DE2609799C2 - Process for operating a group of regeneratively working blast furnace heaters with fixed heating and blowing times and a constant amount of hot blast - Google Patents

Description

The invention relates to a method for operating a group of regeneratively operating blast furnace coil heaters, those for generating the hot blast required by the blast furnace alternately at fixed time intervals be heated and blown cold, the amount of hot blast being kept constant and the Hot blast temperature by mixing colder and warmer hot blast depending on a first Setpoint and subsequent admixture of cold wind can be regulated as a function of a second setpoint is, where the second setpoint corresponds to the hot blast temperature required in the blast furnace and the the first setpoint is selected slightly higher than the second setpoint.

The hot wind, d. H. As is well known, the air heated to a high temperature in the heater becomes the Blast furnace for the combustion of heating fuels and for converting and activating the reducing agents into fed to the blast furnace. The heater group of four or more heater can be used according to three different procedures can be operated.

When operating the system in the so-called parallel process, two or several boiler switched to heating and two or more boiler switched to blowing, whereby the hot blast temperature is regulated in such a way that the hot blast from each of the bubbles Switched hot air heaters cold blast depending on the required hot blast temperature in the Ring line of the blast furnace is admixed.

When operating the blast furnace in the so-called series mode, three or more heater on heating and one or more heater on blowing switched, whereby the regulation the hot blast temperature takes place in the same way as in the parallel process.

When operating the system in what is known as the parallel offset method, the time staggered in each case two or more fan heaters switched to heating and two or more fan heaters switched to blowing, whereby the hot blast temperature is regulated in two stages. In the first stage they become different warm hot wind flows from the heater, which is switched to bubbles, depending on one mixed with the first setpoint, which is slightly above the required hot wind ring line temperature. Smaller amounts of cold wind are then fed into the resulting hot blast

ίο Dependency on a second setpoint accordingly the required hot blast line temperature is mixed in. The first stage is the hot blast temperature Pre-regulated to a temperature level that is slightly above the required hot wind ring line temperature lies. In the second stage, it is then fine-tuned to its final setpoint.

The operation of the system in parallel and in series has the disadvantage that the principle Achieving a certain temperature of the hot wind, the heater with a higher dome temperature than have to work when operating the system in a parallel offset process. Both in parallel as well as in the series operation, namely the temperature of the exhaust gas from the heater The hot breeze is above the required setpoint of the regulated hot blast temperature until the end of the blowing period lie. In the parallel offset process, on the other hand, the hot blast temperature of the individual wind heaters can be adjusted Fall below the required setpoint during the blowing time, as the hot wind is colder in each case at the same time warmer hot blast is added.

In the event of deliberate changes in the required hot blast temperature in the ring main of the blast furnace no difficulties arise, since you can start the new operation by making appropriate changes can gradually adjust the dome temperature in the heater. Short-term increases in the The target temperature of the hot blast is also possible, provided that the heater group has previously set the corresponding higher heat level was heated up.

However, if the desired target temperature of the hot blast has to be reduced for a short time, then there is in the case of wind heater systems operating in parallel, the difficulty that in this Fall through the cold wind mixing line increased, but the wind heaters, but reduced wind volumes are fed. This means that less heat is extracted from the wind heaters. At the end of the blowing time, the wind temperature of the depleted heater is still so high that at Switching on a fully stored boiler the premix temperature is too high to reach the set To achieve the setpoint of the hot blast temperature.

The invention is based on the object of a wind heater system that operates in a parallel offset process of the above type to operate in such a way that it is possible to use the blast furnace for a short time with a to drive a lower regulated hot blast temperature without compromising the operational reliability of the wind heater system to affect.

According to the invention, this object is achieved in that when the second is briefly reduced Setpoint of the hot blast temperature the first, higher setpoint is raised, so that the second Setpoint-dependent hot blast temperature control by mixing cold blast into the hot blast hot blast temperature control dependent on the first, higher setpoint by mixing colder and

superimposed by a warmer hot wind.

In this way it is possible to regulate the hot breeze whose temperature is pre-regulated to the first, higher setpoint is, within a short period of time, to the required lower hot blast temperature in the Bring down the ring line of the blast furnace, because the system is now the hot blast required for it can supply a larger regulated amount of cold wind. This is the flow rate through the heater automatically reduced

The following is an embodiment of the invention explained in more detail with reference to the drawing It shows:

F i g. 1 a simplified rule plan for a Blast furnace system with four blast heaters,

2 shows a nomogram for such a system, showing the temperature profile in the position »on Wind «for the individual wind heaters as well as the respective position of the cold wind throttle valve.

In Fig. 1, 1 denotes a blast furnace which is supplied with hot air by blast heaters 2a, 26, 2c and 2d. The wind heaters 2a to 2d are fed with cold wind through a cold wind line 3 and feed lines 4a, 4b, 4c and Ad. In the line 3 there is a flow regulator 5 which keeps the amount of cold wind flowing through it constant. The hot wind generated in the hot air heaters 2a to 2d can be discharged through ducts 6a, 66, 6cbzw. 6d \ n a hot wind line 7 flow. The hot breeze can be mixed with cold blast via a cold blast mixing line 8 branched off from the dtr line 3. The hot blast stream produced after mixing reaches the ring line of the blast furnace via a further hot blast line 9.

The control device has a temperature controller 10 for pre-regulating the hot blast temperature Output of the hot blast line 7 and a temperature controller 11 for fine-tuning the hot blast temperature on Exit of the hot blast line 9.

The wind flow through the individual wind heaters 2a to 2d can be throttled or shut off by a control flap 12 arranged in the cold wind line 3 or by a cold wind throttle valve 13a, \ 3b, 13c or i3d arranged in the branches 4a, 4b, 4c and 4d.

Further control flaps 14 and 15 are also in the cold wind admixing line 8 or in a bypass line

16 arranged. With the help of these flaps, the amount of cold breeze supplied to the hot breeze can be large or fine be dosed.

The cold wind throttle valves 13a to \ 3d are controlled by the temperature controller 10 via a relay station

17 controlled. The control flaps 12, 14 and 15, on the other hand, are controlled by the temperature controller 11 via split-range devices 20, 21 and 22.

The temperature controller 10 works with a first setpoint value Ti for the hot blast temperature, which is selected to be somewhat higher than the setpoint value Ti for the temperature controller 11. This second setpoint Γ2 is set according to the required temperature of the hot blast in the ring line of the blast furnace.

The mode of operation of the system in the parallel offset Vei will be described below with reference to FIG F i g. 1 and 2:

In the upper field of FIG. 2, the simplified curves 7n, Ta, Ta and Tf _{4 show} the time course of the hot blast temperature of the individual wind heaters 2a to 2dl. Lh and ih denote the blowing and heating times for the wind heater 2a. The switching time in between can be neglected for easier understanding and is therefore not entered. The blowing and heating times are the same for all wind heaters and also constant.

In the lower field of FIG. 2, the curves K show _C i. Kc2, Kc3 and K _c * the degree of opening of the individual cold wind throttle valves 13a to 13i / over time.

As shown in FIG. 2, the blast heaters 2a to 2d are switched to heating or to blowing with a staggered time. The hot blast temperature is first pre-regulated to the first setpoint value Γι 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 T1 and the actual value of the hot blast temperature measured at the measuring point 18. The control signal is fed via the relay station 17 to the actuators of the corresponding cold wind throttle flaps 13a to 13c /, only one of these flaps being reached by the control signal at a time. At the end of the blowing period it has a closing tendency, at the beginning of the blowing period it has an opening tendency. The position assumed by the cold blast throttle flaps 13a to XZd , in turn, causes the different warm blasts of hot blast from the hot blasting heaters to be mixed in line 7 as a function of the control signal of the temperature controller 10.

The hot blast temperature pre-regulated to the target value Ti is then finely regulated with the aid of the temperature controller 11 to the second, somewhat lower target value Ti in accordance with the required hot blast ring line temperature. The temperature controller 11 generates a control signal as a function of the difference between the target value Ti and the actual value of the hot blast temperature measured at the measuring point 19. This control signal is split up into three identical signals via the split-range devices 20, 21 and 22 and fed to the actuators of the control flaps 12, 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 being so small that only the split-range device 20 responds. 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 via the cold blast mixing line 8 and the bypass line 16 is mixed with smaller amounts of cold blast depending on the flap position of the finely throttling control flap 15. In the event of greater differences between the setpoint T2 and the actual value measured at the measuring element 19, the roughly throttling control valve 14 is switched on via the split-range device 21 and the control valve 15 is withdrawn in the closing direction, while the throttle valve 12 remains open. In this way, the hot breeze can be supplied with larger quantities of cold breeze. In the event of an even greater control deviation at the temperature controller, the control flap 12 is adjusted in the closing direction via the split-range device 22, so that even greater amounts of cold blast can flow into the mixing point 23 between the hot blast lines 7 and 9.

On the left-hand side of the upper field, the wine heaters 2a and 2b are in parallel operation. The required regulated hot blast line temperature T) is 1300 ° C, the setpoint Ti of the pre-regulated hot blast temperature is 1350 ⁰ C.

At A , the blast furnace operation suddenly requests one

lower hot blast temperature on the ring main. At this point in time, the hottest wind heater 2b is fully upwind, the cold wind throttle valve 13 £> assigned to it is fully open. Even the cold wind heater la is still hanging on the wind. If the setpoint Ti of the pre-regulated hot blast temperature were to be left unchanged or if it were even reduced roughly analogously to the lower setpoint Ti , the cold blast throttle valve 13a on the wind heater 2a would close more slowly in order to maintain the control circuit of the temperature controller 10 in accordance with the overall lower heat demand when the cold throttle flap 136 is fully open. This lower demand for heat arises from the fact that, as a result of the required lower hot wind ring line temperature, the addition of cold wind is increased via the control circuit of the temperature controller 11.

At the end of the bias time of the heater 2a, its cold wind throttle valve 13a is not yet completely closed. The wind heaters 2a and 2b are comparatively at a higher temperature level because of the lower depletion. For example, the temperature (point B) of the wind heater 2b is now higher than the setpoint 71 in the control circuit of the temperature controller 10, i.e. this control circuit can no longer fulfill its function, since at this moment the wind heater 2c with the highest wind temperature is switched on .

In order to maintain the functionality of the control with increasing depletion of the heater 2b , the setpoint Γι of the temperature controller 10 is not lowered according to the invention, but raised to a higher level that is at least as high as the temperature at point B or slightly higher (point C in the exemplary embodiment) .

If this temperature increase is not carried out, there is only one alternative, the advantages of the parallel to give up staggered operation and for hot blast temperature control solely via the control circuit of the temperature controller 11 to pass. A regulated removal of storage from the heater would then no longer be possible

ίο possible.

Due to the measure according to the invention, the heat demand can be brought to approximately the same value as before the lowering of the setpoint value Ti and the control circuit of the temperature controller 10 continues to function. After two blowing periods, the flap positions of the cold blast throttle flaps have become so well established that parallel operation with the higher setpoint 7Ϊ of the pre-regulated hot blast temperature is possible. The control circuit of the temperature controller 11 has to cover a larger bandwidth, ie more cold breeze must be fed to the hot blast.

Raising the temperature again at D to the original temperature level is easily possible, since the heat storage in the boiler is equivalent to the required output. The adjustment is also completed after two blowing periods.

Any lower one can be used for a short time with unchanged storage and fixed blowing times Reach hot wind ring line temperature without disrupting the control.

For this purpose 2 sheets of drawings

Claims (1)

Claim: Process for operating a group of regenerative blast furnace coil heaters, those for generating the hot blast required by the blast furnace alternately at fixed time intervals be heated and blown cold, the amount of hot blast being kept constant and the Hot blast temperature by mixing colder and warmer hot blast depending on a first target value and subsequent admixture of cold wind as a function of one second setpoint 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 when the second setpoint is reduced for a short period of time, the Hot wind temperature the first, higher Soüwert is raised, so that from the second setpoint dependent hot blast temperature control by adding cold blast to the hot blast from first, higher setpoint dependent hot blast temperature control by mixing colder and superimposed by a warmer hot wind.