus has a body, reaction chamber, separator, grid, overflow device, tray, gas-inlet branch pipes, honeycomb grid, and heat exchanger. Horizontally positioned perforated sheet with holes of round or any other form arranged uniformly serves as a grid. Gas-inlet branch pipes of form similar in plan and of preset height are coupled to the holes tightly from the top. Gas-removing branch pipe is placed in center of every cell of honeycomb grid. Height of branch pipe is equal to tray depth and lower part of honeycomb grid plates is submerged under liquid level in tray. Diffuser is mounted above reaction chamber of the apparatus. Gas-flow moving stabilizer controlled by hoisting-and-lowering mechanism is installed in center of diffuser. EFFECT: enhanced efficiency. 7 cl, 5 dwg

Description

 The invention relates primarily to the power system and the chemical industry, as well as to sanitary equipment, utilities and can be used for gas purification, heat and mass transfer during endo and exothermic reactions involving liquid and gaseous substances in any sector of the national economy, for example , for contact and contact-surface heating of water with products of combustion of natural gas, liquid and solid fuels, as well as for the neutralization of alkaline wastewater with carbon dioxide flue gas gas or for cooling and condensation of vapors in the processes of chemical technology, engineering industry, steel and automotive industries when solving environmental problems in protecting air, water basins and soil from gaseous and mechanical pollution by processing liquids and gas purification, or for air conditioning , practically without limiting the magnitude of the flow of gas and liquid in one device and regardless of the variety of technological processes.

 Known foam apparatuses designed for gas purification, as well as heat and mass transfer processes during endo- and exothermic reactions involving liquid and gaseous substances. Such devices have a housing, a nozzle with an irrigation device for supplying and spraying liquid, a nozzle for draining the liquid / pulp /, gas outlet and gas supply nozzles, a grate on which a foam layer is formed, a hopper / TARAT E. Ya. Et al. Foam mode and foam apparatuses. L .: "Chemistry", 1977, 304 p. Fig. 9/. The lattice in such an apparatus is a perforated sheet with evenly spaced round holes (diameter 8-10 mm), slit-like or any other shape. The manufacture of gratings requires high professionalism of the performers and is an energy-intensive process. In an apparatus with such a grating, the size of its diameter or a larger side is determined by the possibility of a uniform distribution of gas and usually does not exceed 400-500 mm. The hydraulic mode of such an apparatus is the least stable, since there is no overflow device in it. When processing, especially wastewater, openings in the grate tend to clog and overgrow, which significantly reduces the efficiency of such an apparatus and can ultimately lead to its complete stop. In the apparatus at gas velocities of more than 2 m / s, a wave mode occurs (rocking of the foam layer), which leads to a deterioration in the structure of the foam and reduces its efficiency.

 The closest in technical essence is a foam scrubber with a foam layer stabilizer PGPS-LTI-I / TARAT E.Ya. and others. Foam mode and foam machines. L .: "Chemistry", 1977, 304 p. Fig. VI / 1 /. Such an apparatus has a housing, a counterflow failure or tubular grate, a foam stabilizer, an irrigation device, a separator, a pipe for draining liquid / pulp /, gas, gas supply pipes and a hopper. However, in such an apparatus, the hydraulic mode remains unstable, the height of the foam is in the range of 100-120 mm, and the maximum diameter is 1520 mm, which does not solve all the problems.

 The objective of the invention is the creation of a cellular foam apparatus, providing a technical result, consisting in increasing the efficiency of the apparatus and in expanding the boundaries of its use.

 This technical result in a cellular foam apparatus containing a housing, a reaction chamber of the apparatus, a pipe for supplying liquid, a separator, a pipe for supplying gas, a gas outlet, a grate, an overflow device, a pan, a gas inlet, a gas distribution chamber, a honeycomb grate, honeycombs, transverse and longitudinal plates, honeycomb reaction space, surface heat exchanger, pipes of the main collectors for supplying cold and draining hot water, supply and discharge headers, pipe coils, openings for a fluid stream, a diffuser, a gas flow stabilizer and a lifting and lowering mechanism, is achieved by the fact that the grating is a horizontally located perforated sheet with evenly spaced openings of a round or another other shape, to which gas supply pipes of a similar shape and a predetermined height are sealed on top, which makes it possible to form a pan on the grate, under which a gas distribution chamber is placed, and a reaction chamber of the apparatus, in which the surface heat exchanger and the honeycomb grill are placed in such a way that a gas supply pipe is placed in the center of each cell, the height of which is equal to the depth of the pallet, and the lower part of the plates of the honeycomb grill is immersed / not to the entire depth / under the liquid level in the pallet, where in the space under the lower holes for fluid flow are left with the edges of the transverse and longitudinal plates, and a diffuser is installed above the reaction chamber of the apparatus, in which a movable gas flow stabilizer, controlled by a lifting and lowering valve, is placed in the center m mechanism.

 The pallet placed on the grate allows for uniform discharge of water / pulp / from the apparatus through the overflow openings through the overflow device, which makes it possible for each individual cell to work independently and uniformly with all other cells of the apparatus, since the overflow device also performs smoothly regulation and stably maintains the specified foam layer height in the apparatus in the range from 80-100 mm to 3-4 meters and ensures the stability of the aero-hydrodynamic regime, which increases the effect the operability of each individual cell and the apparatus as a whole allows it to practically not limit the number of cells in it, and their calculated number in combination with their size and foam height can be limited either by the sufficiency of providing optimal conditions for a given technological process, or by the power of blowing equipment, which increases the efficiency of the device and expands the boundaries of its use.

 In a cellular foam apparatus, the gas flow through the gas distribution chamber and gas supply nozzles uniformly from below acts on the foam layer in the reaction space of each cell, regardless of their height and cross-sectional dimensions in plan throughout the apparatus as a whole, due to the smooth regulation of aerodynamic performance by gradual vertical lift or lowering in the diffuser in the center of the movable stabilizer of the gas flow by the lifting and lowering mechanism, which increases the efficiency of the cellular foam a device and expands the scope of its use.

 In a cellular foam apparatus, the surface heat exchanger is a tube structure that is identical in size and configuration to the honeycomb lattice, and its pipelines, which are actively involved in the heat exchange process, are tightly mounted in the plane of the longitudinal and transverse plates, which provides a counterflow between gas and liquid in the apparatus, thereby causing an increase in the efficiency of the cellular foam apparatus and its compactness.

 In the cellular foam apparatus, the honeycomb lattice is partially immersed / below the liquid mirror / in the pan, which makes it possible to change the ratio of the depths of immersion of the plates of the honeycomb lattice under the liquid level in the pallet to the full depth of the pallet in the range from 0.001 to 0.95 and allows the formation of a water seal around the entire perimeter of the cells in the device, which prevents unorganized flow / breakthrough / gas between the cells, thereby increasing the efficiency of the device and expanding the boundaries of its use.

 The possibility of changing the magnitude of the ratios between the cross-sectional area of the gas supply pipe to the cross-sectional area of the reaction space of the cell, in the range from 0.2 to 0.9, expands the scope of use of the cellular foam apparatus.

 The area of effective operation of the cellular foam apparatus determines the equal width of the transverse and longitudinal plates in the range from 0.03 to 3.0 m, which expands the scope of its use.

 The effective area of the cellular foam apparatus determines the ratio of the part of the height of the plates of the cell equal to the distance from the plane of the cross section of the outlet of the gas supply pipe to the top of the plates to the height of the foam layer in the cell, in the range from 1.0 to 2.0.

 In FIG. 1 is a longitudinal section through a cellular foam apparatus; in FIG. 2 shows a section of a cellular foam apparatus along section AA; in FIG. 3 is a perspective view of a general view of a honeycomb lattice; in FIG. 4 is a perspective view of a general view of a surface heat exchanger, and FIG. 5 is a perspective view of a central honeycomb of a honeycomb lattice with surface heat exchanger tubes mounted in its plane.

 The cellular foam apparatus comprises a housing 1, a reaction chamber of the apparatus 2, a pipe for supplying liquid 3, a separator 4, a pipe for supplying gas 5, a gas outlet 6, a grill 7, an overflow device 8, a tray 9, a gas outlet 10, a gas distribution chamber 11, a cellular grid 12, honeycomb 13, transverse plates 14, longitudinal plates 15, reaction space of honeycomb 16, surface heat exchanger 17, main manifold pipe for supplying cold water 18, main manifold pipe for draining hot water 19, auxiliary feed pipes ora 20, diverting auxiliary collectors 21, pipe coils 22, holes for fluid flow 23, a diffuser 24, a gas flow stabilizer 25, and a lifting and lowering mechanism 26.

 In a cellular foam apparatus, a gas stream with a speed of up to 22 m / s enters through a pipe for supplying gas 5 to a gas distribution chamber 11, from where it enters a cell 16 through a gas supply pipe 10, where liquid simultaneously flows through a pipe 3. In the reaction space of the honeycomb 16, the liquid is mixed with gas - thus forming a layer of gas-liquid emulsion / foam /. A mobile gas-liquid emulsion can fill the entire reaction space of cells 16, since the height and structure of the foam mainly depend on the gas velocity and the height of the underflooding of the gas supply pipe 10 and can reach several meters. As the gas-liquid emulsion moves upward, foam gradually resolves. The liquid is discharged to the walls of the housing 1 and to the walls of the honeycombs 13 and, under the action of gravity, flows down into the pan 9, where, moving in a horizontal plane through the holes for the fluid flow 23, it is directed to the overflow device 8. The gas processed in the apparatus is freed from trapped liquid droplets in the separator 4 and it is led outward along the exhaust pipe 6. The overflow device 8 in the apparatus allows you to adjust and maintain a predetermined flooding height of all gas supply pipes 10 at the same time. The drainage of the liquid as a whole from the pallet 9 occurs by flowing along the grate evenly from each individual section of the pallet 9, which is limited by the perimeter of the cell 13, through the holes for the flow of liquid 23. Thus, in the apparatus, all the liquid from the pallet 9 enters the overflow device 8, which has a water lock that prevents the passage of gas out.

 To ensure the uniform operation of all cells 13 of the apparatus as a whole, a gas flow stabilizer 25 is provided, which is located in the center of the diffuser 24 and with the help of the lifting-lowering mechanism 26 is able to move vertically / up-down / and, therefore, regulate the aerodynamic performance of the gas flow and evenly affect the height and structure formation of the foam layer in the apparatus.

 To heat the water, in the apparatus, in the volume of the reaction chamber of apparatus 2, a surface heat exchanger 17 is placed, which is a tube structure identical in size and configuration to the honeycomb grid 12. Cold water from the water supply through the main collector pipe 18 enters the surface heat exchanger 17 supply auxiliary collectors 20, from which flows into the pipe coils 22, where it is actively heated in countercurrent in the foam layer. Heated water then flows into the secondary auxiliary collectors 21, from which it enters the pipe of the main collector to drain hot water 19 and is sent to the consumer.

 The body of the cellular foam apparatus has a square or round shape and can be made of plastics, glass, metal, ceramics, asbestos cement, concrete and reinforced concrete. The plates of the apparatus can be made of glass, metal, aluminum and its alloys. The pipes of the surface heat exchanger are made of stainless steel, and the pipe coils are made of smooth copper or stainless pipes, or glass, or brass, or aluminum and its alloys.

 The general characteristics of the cellular foam apparatus are shown in Table 1 according to the indicators of the hot water supply project for domestic needs, based on the boiler KV-G-2.5-95 of the UVT-5G water-heating plant manufactured by TKZ KRASNY KOTELSCHIK OJSC in Taganrog .

The cellular foam apparatus is compact due to the high intensity of the process. For example, the apparatus operates reliably at an irrigation density of up to 300 m ³ / m ² · h in the process of neutralizing alkaline wastewater with carbon dioxide flue gas. During gas purification and flue gas cooling, the cellular foam apparatus is able to operate without an external irrigation system / with self-irrigation /. There are no moving parts and elements in the apparatus, and a liquid dip in the grate is also completely excluded, which ensures high reliability and efficiency of its operation in the presence of contaminants in the gas and liquid at the same time. In this case, it is especially worth noting the relatively low relative energy intensity and small dimensions of the apparatus.

Claims (7)

 1. A cellular foam apparatus comprising a housing, a reaction chamber of the apparatus, a fluid supply pipe, a separator, a gas supply pipe, a gas outlet pipe, a grill, an overflow device, a tray, gas supply pipes, a gas distribution chamber, a honeycomb grill, honeycombs, transverse and longitudinal plates , honeycomb reaction space, surface heat exchanger, pipes of the main collectors for supplying cold and draining hot water, supply and discharge auxiliary collectors, pipe coils, openings for the flow of liquid a tee, a diffuser, a gas flow stabilizer and a lifting and lowering mechanism, characterized in that the grate is made in the form of a horizontally arranged perforated sheet with evenly spaced openings of a round or another other shape, to which gas supply pipes of a similar shape and a predetermined height are hermetically tightly connected from above forming a pan on the grate, under which a gas distribution chamber is placed, and above the pan there is a reaction chamber of the apparatus in which surface heat is placed the exchanger and the honeycomb lattice in such a way that a gas outlet is placed in the center of each cell, the height of which is equal to the depth of the pan, and the lower part of the plates of the honeycomb lattice is not submerged to the entire depth below the liquid level in the pan, where in the space under the transverse and longitudinal plates are located holes for fluid flow, and a diffuser is installed above the reaction chamber of the apparatus, in which a movable gas flow stabilizer, controlled by a lifting and lowering mechanism, is placed in the center.  2. The apparatus according to claim 1, characterized in that the honeycomb lattice is partially immersed below the liquid mirror in the pan, which makes it possible to change the ratio of the depth of immersion of the plates of the honeycomb lattice under the liquid level in the pallet to the full depth of the pallet in the range from 0.001 to 0.95 and forms a water seal along the entire perimeter of the cells in the apparatus.  3. The apparatus according to claim 1, characterized in that the gas flow stabilizer is installed with the possibility of gradual vertical rise or lower in the diffuser in the center of the lifting and lowering mechanism.  4. The apparatus according to claim 1, characterized in that the surface heat exchanger is a tube structure that is identical in size to the honeycomb grid and its pipelines and pipe coils actively involved in the heat exchange process are tightly mounted in the plane of the longitudinal and transverse plates .  5. The apparatus according to claim 1, characterized in that the magnitude of the relationship between the cross-sectional area of the gas supply pipe and the cross-sectional area of the reaction space of the cell is in the range from 0.2 to 0.9.  6. The apparatus according to claim 1, characterized in that the transverse and longitudinal plates have an equal width in the range from 0.03 to 3 m  7. The apparatus according to claim 1, characterized in that the ratio of the part of the height of the plates of the cell equal to the distance from the plane of the cross section of the outlet of the gas supply pipe to the top of the plates to the height of the foam layer in the cell is in the range from 1.0 to 2.0 .

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