SU662790A1 - Method of automatic regulation of bar refrigerator heat conditions - Google Patents

Description

I

The invention relates to the production of building and other materials in rotary kilns with grate coolers, for example, in the cement industry.

A known method for automatically controlling the cooling process of clinker in a grate cooler, for example, in the production of cement clinker 1.

The disadvantage of this method is to control the change in the number of moves of the grate without taking into account the structural and technological constraints typical of the grate coolers, which leads to low efficiency or inoperability.

Another method is known for automatically controlling the depot mode of a grate cooler operating in conjunction with a rotary kiln, including measuring the temperature and the number of strokes of the grate, the total air flow, determining the ratio of pressure on the grate to the total air flow, changing the number of grate moves and the position of the guide apparatus total air and pressure control over the grille by changing the position of the asher air bristle 2.

This method is closer to the proposed invention. It includes stabilizing the pressure above the grille by changing the size of the aspiration air baler, stabilizing the grate temperature by changing the position of the common air guide vanes and stabilizing the differential pressure ratio on the grille and the total air flow rate by changing the number of grid strokes.

However, this method has a number of disadvantages. One of the main purposes of the grate coolers is to maximize heat removal and to achieve this goal it is reasonable to minimize the number of grate moves. The known method of stabilizing the temperature of the grate by changing the position of the common air guides, carried out in conjunction with the change in the number of strokes of the grate, does not maximize the heat return to the furnace. For example, if a rotary kiln enters the lattice of a refrigerator

KTYTNGKER Sa. The lattice temperature is age; t due to

increase the heat transfer surface. At the same time, due to the small size of the granules, the cooling rate of the clinker is increased. In this case, the maximum heat removal can be achieved with less air flow and, due to an increase in the temperature of the lattice, an increase in

air supply, which in turn leads to a decrease in the temperature of the air supplied to the furnace, i.e., to a decrease in heat consumption, o varush, which is fed to the furnace. Another disadvantage of controlling by a known method is an arbitrary (uncontrollable) change.

 clinker temperature at the outlet of the refrigerator. This leads to the appearance of hot clinker at the exit of the refrigerator and to: as a consequence, a decrease in the efficiency of the refrigerator, additional wear of the clinker conveyors and violation of the technology of storing and grinding the clinker:

In addition, the lack of control by a known method is a decrease in the efficiency of the refrigerator due to the fact that the method does not provide protection against overloading of the grate drive mechanism of the refrigerator. For example, as the coarseness of the clinker coming out of the kiln increases, the resistance of the material to the fiery grate of the refrigerator by pushing it with grates increases. When this happens, the load current of the drive motors of the grid increases. At the same time, the air pressure under the grille decreases and, following by the TV, the ratio of the pressure drop across the grille to the total air flow is reduced.

Characteristic aerodynamic drag layer. According to a known control method, in this case, the number of lattice strokes will decrease, which in turn will lead to an increase in the layer thickness and a further increase in the load current of the lattice drive motor. This increase in current can occur up to the stopping of the grid or the emergency disconnection of the drive motor of the grid due to overload. The purpose of the invention is to increase the efficiency of the grate cooler.

This is achieved by the fact that in the method of

t№a1 iChESK6go regulation of the thermal mode of the grate cooler, works 1Yush: his together with a vrashuy furnace,

including measurement of temperature and lattice travel, air flow rate, 50

CREDENT PRESSURE ON GRID

to the consumption of general air, change in the number

grate moves and position

Direction of the general air devices

 and pressure control over the grate by changing the position of the gate of the aspiration ss

 T0 Vbz Dukha7Yabt10 accurately measure the current on the motor grille and the temperature

; ch1Uyvr nykhfo cooler, determine the difference between the lattice temperature, the load current of the lattice engine and the ratio of pressure on the lattice to the total air flow and the corresponding permissible values, determine the required change in the number of lattice strokes for each of the differences obtained and choose from the obtained values the greatest, and the change in the number of moves of the grate is made by the chosen value, and the change in the position of the guide vanes ha is carried out until the clinker cooler outlet temperature of a predetermined value.

One of the sources for increasing the efficiency of the refrigerator in controlling the proposed method is controlling the position of the common air guide devices depending on the clinker temperature at the refrigerator outlet or on the correlated values: the temperature of the aspiration air, or the lattice temperature in the cold part of the refrigerator. At the same time, due to the stabilization of the temperature of the clinker at the exit of the refrigerator, the working conditions of the process equipment are improved and the heat loss from the refrigerator is reduced.

Another source of increase in the efficiency of control of the refrigerator according to the proposed method is the implementation of its operation with the minimum allowable number of strokes. With a decrease in the number of grid strokes (p), the heat return to the furnace with air from the refrigerator increases. The decrease in the number of lattice strokes is limited by the fact that the lattice temperature (t) increases, the load current of the lattice drive motors (J), as well as the resistance of the layer, an indirect characteristic of which can be the pressure ratio under the lattice, slightly different from the pressure difference on the lattice, to the total air flow rate (- | -). For each refrigerator, there are Allowable values of these veins, 1 times, above which there is a burnout of the grates, respectively, - the output of the grate drive motors and unacceptable changes in heat transfer and air flow direction on the grate. depending on the progress of the cooling process and on the state of the refrigerator equipment, any of the indicated values can reach their limiting values. To clarify the essence of the method, Fig. 1 shows the range of permissible operation modes of the refrigerator when the values T and 0 are defined. Referring to the coordinate axes in Fig. 1 the values of T and 3 are indicated with the indicated values of their allowable values (T 3). Direct wash 3 limit area. Their dispensations are found experimentally for a particular refrigerator. Line AB in fig. Figure 1 shows the relationship between a change in T and 11 with a change in n, with the arrow indicating the direction of increase in the number of lattice moves. The reduction of n in this case is limited to the limiting output of 3. When uncontrollable parameters change, for example, the temperature of the clinker at the entrance to the refrigerator, the size of the granules, etc., the position of the AB line will change and may take, for example, the position AB. In the latter case, a decrease in n leads to an exit to the limitation by T. To find the minimum number of lattice strokes, ensuring maximum heat return to the furnace, and to prevent T or J from exiting the range of acceptable values, in accordance with the proposed method, T and 3, their distance is determined from the corresponding WIRED boundaries 3, T®. The distance from the boundaries allows one to determine the required change in the number of lattice strokes using the experimental static dependencies to reach the corresponding limit.

Dn (T) f, (7-T) An (a) fz (J-3)

The approximate appearance of them is shown in Fig. 2. The dependence is also shown there:

n () f, t: | - (| -)

Near the normal operation of the refrigerator, these dependences can be considered as linear, and their angle of inclination does not change much. If for the considered case An (3) Dn (T), then the number of moves is equal to n + Dn (3).

With Dn (3) O, this corresponds to the safest step of decreasing n, and with Dn (3) 0, this corresponds to the maximum step, which ensures that all variables return to the range of acceptable values. Of the two values of D p, the choice of the largest one ensures the stabilization of one of the variables at the limit of the range of permissible values, provided that the other is not out of this range. Similar reasoning, on finding the minimum allowable n can be made in

the case of three values T, 3, (- | -), limiting the range of variation of the number of lattice moves. The method is carried out as follows.

The pressure above the cooler grate is stabilized by changing the position of the aspiration air. Let the number of strokes of the grid be determined at the given moment by the load current of the grate motor, the value of which is on the boundary O

 () In this case, Dp (i) O, and Dp (T) O and An (| -) 0. Suppose that a clinker with a higher temperature began to come from the furnace, but with the same

consumption and particle size distribution. This does not change the load current of the motor grid J and the ratio of the pressure under the grid to the total air flow, and the temperature T will increase.

The 3-JTT differences are determined and

 - () by experimental static dependencies, the form of which is shown in Fig. 2, determine

Dp (3), Dp (t), Dp ()

If T has become more than T, then Dn (T) 0, and

0 An (0) 0 and Dn () 0. In this case, according to the method, we choose from A n the greatest, which is now Dn (T).

The current value of the number of lattice moves and n per Dp (T) changes and is maintained

5 value obtained. The value is now on the boundary of T, and Cf J

  () If in the future there was an increase in the consumption of clinker in the refrigerator, then increase 7, 3 and. According

0 with the proposed methods determine T-T, 7-3 - (). for which also, as mentioned above, An (T), Dn (3), An (-1 :) are found. Suppose that it turned out An () An (T), Dn (a) 0. Then An (J-) 5 is the greatest. The current value of the number of moves is changed by the value Dp (-) and the resulting value is maintained. At the same time, an increase in the number of lattice moves will result in -5- being equal to (- | :), and 3 3,

0 In this way, when controlling for the proposed method, a change in the number of lattice moves is provided, that at least one of the values of T, 3 ,. is on the border of the range of acceptable values

5 that provides maximum heat recovery with air into the oven.

The control of the number of lattice strokes, as well as disturbances arising during the cooling process, lead to a change in the temperature of the clinker at the outlet of the refrigerator. The clinker temperature at the outlet of the refrigerator is stabilized by changing the position of the common air guides so that the change in the air supply to the refrigerator is proportional to the change in the temperature of the clinker at the output of the heater. Thus, the control ensures the greatest return to the furnace at each moment of time when structural and technological constraints, i.e., the efficiency of the refrigerator is improved.

Claims (2)

1. USSR author's certificate number 259093, cl. F 27 D 19/70, 1971. 2. USSR author's certificate number 193336, cl. F 27 D 19/00, 1959. Rig- yp m yp yt