EA010144B1 - Boiler-utilizer - Google Patents

Abstract

The invention relates to thermal engineering and can be used in boiler-utilizers, installed downstream metallurgic furnaces for cooling high-temperature dust-laden gases utilizing their heat for steam production, in particular, in boiler-utilizers downstream furnaces in non-ferrous metallurgy. A horizontally-positioned boiler-utilizer comprises radiation (1) and convection (2) gas flues with limiting walls (4) and bins (3), rows of thermosiphon pipes (5) with coolers (6) fixed in the upper part of gas flue and united into blocks (7) by upper (8) and bottom (9) cooler header, upper (10 and lower (11) aerodynamic partitions, wherein all thermosiphone pipes (5) are positioned inside the convection gas flues (2), their working length L constitutes 2/3-1 of the height of side limiting walls, transverse pitch Sbetween the thermosiphon pipes in the block equals to 2-3 diameters d, longitudinal pitch Sbetween the thermosiphone blocks equals to 1-1.2 diameter D of the lower cooler collector, and the lower aerodynamic partition is also positioned in the convection gas flue beneath the thermosiphon blocks. The technical result is aimed at increasing thermal output of boiler-utilizer by 10-30% due to the simultaneous increase of heat-exchange surfaces, their lesser contamination and higher rate of their purification.

Description

The invention relates to the field of power engineering and can be used in boiler utilizers installed behind metallurgical furnaces for cooling high-temperature dusty gases with utilization of their heat to generate steam, in particular, in waste heat boilers behind non-ferrous metallurgy furnaces.

The flue gases of most non-ferrous metallurgy furnaces have a high temperature, which makes it possible to efficiently use their physical heat, however, they are characterized by a high content of sublimates of non-ferrous metals and fine charge ash, which is in a softened state.

Known U-shaped waste heat boiler, including a radiation duct made of screen panels with rows of thermosyphons with refrigerators installed in it, and a convective gas duct connected to it, in which rows of thermosyphons with refrigerators are also located, the lower collectors of which are fastened along the entire length, they form a ceiling overlap (see RF certificate for utility model No. 29979, MPK P22V1 / 18, priority dated July 23, 2002, published June 10, 2003, Bull. No. 16, "Waste-heat boiler").

A disadvantage of the known device is that the rows of thermosyphons installed in the radiation and convective duct are intensively clogged with sediments, which reduces the efficiency of heat exchange.

Rows of thermosyphons installed in a radiation flue, where the temperature of dusty gases is higher than the temperature of solidification of dust, are clogged with agglomerated dust, which sharply reduces the heat transfer of the aforementioned additional heat exchange surfaces.

In a convective gas duct, due to a decrease in the gas temperature, the adhesive ability of dust decreases and the velocity of the gases increases. However, the rows of thermosyphons installed in the convective gas duct of the well-known U-shaped waste heat boiler are washed by the gas flow at high speed in the longitudinal direction, as a result of the natural oscillations of thermosyphon pipes with a limited length are minimal and the effect of self-cleaning from the growing sediments does not occur.

The closest in technical essence to the claimed device is a waste heat boiler located horizontally, including a radiation gas duct with fencing heat exchange surfaces and a convective gas duct installed under the gas ducts for collecting dust, while additional heat exchange surfaces are installed in the radiation duct, made in the form of a drum separator for rows of thermosyphon tubes with refrigerators fixed in the upper part of the duct, located relative to each other in staggered order and combined into blocks upper and lower collectors of refrigerators, and in the convective gas duct heater sections are installed.

In addition, in the upper part of the radiation flue, a partition is installed as a series of thermosyphons to change the direction of gas movement downwards, and in the lower part - along the direction of gas movement, a partition is used to change the direction of gas movement to rows of thermosyphons (see RF certificate for useful model No. 17354 IPC R22V31 / 08, priority of 10.10.2000, published on March 27, 2001, Byul. No. 9, “Waste Heat Recovery Boiler”).

A disadvantage of the known device is that the additional heat exchange surfaces installed in the radiation flue, made in the form of rows of thermosyphons combined in blocks connected to the separator drum, are intensively clogged in the radiation flue in the radiation flue, which reduces the heat exchange efficiency and makes effective cleaning impossible available heat transfer surfaces.

The technical result of the claimed invention is to increase the heat output of the recovery boiler by simultaneously increasing the heat exchange surfaces, reducing their pollution and increasing the degree of their cleaning.

The technical result is achieved by the fact that in the inventive waste heat boiler, located horizontally, includes radiation and convection duct, each of which contains enclosing walls and bunkers, rows of thermosyphon tubes with refrigerators, fixed in the upper part of the duct, combined into blocks by upper and lower headers of refrigerators , and the upper and lower aerodynamic partitions according to the invention, all pipes of thermosyphons are located in a convective gas duct, and their working length is 2 / 3-1 of the heights fencing walls, while the transverse pitch between thermosyphon pipes in a block is 2-3 diameters of thermosyphon pipes, the longitudinal spacing between thermosyphon blocks is 1-1.2 diameters of the lower collector of refrigerators, and the lower aerodynamic partition is also installed in the convective gas duct under the thermosyphon blocks.

When installing thermosyphon blocks with a working length of thermosyphon pipes equal to 2 / 3-1 of the height of side enclosing walls in a convective gas duct, transverse spacing between the pipes of thermosyphons in a block equal to 2-3 diameters of thermosyphon pipes and a longitudinal step between blocks of thermosyphons equal to 1-1 , 2 diameters of the lower collector of refrigerators, is achieved, on the one hand, an increase in the heat exchange surface in a given volume due to the maximum filling of the volume with pipes and, on the other hand, a simultaneous decrease in the buildup of deposits and clogging spread of space

- 1 010144 between the pipes due to the provision of their own vibrations, which generally improves the conditions for cleaning loose dust and increases the efficiency of heat transfer (convective heat transfer), and, consequently, the heat output of the recovery boiler.

The lower partition, installed along the convective gas duct under the blocks of thermosyphons, contributes to the direction of gas movement on the convective heat exchange surfaces and dust deposition in bunkers under them.

The intensity of natural oscillations of thermosyphon blocks washed in a convective flue in the transverse direction by the flow of high-speed dusty gases is due to the increased flexibility of thermosyphon pipes along their entire length within the claimed ratios of their length and height of side walls that prevent the accumulation of deposits on the pipes and blockage of the space between the pipes nagylyu

The resulting natural oscillations allow one to achieve the self-cleaning effect without forced oscillations, which makes it less likely to resort to purification by exciting forced oscillations.

When the working length of the thermosyphon pipes is less than two thirds of the height of the side walls protecting the heat exchange surface unnecessarily decreases and the flexibility of the pipes decreases. The maximum working length of thermosyphon pipes, corresponding to the height of the side walls, is determined by the configuration of the bunker and the height of the layer of dust accumulating in the bunker.

When the transverse pitch between the pipes of thermosyphons in the block is less than 2 diameters of the pipes of thermosyphons and the longitudinal pitch between the blocks of thermosyphons less than 1 diameter of the lower collector of refrigerators, intensive formation of nastily between the pipes and an increase in deposits on the pipes of heat exchange surfaces occurs.

When the transverse pitch between the pipes of thermosyphons in the block is more than 3 diameters of the pipes of thermosyphons and the longitudinal pitch between the blocks of thermosyphons more than 1.2 diameters of the lower collector of refrigerators, cleaning conditions improve, however, the heat transfer efficiency decreases sharply by reducing the heat exchange area of convective surfaces in a given volume.

Technical solutions that coincide with the set of essential features of the invention have not been identified, which allows to make a conclusion about the compliance of the invention with the condition of patentability "novelty".

The inventive essential features of the invention, determining the receipt of the specified technical result is not explicitly follow from the prior art, which allows to make a conclusion about the compliance of the invention to the condition of patentability "inventive step".

The condition of patentability "industrial applicability" is confirmed by the example of a specific implementation.

FIG. 1 shows a longitudinal section of the recovery boiler; FIG. 2 is a cross-section of the boiler utilizer and the lower collector assembly I with refrigerators.

The tunnel-type waste heat boiler contains sequentially located radiation flue 1 and convective gas flue 2 with hoppers 3 located under them for collecting particles of dusty gases. The enclosing walls of the convective and radiation ducts 4, as well as the ceiling overlap of the radiation duct are made in the form of membrane heat exchange surfaces, the separate panels of which are fastened together by vertical and horizontal butt-tight gas-tight seams.

In a convective flue 2, heat exchange surfaces are installed, made in the form of rows of thermosyphon tubes 5 with refrigerators 6, combined into blocks 7 by upper 8 and lower headers 9 of thermosyphon refrigerators, while the lower headers of thermosyphon blocks refrigerators arranged in a row form the ceiling of the convective gas flue .

In the radiation flue, an upper aerodynamic partition wall 10 is installed, made of a block of thermosyphons, each tube of which is provided with curtains along the entire working length, symmetrically located on both sides and connecting with an overlap in the annular space.

The lower aerodynamic partition 11 of brick is installed in the middle along the convective gas duct under the blocks of thermosyphons.

In a particular embodiment each block thermosyphons working length L thermosyphons corresponds to the height H of the side boundary walls, namely 5700 mm, the lateral spacing January ₈ between the pipes thermosyphons at block is 2 pipe diameters thermosyphons b _are, namely, when the diameter of tube The 89 mm thermosyphon is 178 mm and the longitudinal step 8 ₂ between the thermosyphon blocks is equal to 1 diameter of the lower collector of refrigerators Ό, namely, when the diameter of the inlet manifold 219 mm is 219 mm.

The waste heat boiler works as follows.

Dusty gases with a temperature of 1000-1200 ° C and a speed of 0.5-1 m / s come from the metallurgical furnace to the radiation gas duct 1, where due to radiation radiation heat is transferred through the pipe walls of gas-tight membrane panels to the coolant and bends around the upper aerodynamic partition 10, with this from the gas flow occurs the loss of large fractions of dust in the bunkers, and the dust particles remaining in the gas are cooled, solidify and lose their adhesive ability.

- 2 010144

Then, gases with a temperature of 600–700 ° C and an increased rate enter the convective gas duct 2 with dust bins 3, where, washing the full convection heat-exchanging surfaces in the form of thermosyphon blocks 7 with the highest possible dense arrangement of pipes 5, they give off heat to the coolant. Water from the drum separator through the downstream circulation pipe gets into the lower collectors 9 of the refrigerators of thermosyphons 6 and from the upper collectors 8 flows back into the drum separator, being separated into water and steam.

Vibrating due to the movement of gases, thermosyphon tubes of optimal length, as well as optimal transverse and longitudinal spacing of thermosyphon blocks help reduce the formation of loose dust deposits and increase the degree of cleaning of heat exchange surfaces.

The lower partition 11 is installed along the convective flue below the thermosyphon blocks 7 and contributes, on the one hand, to the directional movement of gases to convective heat exchange surfaces, on the other hand, to the dust falling into the bunkers under them.

To clean the convective heat exchange surfaces, the gas pulse cleaning unit is periodically turned on.

As a result, due to the maximum possible increase in convective heat exchange surfaces and a simultaneous decrease in the formation of deposits on them and an increase in the degree of their purification, the heat output of the recovery boiler increases by 10-30%.

Claims (1)

A waste heat boiler located horizontally, including radiation and convection flues, each of which contains enclosing walls and bins, rows of thermosyphon tubes with refrigerators, fixed in the upper part of the duct, combined into blocks by the upper and lower collectors of the refrigerators, and the upper and lower aerodynamic partitions, characterized in that all the thermosiphon tubes are located in the convective gas duct, and their working length is 2 / 3-1 of the height of the side enclosing walls, while the transverse step between the tubes and thermosiphons in the block is equal to 2-3 diameters of thermosiphon pipes, the longitudinal step between the thermosiphon blocks is 11.2 diameters of the lower collector of refrigerators, and the lower aerodynamic partition is also installed in the convection duct under the thermosiphon blocks.