RU2500867C2 - Energy-saving device for cleaning of smoke gases of group of heat generators of apartment heating systems - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: energy-saving device for cleaning of smoke gases of a group of heat generators of apartment heating systems comprises a box laid onto the upper slab of the building, made from a corrosion-resistant material, the bottom of which is equipped with holes connected with pipes of individual flues and sewage drains and connected on the opposite edges with atmosphere via flues with deflectors, besides, each flue at the rear side is equipped with a door, inside it there are rows of vertical perforated cassettes opened on top, forming vertical gas channels between each other, vertical perforated cassettes are made from a corrosion-resistant material, their cavities are filled with an adsorbent - granules of pumice made from metallurgical slags with lime factor M>1 and diameter of granules from 5 to 10 mm, the bottom of the box is made with inclination I towards sewage risers, and upper edges of pipes of individual flues are arranged above the level of the bottom of the box by the value of δ.

EFFECT: higher reliability and efficiency of an energy-saving device for cleaning of smoke gases of a group of heat generators of apartment heating systems.

5 dwg

Description

The invention relates to a power system and can be used to clean flue gases from harmful impurities from sources of heat supply for apartment heating systems.

Known sanitary prefix for heat generators of autonomous heat supply systems, consisting of a housing equipped with inlet and outlet flue gas nozzles, inside of which are removable horizontal perforated baskets filled with a mixture of hydrated lime chips Ca (OH ₂ ) and activated carbon, covered with a grate covered with a layer of high-viscosity fuel oil In this case, horizontal rows of perforated and non-perforated pipes are arranged under the baskets, an axial fan is placed in the air pipe, and the smoke outlet pipe is placed call communicates with the atmosphere through the chimney and the deflector, and is provided with a conical bottom tray connected with the drain through a water seal pipe [RF patent №2390692, IPC F23J 15/02, 2010].

The main disadvantages of the known device include the complexity and bulkiness of the design, which does not allow its use in residential heating systems.

Closer to the proposed invention is a column for complex flue gas cleaning, containing a rectangular casing, with outlet and intake air slots, closed at the bottom with a flat pyramidal bottom with a removable cup, and a prismatic lid on top, inside of which there is a gate equipped with inlet and outlet pipes, respectively at the same time, three cleaning stages, consisting of vertical perforated cassettes, are placed inside the case along the flue gas movement. sides filled with an adsorbent, which is particles of crushed slaked lime (Ca (OH) ₂ ), activated carbon and a metal mesh coated with a layer of paraffin, and between the cassettes there are gas channels and air channels connected in their lower part to the intake slots, in the upper - with exit slots, forming a plate heat exchanger, and the inlet and outlet nozzles are connected to the heat generator gas duct [RF Patent No. 2414281, IPC B01D 53/46, 2011].

The main disadvantages of the known column for complex flue gas cleaning include the impossibility of utilizing flue gas heat and flue gas cleaning from a group of heat generators, the complexity of the cleaning unit design, the high cost of adsorbent (activated carbon) and the impossibility of its regeneration, which reduces the reliability and efficiency of the device.

The technical result achieved by the invention is to increase the reliability and efficiency of an energy-saving device for cleaning flue gases from a group of heat generators of apartment heating systems.

The technical result is achieved by the fact that the proposed energy-saving device for cleaning flue gases of a group of heat generators of apartment heating systems contains a box laid on the upper floor of the building, made of corrosion-resistant material, the bottom of which is provided with openings connected to the channels of individual chimneys and sewer risers and connected to the opposite edges with the atmosphere through the chimneys with baffles, and each chimney on the back side is equipped with a door, In the morning, there are rows of vertical perforated cassettes open on top, forming vertical gas channels between them, vertical perforated cassettes are made of corrosion-resistant material, their cavities are filled with adsorbent — pumice granules made of metallurgical slag with a basicity module M> 1 and a granule diameter of 5 to 10 mm, the bottom of the duct 1 is made with a slope I towards the sewer risers, and the upper edges of the channels of individual chimneys are located above the surface of the bottom of the duct by Well δ.

The proposed energy-saving device for cleaning flue gases of a group of heat generators of apartment heating systems (EUODG) is presented in Figs. 1-5 (Fig. 1 is a general view of the device, Figs. 2, 3 are a general view and section of a chimney; 4, 5 are docking units with the bottom of the duct of sewer risers and chimney channels of heat generators).

The proposed EUODG contains a duct 1 made of a corrosion-resistant material laid on the upper floor 2 of the building, the bottom of which is provided with openings 3 and 4 connected to the channels of individual chimneys 5 and sewer risers 6, respectively, connected at opposite edges to the atmosphere through chimneys 7, equipped with deflectors 8, and each chimney 7 on the back side is equipped with a door 9, inside it there are rows of vertical perforated, open top cassettes 10, forming a vertical gas channels 11, vertical perforated cartridges 10 are made of corrosion-resistant material, their cavities are filled with pumice granules 12 made of metallurgical slag with a base module M> 1 and a granule diameter of 5 to 10 mm, the bottom of the duct 1 is made with a slope of I sewer risers 6 and the upper edges of the pipes of individual chimneys 5 are located above the surface level of the bottom of the duct 1 by a value of δ.

EUODG works as follows. Flue gases from the group of heat generators (not shown in FIGS. 1-5) of the residential building through the chimney pipes 5 enter the duct 1, which contacts the upper floor of the building through its bottom and is washed by the attic air through the roof of the duct 1 from the top (in FIG. 1 -5 not shown) or with outside air. In the box 1, they are evenly distributed in its cavity, moving to the nearest chimney 7. As it moves, as a result of heat exchange with the upper floor 2 of the building and the attic air (not shown in Figs. 1-5) through the walls of the bottom and the lid of the box 1 flue gases, as a result of a large area of heat exchange (bottom and cover) of the box 1, are rapidly cooled to a temperature below the dew point with the formation of condensate of water vapor present in them, which, in contact with the gas medium, absorbs nitrogen oxides (NO _x ), sulfur oxides (SO _x ), ox carbon ides (CO and CO ₂ ) and other harmful components, forming acid condensate, draining along an inclined bottom with a slope of I into the sewer risers 6, where it mixes with wastewater, moving away with them to treatment facilities (the angle of slope I should be greater or equal to the angle of repose of water). At the same time, moving along the bottom of the duct 1, acid condensate does not flow into the channels of the chimneys 5, so their edge is higher than the surface of the bottom of the duct 1 by a value of δ, the value of which is selected from the condition of guaranteed prevention of condensate from entering the ducts of the flues 5. Approaching the edge of the duct 1, chilled and partially cleaned of harmful components, the flue gases enter the chimneys 7, inside which vertical perforated cartridges 10 are placed (the attachment points of the cartridges 10 are not shown in FIGS. 1-5), between which there are gas channels 11. Dymov e gases pass through the gas channels 11, penetrate through the holes in the walls of the vertical perforated cassettes 10, filled with granules 12 of slag pumice with a diameter of 5 to 10 mm, made of basic metallurgical slags (the diameter of the granules 12 is assigned from the conditions of maximum filling of the cartridges 10 and the standard range of sizes granules of slag pumice). Slag pumice made from basic metallurgical slag is a material with a highly porous mechanically strong structure consisting of calcium oxide, silicon oxide, aluminum oxide and partially magnesium oxide (CaO, SiO ₂ , Al ₂ O ₃ , MnO) with the basicity module M > 1 [Building materials. Directory. Ed. Boldyreva A.S. et al. - M.: Stroyizd., 1989, p. 423; Domokeev A.K. Construction Materials. - M .: Higher. School, 1989, p. 163]. The high basicity modulus gives the granules 12 basic properties, allowing them to sorb substances with acidic properties on their surface, which include harmful impurities present in flue gases (NO _x , SO _x , CO, CO ₂ ), and a high porosity of their structure creates a high specific surface, which, ultimately, allows the use of granules 12 of slag pumice as an effective adsorbent for harmful impurities of flue gases at various temperatures. In addition, based on its composition, granules 12 of slag pumice are resistant to the corrosive effects of acidic components of flue gases, are widely available and relatively cheap. The flue gas stream passing through the gas channels 11 and repeatedly reaching the surface of the granules 12 and inside them is cleaned of harmful impurities (NO _x , SO _x , CO, CO ₂ ), which are sorbed on the surface and inside the granules 12. Oxides adsorbed from the flue gases nitrogen and sulfur in the pores of granules 12 have a high reactivity due to their interaction with the surface of the adsorbent granules 12 of slag pumice [Nenitscu K. General chemistry - M .: Mir, 1968, p. 298], therefore, they are oxidized by oxygen (oxygen is present in flue gases as a result of excess air supplied to the fuel) at a rate greater than in the gas phase with the formation of NO ₂ and SO ₃ readily soluble in water. The resulting nitrogen and sulfur oxides, in turn, interact with water particles generated in the pores of the granules 12 as a result of capillary condensation of water vapor in the flue gas, with the formation of the corresponding acids HNO ₃ and H ₂ SO ₄ . In addition, finely dispersed particles (soot, etc.), which are in the flue gases, settle on the surface and in the pores of the granules 12, after which the cleaned smoke pots from the gas channels 11 enter the deflector 8, from where they are released into the atmosphere. The additional resistance due to the presence of the duct 1 between the channels of the chimneys 5 and the chimneys 7 is compensated by the condensation of a significant part of the water vapor in it and the resulting significant reduction in the volume of flue gases, their insignificant speed in the duct 1, as well as the additional traction that creates deflector [V.N. Bogoslovsky et al. Heating and ventilation, Part II. - M .; Stroyizdat, 1978, p.309], which ultimately increases the total draft in all flues (chimney channels 5, duct 1 and chimneys 7). In this case, as a result of heat exchange, simultaneously with the cooling of the flue gases in the duct 1, due to the heat removed from them, the upper floor 2 of the building and the attic air are heated. The intake of acid condensate, obtained as a result of condensation of water vapor and enriched with harmful components of flue gases, into wastewater through sewer risers 6, reduces their pH and the appearance of solid deposits in the corner and horizontal sections of pipes of the sewer network, and the resulting wastewater enrichment with CO ₂ promotes the processes of photosynthesis [Komov VP et al. Biochemistry. - M .: Drofa, 2004, p.210] in the fields of irrigation of urban wastewater treatment plants.

EUUH smoke pipes are placed along the edges of both roof slopes so that the deflectors 8 of the opposite rows of pipes 7 can compensate each other when the wind direction changes. The dimensions of one duct 1 and the number of chimneys 7 on it depend on the number and power of the served group of heat generators, the number of chimney channels 5, the distance between them and. determined by technical and economic calculation. In this case, a prerequisite should be the presence in the duct 1 of sewer risers 6. The number of ducts 1 and the total number of chimneys 7 on the roof are determined from the ratio of the areas of the building and duct 1. The dimensions of the chimneys 7 and perforated cartridges 10, the granule volume 12 in each , the number of perforated cartridges 10, their length, height and width, the width of the gas channels 11 are determined depending on the total power of the served group of heat generators, fuel consumption and type, as well as the required degree of flue gas purification.

When the activity of the granules 12 decreases, they are subjected to regeneration, which is carried out in the summer. The regeneration process consists in cleaning the surface and pores of the granules 12 from fine particles and adsorbed molecules of harmful impurities and is carried out by washing the granules 12 with warm water when opening the doors 9. During mechanical wear of the granules 12 they are replaced with fresh ones.

Thus, the proposed EUODG provides a centralized purification of flue gases from a group of heat generators and from harmful components without the use of expensive and hazardous chemicals, allows you to simultaneously utilize their heat using slag pumice granules made from basic metallurgical slags with a basicity module M> 1, s high reliability and efficiency.

Claims (1)

An energy-saving device for cleaning flue gases from a group of heat generators of apartment heating systems, including a duct made of corrosion-resistant material, a chimney with a deflector, vertical perforated cassettes made of corrosion-resistant material, filled with adsorbent and installed with the formation of vertical gas channels between them, characterized in that the duct is laid on the upper floor of the building, its bottom is equipped with openings connected to the channels of individual chimneys and canals of the riser pipes, its opposite edges are connected to the atmosphere through chimneys, each chimney on the back side equipped with a door, inside it there are rows of vertical perforated cassettes open on top, filled with pumice granules made of metallurgical slag with a base module M> 1 and diameter granules from 5 to 10 mm, the bottom of the box is made with a slope I towards the sewer risers, and the upper edges of the pipes of individual chimneys are located above the level of the surface of the bottom of the box by values δ.

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