RU2499056C2 - Cyclic heating method of hot-blast stoves - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: method involves heating of a hot-blast heater, which is performed in a cyclic mode with high-temperature and low-temperature periods and/or periods with increased and reduced consumption of combustion products. At high-temperature period there set is temperature of combustion products, which is equal to 1.01-1.2. At low-temperature period - 0.8-0.99 of average temperature for a separate heating time interval, and/or reduced and increased consumption of combustion products of 0.99-0.5 and 1.01-1.5 respectively of average consumption of combustion products is set for a separate heating time interval.

EFFECT: higher hot air blasting temperature and efficiency of a hot-blast heater.

6 cl, 5 dwg, 1 ex

Description

The invention relates to the field of high-temperature heating of the blast and can be used in blast furnace heaters.

At present, the process of heating blast-furnace air heaters is carried out at practically constant or slowly varying rates of combustion products and their temperature. The consumption of combustion products is determined by the limiting characteristics of the operation of the burner devices used by the fans, as well as the operating time of the air heaters for heating, and its temperature by the type of refractories used, the calorific value of the fuel used and the type of burner device.

Known are the results of studies of stepwise heating modes of air heaters (Shklyar F.R., Malkin V.M., Kashtanova S.P., Kalugin Y.P., Sovetkin V.L. Domain air heaters: designs, theory, operation modes. - M. : Metallurgy, 1982, 176 pp. With ill., S.158). The experiments were carried out for the heating mode, carried out in two stages with a constant total fuel consumption during the heating period. At the same time, the relative fuel consumption in the first heating stage and the relative time of the first heating stage were changed. As a result, it was found that the optimal mode is with a constant fuel consumption throughout the heating period. This mode, according to the researchers, allows, with better use of the heat of the nozzle, to obtain a relatively higher temperature of hot blast.

However, in the case of a constant or slowly changing flow rate of the combustion products and their temperature during the heating period, the heating process is characterized by the following disadvantages: reduced heat transfer coefficient from the combustion products to the nozzle; uneven distribution of flow velocities over its cross section and, as a result, temperature distortions, reduced efficiency of the air heater and the temperature of the hot blast supplied to the blast furnace, which ultimately leads to cost overruns of expensive coke.

The claimed method of cyclic heating of a blast furnace heater, including heating, which is carried out in a cyclic mode with high-temperature and low-temperature periods, while the temperature of the combustion products is set to 1.01-1.2, and when the low-temperature period is 0.8-0, 99 from the average temperature for a single interval of the heating time and / or establish a lower and increased consumption of combustion products 0.99-0.5 and 1.01-1.5, respectively, from the average consumption of combustion products for a separate interval webbings heating.

This mode is a process of controlled temperature and aerodynamic non-stationarity, which, due to additional turbulization of the gas stream at the boundary of the heat transfer surface, leads to a decrease in the thickness of the boundary layer between the heat carrier flow and the heat transfer surface of the nozzle, which in turn allows increasing the heat transfer coefficient from the combustion products to the nozzle material air heater. This leads to an increase in the efficiency of each heater in the unit and to an increase in the temperature of the hot blast. The controlled unsteadiness of the supply of combustion products supplied to the nozzle also contributes to a more uniform gas distribution and, as a result, an increase in the uniformity of heating of the nozzle, which also leads to an increase in the blast temperature and the durability of the heater.

With a high-temperature period of the cycle, the temperature of the combustion products is set to 1.01-1.2, and with a low-temperature period of 0.8-0.99 of the average temperature for a separate interval of heating time or the maximum operating temperature of the nozzle and the dome of the heater - the temperature of the use of refractories. When the temperature in the high-temperature period of the cycle is less than 1.01 of the temperature of the use of refractories, the heat exchange between the gas stream and the nozzle of the heater decreases and all indicators of the heating process deteriorate. An increase in temperature of more than 1.2 from the temperature of the use of refractories makes it possible to intensify the heat transfer process and increase the temperature of hot blast, however, it causes the risk of melting of the refractories of the dome and the nozzle of the air heater. In this case, the temperature in the low-temperature period of the cycle should be in the range of 0.8-0.99 of the temperature of the use of refractories, since with a decrease in this temperature (less than 0.8) the speed of the heat wave, although it increases, however, its temperature decreases and the process indicators heating deteriorate.

Heating is also carried out in a cyclic mode with periods of lower and higher consumption of combustion products of the cyclic mode. At the same time, reduced and increased consumption of combustion products is set in the ratio of 0.99-0.5 and 1.01-1.5, respectively, from the average consumption of combustion products for a separate heating time interval. Exceeding the average flow rate by more than 1.5 times is impractical, due to the deterioration of the quality of fuel combustion and excessive energy consumption, since the fan supplying combustion air leaves the area of maximum efficiency, as well as with an increase in capital costs for installing more powerful fans and burner devices.

The number of cycles per heating period is set equal to 4-40. The number of cycles less than 4 does not significantly improve the heat engineering parameters of the heating process, which is impractical, and an increase in their number more than 40 can lead to uncontrolled pulsations (self-oscillations) in individual elements of the smoke path of the heater, which can lead to a reduction in the life of its operation.

The amplitude of the temperature and / or consumption of combustion products, depending on the specific production conditions and capabilities, is set either constant (the same) in each cycle, or in each subsequent cycle is reduced by 1.05-1.5 times compared with the previous cycle, which eliminates the possible overheating of refractories at the end of heating, or the amplitude of the temperature of the combustion products in each subsequent cycle is increased by 1.05-1.5 times in comparison with the previous cycle. Moreover, it is advisable to use the option with a constant amplitude of temperature change in each cycle using the simplest automatic control systems. Options with decreasing / increasing amplitudes, or changing according to an arbitrary schedule, as more effective, require more complex and reliable control systems, and the magnitude of the decrease / increase in amplitude in each subsequent cycle is set in the range of 1.05-1.5 times based on the conditions of achievement specified amplitude to the end of the heating period of the heater. Similarly to the amplitude, the frequency of the cycles can vary.

When organizing a cyclic mode with a change in the temperature of the combustion products in order to increase the average temperature during the heating period, the ratio of the duration of the low-temperature and high-temperature periods is set to: 0.2 ÷ 1.0: 1.0. The value of this ratio of less than 0.2 does not introduce the required non-stationarity into the process and the process becomes close in its characteristics to a process with a constant temperature, and more than 1.0 to a decrease in the average temperature.

The required temperature in the low and high temperature periods of the cyclic mode is ensured by burning fuel in each cycle period with a minimum air consumption (excess) coefficient of 1.05-1.15 by controlling caloric content by mixing fuels with different calorific values (for example, blast furnace and natural gas , blast furnace and coke oven gas, water-carbon emulsion and fuel oil, etc.), or if the required temperature of the combustion products is not provided, change the air flow / excess coefficient in the direction of its increase . Such an organization of the fuel combustion process reduces its consumption by approximately 4-5%.

Thus, by cyclically changing the temperature and / or flow rate of the combustion products supplied to the blast furnace, as well as establishing the optimal frequency, shape and amplitude of the cycles, an intensification of the heating process of the blast furnace is achieved. The technical result achieved by the claimed method is to increase the temperature of the hot blast and the efficiency of the heater.

The proposed heating method relates to a separate air heater and does not depend on the number of blast furnace air heaters operating in the unit, on the operation mode of the blast furnace wall unit (serial, pairwise-parallel, mixed, parallel, etc.), type of burner device, heating system used ( with an external or internal combustion chamber, shaftless, etc.) and the nozzle used for heating types of fuel (blast furnace, coke oven, natural, mixed gas, fuel oil, water-coal emulsion, etc., and also mixtures thereof).

Example. The invention is illustrated by figures, in which Figs. 1, 2 respectively show a change in the relative consumption of combustion products and temperature during heating at a constant amplitude, frequency and shape, in Fig. 3 with decreasing amplitude, in Fig. 4 with a changing shape, frequency and the amplitude of the cycles, in Fig.5 is a change in the temperature of the combustion products during heating with decreasing amplitude and average temperature. The dotted line in all the figures shows the average value of the parameter during heating. The proposed method can be implemented as follows. The consumption of combustion products is determined by the consumption of fuel and oxidizer (air). The temperature of the combustion products can be measured or calculated, or the dome temperature can be used to conduct the process, to a certain extent reflecting the temperature of the combustion products. The cyclic mode with a simultaneous increase in temperature and a decrease in flow during some periods of the cycle, with a decrease in temperature and an increase in flow to others is relatively easy to organize by changing the coefficient of flow (excess) of air due to periodic changes in air or fuel consumption. If the temperature of the combustion products must be kept constant, and only cycles in the number of products of combustion are needed, then this is done by simultaneously changing the air and fuel consumption with a constant fuel-air ratio. This can be realized even with manual or remote control. In more complex cases, the task for the consumption of combustion products is set in an automated control system in accordance with the schedule depicted, for example, in Figs. 1, 4. Moreover, depending on the regulation method used, the task is set either to the gas flow rate or to air consumption. The average value of the consumption of combustion products is set similar to the basic mode (without cycles). The gas-to-air ratio maintains the required dome temperature associated with the temperature of the combustion products. The number of cycles for the heating period is set in the range of 4-40, depending on the capabilities of the air heater control system used. The amplitude is in the range of 0.5-1.5 of the average flow rate for the heating period. Similarly to air consumption, the temperature of the combustion products is changed by changing the fuel-air ratio, and when using two types of fuel, for example, “rich” gas (natural or coke oven) and “poor” gas (blast furnace), the ratio is “rich gas-poor”, and the process of burning fuel is carried out with a minimum coefficient of flow (excess) of air 1.05-1.15. At the same time, the maximum temperature is set with a coefficient of 1.0-1.2, for example, in the range up to 150 ° C above the application temperature for this type of refractory material and the minimum temperature is such that the average temperature during the cycle is maintained at a level not exceeding the maximum allowable for this type of refractories. The temperature amplitude in the cycle is in the range of 300 ° C, and the cycle period is 2-15 minutes. When implementing the method, it is also possible to combine cyclical changes in both the flow rate of combustion products (FIG. 1) and their temperature (FIG. 2), as well as various forms of change in amplitude (FIG. 3) and a combination of changes in amplitude, frequency and shape of cycles (FIG. .four). Figure 5 shows a graph of the temperature of the combustion products in the case when its average value decreases during the heating period. Thus, using modern means of control and regulation, it is possible to realize the necessary, in accordance with the proposed method of cyclic heating, independent change in the consumption of combustion products and their temperature.

The simulation results of the operation of blast-furnace air heaters using the known and proposed methods show that due to the introduced controlled temperature and aerodynamic non-stationarity of the technological process of heating, the heat transfer coefficient increases by 3-5%, which leads to a corresponding increase in the efficiency of the heater, as well as an increase in the temperature of hot blasting by 30 -50 ° C.

Claims (6)

1. The method of cyclic heating of a blast furnace heater, including heating, which is carried out in a cyclic mode with high-temperature and low-temperature periods, while the temperature of the combustion products is set to 1.01-1.2 for a high-temperature period, and 0.8-0 for a low-temperature period 99 from the average temperature for a separate interval of the heating time and / or establish a lower and increased consumption of combustion products 0.99-0.5 and 1.01-1.5, respectively, from the average consumption of combustion products for a separate time interval heating. 2. The method according to claim 1, characterized in that during the high-temperature period of the cycle, the temperature of the combustion products is set equal to 1.01-1.2 of the temperature of the use of refractories. 3. The method according to claim 1, characterized in that the number of cycles during the heating period is set equal to 4-40. 4. The method according to claim 1, characterized in that the amplitude of the temperature and / or consumption of combustion products in each subsequent cycle is reduced and / or increased by 1.05-1.5 times compared with the previous cycle. 5. The method according to claim 1, characterized in that the ratio of the duration of the low-temperature and high-temperature periods of the cycle is set in a ratio of 0.2 ÷ 1.0: 1.0. 6. The method according to claim 1, characterized in that the average flow rate and / or temperature of the combustion products during one full cycle is changed during heating.

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