DE2609799B1 - Regenerative wind heaters for blast furnaces - where hot and cold air is automatically mixed to obtain accurate blast temp. - Google Patents

Abstract

A group of regenerative blast furnace wind heaters are operated alternately during specific times in which heating occurs followed by blowing, the amt. of wind held constant and its temp. adjusted by mixing hot and cold air according to a desired value (1); more cool air is then added to reach a second desired temp. (2) at which the blast is fed into the furnace. During the short time redn. of temp. (2), temp. (1) is raised and then a cold air blast is added to obtain the desired temp. (2). This process permits the blast temp. to be lowered for short times without impairing the operational safety of the plant). Very accurate control of the amt. and temp. of the blast is obtd.

Description

According to the invention, this object is achieved in that, in the case of short-term Lowering the second setpoint of the hot blast temperature, the first, higher setpoint is raised so that the hot blast temperature control dependent on the second setpoint by adding cold wind to the hot wind, the one that depends on the first, higher setpoint Hot blast temperature control by mixing colder and

superimposed on a warmer hot wind In this way it is possible to whose temperature is pre-regulated to the first, higher setpoint, within a short period of time to the required lower hot blast temperature in the ring main of the blast furnace, because the system is now responsible for the hot wind can supply required larger regulated amount of cold wind.

Here, the flow rate through the heater is automatic The following is an embodiment of the invention with reference explained in more detail on the drawing. It shows: F i g. 1 a simplified rule plan for a blast furnace system with four blast heaters, F i g. 2 a nomogram for a such a system, showing the temperature profile in the "on wind" position for the individual wind heater as well as the respective position of the cold wind throttle valve.

In FIG. list with 1 denotes a blast furnace, which is powered by a blast furnace 2a, 2b, 2c and 2d is supplied with hot air. The wind heaters 2a to 2d are through a cold wind line 3 and feed lines 4a, 4b, 4c and 4d fed with cold wind In A flow regulator 5 is arranged in line 3, which regulates the flow of cold wind keeps constant. The hot wind generated in the heater 2a to 2d can be discharged 6a, 6b, 6c or f in a hot blast line 7 flow. The hot wind can have a Cold wind admixing line 8 branched off from line 3 is admixed with cold wind. The hot blast generated after mixing is passed through another hot blast pipe 9 into the ring line of the blast furnace.

The control device has a temperature controller 10 for pre-control the hot blast temperature at the outlet of the hot blast line 7 and a temperature controller 11 for fine-tuning the hot blast temperature at the outlet of the hot blast line 9.

A control flap 12 or through the cold wind throttle valves 13a arranged in the branches 4a, 4b, 4c and 4d, 13b, 13c and 13d, the wind flow through the individual wind heater 2a to 2d throttled or

be locked.

Further control flaps 14 and 15 are also in the cold wind mixing line 8 or arranged in a bypass line 16. With the help of these flaps the dem The amount of cold blast supplied to the hot breeze can be dosed large or fine.

The cold wind throttle valves 13a to 13d are controlled by the temperature controller 10 controlled by a relay station 17 The control of the regulating flaps 12, 14 and 15, on the other hand, is carried out by the temperature controller 11 via split-range devices 20, 21 and 22nd

The temperature controller 10 works with a first target value T, the Hot blast temperature that is slightly higher than the setpoint T2 for the temperature controller 11 is chosen. This second setpoint value T2 is corresponding to the required temperature of the hot blast in the ring line of the blast furnace The mode of operation of the Plant in the offset process is described below with reference to the F i g. 1 and 2: In the upper field of FIG. 2 show the simplified Curves Tci, Etc2, Tc3 and Tc4 show the time course of the hot wind temperature individual wind heaters 2a to 2d. With tb and th are the blowing and heating times for the wind heater 2a denotes the intermediate one Switching time can be easier Understanding can be neglected and is therefore not registered. The blow and Heating times are the same and constant for all wind heaters.

In the lower field of FIG. 2 show the curves Kcl, KC2. Kc3 and Kc4 the degree of opening of the individual cold wind throttle valves 13a to 13d over time.

As shown in FIG. 2 can be seen, the wind heaters 2a to Switched to heating or to blowing at two-time staggered intervals. The hot breeze temperature is initially pre-regulated to the first setpoint T with the aid of the temperature controller 10. The temperature controller 10 generates a control signal as a function of the difference between the setpoint Tt and the actual value of the hot blast temperature measured at the measuring point 18. The control signal is sent via the relay station 17 to the actuators of the corresponding Cold wind throttle flaps 13a to 13d supplied, with only one of these flaps is achieved by the control signal. At the end of the blowing period it has closing Tendency to open at the beginning of the blowing period. The ones from the cold wind throttles 13a to 13d assumed position in turn has the effect that in the line 7 the different warm hot wind currents from the heater, which is switched to bubbles, as a function of are mixed by the control signal of the temperature controller 10.

The hot blast temperature, which is pre-regulated to the setpoint T, is then with the help of the temperature controller 11 to the second, somewhat lower setpoint T2 fine-tuned according to the required hot wind ring line temperature The temperature controller 11 generates a control signal depending on the difference between the Setpoint T2 and the actual value of the hot blast temperature measured at measuring point 19. This control signal is divided into three equal parts via the split-range devices 20, 21 and 22 Signals split up and fed to the actuators of the control flaps 15, 14 and 15.

Normally, the control flap 12 is open, while the control flap 14 is closed and the control flap 15 is in control mode, the controller output is so small that only the split-range device 20 is activated. The fine control of the hot blast temperature then takes place in such a way that the hot blast flowing through the hot blast line 7 Smaller amounts of cold wind via the cold wind mixing line 8 and the bypass line 16 mixed in as a function of the flap position of the finely throttling control flap 15 will. In the case of larger differences between the target value T2 and that at the measuring point 19 measured actual value then becomes the coarse throttling via the split-range device 21 Control flap 14 switched on and the control flap 15 withdrawn in the closing direction, while the throttle valve 12 remains open. In this way, the hot breeze can get bigger Amounts of cold wind are supplied. In the event of an even greater control deviation on the temperature controller If the control flap 12 is adjusted in the closing direction via the split-range device 22, so that even larger amounts of cold blast of the mixing point 23 between the hot blast lines 7 and 9 can flow in.

On the left side of the top box are the bubbler 2a and 2b shifted into operation in parallel. The required regulated hot wind ring line temperature T2 is 1300 "C, the setpoint T1 of the pre-regulated hot blast temperature 13500 C.

At A, the blast furnace operation suddenly requests one deeper Hot wind temperature at the ring main. This is when the hottest stove is 2b fully upwind, the cold wind throttle valve 13b assigned to it is fully open. The cold wind heater 2a is also still fully exposed to the wind. If one were to use the setpoint T, leave the pre-regulated hot blast temperature unchanged or even roughly analogous to lower the lower setpoint T2, the cold wind throttle valve 13a would be on Wind heater 2a close more slowly in order to correspond to the overall lower heat demand When the cold throttle valve 13b is fully open, the control circuit of the temperature controller 10 maintain. This lower heat demand arises from the fact that as a result the required lower hot wind ring line temperature, the cold wind additive the control circuit of the temperature controller 11 is enlarged.

At the end of the blowing time of the heater 2a is its cold wind throttle valve 13a not yet completely closed. The coil heaters 2a and 2b are comparative because of the lower depletion at a higher temperature level. So lies For example, now the temperature (point B) of the heater that is fully open to the wind 2b higher than the setpoint T, in the control circuit of the temperature controller 10, d. H. this The control circuit can no longer fulfill its function, as the wind heater is at this moment 2c is switched on with the highest wind temperature.

To the functionality of the regulation with increasing depletion of the heater 2b is maintained according to the invention, the target value T, des Temperature controller 10 is not lowered, but on higher level raised that is at least as high as the temperature at point B or slightly higher (point Cim Embodiment).

If this temperature increase is not carried out, only that remains Alternative to give up the advantages of parallel staggered operation and to hot blast temperature control to pass through the control circuit of the temperature controller 11 alone. A regulated one De-storage of the heater would then no longer be possible.

Due to the measure according to the invention, the heat demand can approximately the same value as before lowering the setpoint value T2 and the control circuit of the temperature controller 10 continues to function. The flap positions the cold wind throttle valves have worked well enough again after two blowing periods that a parallel offset operation with the higher setpoint Tt of the pre-regulated Hot blast temperature is possible. The control circuit of the temperature controller has 11 to cover a wider range, d. H. more cold wind must be added to the hot wind will.

The re-adjustment at D to the original temperature level is easily possible, since the heat storage in the heater is the required Performance is equivalent. The adjustment is also completed after two blowing periods.

So can be short term with unchanged storage and fixed Blow times can reach any lower hot draft pipe temperature without that the regulation is messed up.

Claims (1)

Claim: Method for operating a group of regenerative working blast furnace coils that are needed to generate the blast furnace Hot winds are alternately heated and blown cold at fixed time intervals, whereby the amount of hot blast is kept constant and the hot blast temperature is maintained Mixing of colder and warmer hot air depending on a first setpoint and then admixing cold wind as a function of a second target value can be regulated, the second setpoint being the hot blast temperature required in the blast furnace and the first setpoint is selected slightly higher than the second setpoint, characterized in that with short-term lowering of the second setpoint the hot breeze temperature the first, higher setpoint is raised so that the from Second setpoint-dependent hot breeze temperature control by adding cold breeze in the hot blast the hot blast temperature control dependent on the first, higher setpoint superimposed by mixing colder and warmer hot wind. The invention relates to a method for operating a group of regeneratively working blast furnace heaters, which are used to generate the from the blast furnace The required hot breeze is alternately heated and blown cold at fixed time intervals the amount of hot blast and the hot blast temperature being kept constant by mixing colder and warmer hot air depending on a first Setpoint and subsequent admixture of cold wind depending on a second The setpoint is adjustable, the second setpoint being the hot blast temperature required in the blast furnace and the first setpoint is selected to be slightly higher than the second setpoint. The hot wind, d. H. those in the stove at high temperature warmed air is known to be used in the blast furnace to burn the fuel as well for conversion and activation of the reducing agent fed into the blast furnace. the A group of four or more heaters can be made up of three different ones Procedures are operated. When operating the system in the so-called parallel process at the same time two or more heaters on heating and two or more Bubble heater switched to bubbles, the hot blast temperature in the way it is regulated that the hot breeze from each of the hot air heaters switched to bubbles Cold wind depending on the required hot wind temperature in the ring main The blast furnace is mixed in when operating the blast furnace in the so-called series operation are three or more heaters on heating and one or at the same time several heater switched to blowing, whereby the regulation of the hot blast temperature takes place in the same way as with the parallel procedure. When operating the system in the so-called parallel offset process two or more hot air heaters are set to heat and two are staggered or several heater switched to bubbles, the hot blast temperature in two Levels is regulated. In the first stage, the different warm hot wind currents from each of the hot air blowers, depending on one mixed with the first setpoint, which is slightly above the required hot wind ring line temperature lies. The resulting hot wind stream will then be smaller Amounts of cold wind as a function of a second setpoint according to the the required hot wind ring line temperature. In the first stage will so the hot blast temperature is pre-regulated to a temperature level that is slightly above the required hot wind ring line temperature. In the second stage will they are then fine-tuned to their final setpoint. The operation of the system in the parallel process and in series has the disadvantage in principle that for Achieve a certain temperature of the hot blast the heater with a higher Dome temperature than when operating the system in the parallel offset process have to. Both in the parallel process and in the series operation must namely the temperature of the hot wind flowing out of the heater until the end of the Blowing period are above the required setpoint of the regulated hot blast temperature. In the parallel offset process, however, the hot blast temperature of the individual Winder heaters fall below the required setpoint during the blowing time, because the each colder hot blast is mixed with a warmer hot blast at the same time. In the case of deliberate changes to the required There are no problems with the hot blast temperature in the ring line of the blast furnace because you can start the new operation by changing the dome temperature accordingly can gradually adjust in the heater. Short-term increases in the setpoint temperature the hot breeze are also possible, provided that the heater group has been set up beforehand the corresponding higher heat level has been heated up. But it has to reach the desired target temperature of the hot blast at short notice are reduced, then there is a parallel staggered procedure Winderhitzeranlagen the difficulty that in this case by the Kaltwindzumischleitung increased, but reduced wind quantities fed to the wind heaters will. As a result, less heat is extracted from the wind heaters. At the end of the blowing time, the wind temperature of the relieved heater is still so high that the premixing temperature is reached when a fully stored blast furnace is switched on is too high to reach the set target value for the hot blast temperature. The invention is based on the object of a parallel offset To operate the procedure-working wind heater system of the above-mentioned type in such a way that that it is possible to run the blast furnace for a short time with a lower regulated hot blast temperature to drive without affecting the operational safety of the heater system.