SU1622719A1 - Column for moisturizing outgoing gases of rotary furnaces of dry cement production technology - Google Patents

Abstract

The invention relates to the production of cement by the dry method and can be used in the metallurgical and other industries of the industry, where the problem of purifying waste gases containing high resistive dust is solved. The aim of the invention is to increase efficiency and reliability in operation. The moistening column of exhaust gases from rotary kilns of the dry cement production method includes a cylindrical part 1 equipped with several nozzles for spraying water 2, an expanded chamber 3 with a ratio of diameters 1.8-2: 1 and a ratio of the length of the expanded chamber to the length of the cylindrical part of the column 0, 8-1.0: 1. Exhaust gases enter the column through gas turbine 6, pick up droplets of sprayed water and carry it into the expanded chamber 3. Large droplets fall out of the stream downwards, where they evaporate, decrease in size and then again into the chamber 3, and then into gas duct 5. 1 ill., 2 tab. Ё About yu vj Yu

Description

The invention relates to the production of dry cement, namely, devices for the preparation of exhaust gases of rotary kilns of the dry method of cement production for cleaning in electrostatic precipitators, and can be used, for example, in the metallurgical industry and other areas where the problem of cleaning exhaust gases is solved. containing high resistance dust.

The purpose of the invention is to increase the efficiency and reliability of work.

The drawing shows a humidification column for exhaust gases.

The column consists of a cylindrical part 1, which is equipped with several nozzles 2 for spraying water, an expanded chamber 3 made of a cylindrical shell with truncated cones adjacent to it with a ratio of 1.8-2: 1 diameters and the ratio of the length of the expanded chamber to the length of the cylindrical part columns 0.8-1.0: 1, junction 4, adjoining, evaporative duct 5 and inlet duct 6

The column works as follows. Exhaust gases enter the lower part of the cylindrical part of the column through duct 6 and move along it at a speed of 20-22 m / s, pick up drops of water sprayed by nozzles 2 and carry it into the expanded chamber 3, where their speed drops to 5 m / s. Large droplets fall out of the stream downward, where they evaporate, decrease in size, and are again transferred to chamber 3, and then to flue 5.

In tab. Figure 1 shows the data for increasing the residence time in the dust-gas flow column in a column depending on the combination of design parameters of the column.

From tab. 1, it can be seen that different ratios of the diameters of the expanded chamber and the cylindrical part of the column correspond to certain length ratios.

So, to ensure an increase in the residence time of the dust-gas flow (water droplets) by 2.5-3.0 times, columns with the following ratios of parameters of the expanded chamber allow: with a ratio of diameters of 1.7: 1, the ratio of lengths is 1.0-1.1: 1; when the ratio of diameters is 1.8: 1, the ratio of lengths is 0.8-1.1: 1: when the ratio of diameters is 2: 1, the ratio of lengths is 0.7-1.0: 1; when the ratio of diameters is 2.1: 1, the ratio of lengths is 0.7-0.8: 1.

With a ratio of diameters of 1.7: 1, the ratio of lengths of 0.7: 1 and 0.8: 1 is out of limit, i.e., they do not provide an increase in the residence time 2.5 times. When the ratio of diameters is less than 1.7: 1, all the ratios of the camera parameters do not provide the necessary residence time in the apparatus and, accordingly, do not allow the required amount of water to evaporate without the risk of smearing the abutting unit. Similarly, the ratio of lengths of 0.7: 1 will be beyond the limit, with a ratio of diameters of 1.8: 1.

When the ratio of diameters is more than 2.1: 1, also when the ratio of diameters

0 2: 1 and 2.1: 1 and ratios of length more than 1: 1 and 0.9-1.1: 1, respectively, when the residence time of the drops increased by more than 3 times, reducing the speed of the dust-gas stream below 5 m / with leads to falling out of

5 gas flow coarse fraction of wet dust and sticking it to the walls of the cone. These all values are also beyond the limits. The choice of the ratio of lengths is limited on the underside (0.7) by the conditions for providing

0 the required residence time of the droplets in the apparatus and sufficient angles of inclination of the conical part of the chamber, and from the top (1,1) - design considerations (for example, the need to locate 3 pins of nozzles on the cylindrical part of small diameter; the need not to exceed the overall height of structures and .P ).

The performance of the proposed design of the humidification column is considered in comparison with the known one.

In tab. 2 shows the operating parameters of the prototype and the proposed column when the ratio of the diameters of the expanded chamber and the cylindrical part 2: 1 and

5 ratio of lengths 1: 1.

As can be seen from the above data, the residence time of the gas (droplets) in the known column is 2 s, and in the proposed one it is 6 s. This allows for evaporation in the proposed

0 column required 20-22 tons of water per hour before the dust and gas flow comes into contact with the column adjoining unit with the pre-evaporative gas duct. In the well-known column (according to commissioning data) to evaporate more

5 8–10 tons is unsuccessful, and the 60-meter pre-flue gas duct does not fulfill its function due to glossing over the junction assembly. In the proposed column, there is no need for an evaporative gas duct, and gas flow 5 is only needed to supply gases to the electrostatic precipitator.

When using the proposed column, it is possible to provide the following parameters of gases entering into

5 electrostatic precipitator: t 130-150 ° С with a moisture content of 140-160 g / kg from dry gas, which predetermines the effective operation of the filter with a purification coefficient above 0.99.

When using the prototype, due to its lack of efficiency and reliability, the coefficient for cleaning gas from dust in an electrostatic precipitator above 0.97 cannot be obtained.

Thus, due to the installation in the upper part of the column of the expanded chamber, the diameter and length of which relate to the diameter and length of the cylindrical part of the column as 1.8-2.0: 1 and 0.8-1.0: 1, respectively, the residence time is increased. water droplets in the apparatus by 2.5-3 times, which virtually eliminates the smearing of the node adjoining the evaporative gas duct of the column and allows to increase the efficiency of the column operation by increasing the intensity of heat exchange and increasing the amount of evaporated water by 2 times. At the same time, there is no need to construct a secondary evaporator.

Such a design allows optimization of gas flow parameters (temperature and humidity) before entering the electrostatic precipitator, which will significantly increase the cleaning efficiency.

Claims (1)

Claims of the humidification column of exhaust gases of rotary kilns of the dry cement production method, comprising a gas duct for a lower gas supply, a system for supplying and spraying water installed in the cylindrical part of the column, in order to improve reliability and efficiency The column in the upper part is provided with an expanded chamber, the diameter and length of which relate to the diameter and length of the cylindrical part of the column as 1.8-2.0: 1 and 0.8-1.0: 1, respectively. table 2 Options Height (length) of the column, m Diameter, m Diameter of the lower cylindrical part, m The length of the lower cylindrical part, m Diameter of the expanded chamber, m Length of the evaporative duct, m The amount of gases entering the column, m3 / h The temperature of the gases in front of the column, ° C The residence time of gases in the column. C Temperature of gases before the filter, ° C Moisture content before the filter, g / kg Gas dust removal coefficient in an electrostatic precipitator Prototype Proposed column 40 2.9 60 75200 320 2 60-180 10-130 0.97 40 2.9 20 5.8 Structurally adopted for supplying gases to filters (5-15) 475200 320 6 130-150 140-160 0.99