SU1304003A1 - Device for controlling temperature of multizone broaching installations - Google Patents

Abstract

This invention relates to an automatic adjustment technique. The aim of the invention is to improve productivity and improve product quality. This goal is achieved due to the fact that when an uncompensated (due to technological limitations) temperature variation occurs in one of the zones, the material is further heated in subsequent (along the material) zones and at the same time a corresponding increase in the temperature stabilization setting in one of the previous zones. The reduction of the speed of passage of the processed material to compensate for its underheating is carried out only when a certain number of zones (specified in the majority element) of the number of zones is reached at the technological limitations. 1 sludge. e cl so about 4 Oh about so

Description

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1304003

The invention relates to automating the thermal conditions of stretching furnaces and can be used in the metallurgical and engineering industries, for example, for continuous annealing and hot-dip galvanizing units.

The aim of the invention is to increase the productivity of the unit and improve product quality.

The drawing is a structural diagram of the proposed device.

A device for controlling the temperature of multi-zone drawers contains a continuous furnace 1, divided into a zone 2, through which the processed material 3 is passed. Material 3 is supplied by an electric actuator 4, the speed of which is regulated by the speed controller 5 and set from the setting unit 6. Temperature in each zone measured by sensor 7 and maintained by adjusting the fuel flow or

This is due to the need to transfer an unrealizable parameter deviation. .

The speed correction of the electric drive 4 is carried out with the help of the third adder 20, the majority element 21, the OR logic element 22 and the second switch 23.

The device works as follows at the same time.

During normal operation of the zone, the temperature stabilization in it is ensured by the operation of the circuit consisting of sensor 7, for the temperature 12,

15 of the first adder 11, the temperature controller 9, the first switch 10 (in the on position, there is no signal at the output of the detector 13) and the actuator 8.

20 For example, for the second zone, with

when the technological limitation signal arrives from the alarm device 13, the first switch 0 is opened (at the output of the alarm device 13, a single

electricity using performer- 25 signal). In this case, the executive mecha nism of the mechanism 8. The control circuit of the arm 8 will be fixed in its

each zone contains a temperature controller 9, the output of which is connected to the first input of the first switch 10, the output of the switch 10 is connected to the input of the actuator 8, the first adder 11, the first and second inputs of which receive information respectively from the setting unit 12 and the temperature sensor 7, and the output of the first adder 11 is connected to the input of the regulator 9. To form a limiting signal by technological or design parameters (power

nozzles, the limiting temperature of the nag Q second zone required significant and others) serves as a signaling device 13 with an output signal in the form of a logical unit. To ensure transfer to the neighboring zones of the arising and uncompensated temperature deviation from the task when this zone leaves the technological limits, there is a set of elements including the second adder 14, the first and second switches 15 and 16, the AND 17 gates. In the control circuit of the first zone, the signal transfer of the uncompensated rejection of the parameter from the second zone is implemented using the first switch 15, the second switch 19 and the logical elements 17 AND 18 and NOT. The control circuit of the last nth zone does not contain additional elements.

to increase the heating power. The overheating of the material in the second zone should be compensated in the subsequent (along the material course) zone. For this purpose, the unbalance signal from the output of the first adder 11 through the first input of the first switch 15 will go through its first output to the third input of the first adder 11 of the third zone. JQ Turning on the first switch 15 of the second zone to the first position will be due to the presence of a signal at its second (control) input associated with the output of element 17 And of this zone, both of which at the specified time were under the potential of the first: because that in this zone the alarm has triggered 13 restrictions and at its output 55

This is due to the need to transfer an unrealizable parameter deviation. .

The speed correction of the electric drive 4 is carried out with the help of the third adder 20, the majority element 21, the OR logic element 22 and the second switch 23.

The device works as follows.

During normal operation of the zone, the temperature stabilization in it is ensured by the operation of the circuit consisting of sensor 7, for the temperature 12,

the first adder 11, the temperature controller 9, the first switch 10 (in the on position, there is no signal at the output of the alarm device 13) and the actuator 8.

For example, for the second zone, with

when the technological limitation signal arrives from the alarm device 13, the first switch 0 is opened (at the output of the alarm device 13, a single

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current position. Since in the second zone the automatic control loop turned out to be off, the deviation signal will increase at the output of the first adder 11 of this zone, and with a high probability this deviation will occur in the direction of decreasing from the reference. This is due to the fact that the limitation (for example, on the temperature of the radiant tubes in a continuous furnace) was due to the fact that in the previous zones the material turned out to be underheated and in data5

to increase the heating power. The overheating of the material in the second zone should be compensated in the subsequent (along the material course) zone. To this end, the signal unbalance from the output of the adder 11 through the first input of the first switch 15 will go through its first output to the third input of the first adder 11 of the third zone. Q Turning on the first switch 15 of the second zone to the first position will be due to the presence of a signal at its second (control) input associated with the output of element 17 And of this zone, both of which at the specified time were under the potential of the unit: the first because that in this zone the alarm has triggered 13 restrictions and at its output by 5

a logical unit occurred, and the second because it is connected to the output of element 18 of the NOT second zone, which is connected by its input to the alarm indicator 13 of the restrictions of the third zone (it is assumed that the third zone is not in the restriction mode). If at the time in question it turned out that the restriction alarm 13 also worked in the third zone, the switch 15 of the second zone will remain normally turned on (with zero control at the second input) in the second position, at which the output signal of the second zone adder 11 goes to one of the inputs the third adder 20. The underheating of the material in the second zone will not be compensated directly in the third zone, but this deviation will be gradually worked out in the subsequent zones (due to the effect and) if a greater number of them have not come to restrict. If a certain (for - 25 temperatures in this zone. In the case

given by the majority element 21) the number of zones imposed on the restriction, then the compensation of the material tempera- ture tolerance in the zones will be compensated for by reducing the drawing speed. At the same time, a single signal that emerges at the output of the majority element 21 will pass through the first input of element 22 OR to the first (control) input of the second switch 23, ensuring that it is turned on. Then the total signal temperature deviations in the zones from the output of the third adder 20 will go through the second

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blocking the second zone (output for limitations on technological parameters) by the output signal of the detector 13 of this zone, the switch 16 will be transferred to the second position, in which the uncompensated signal of the third zone reject will be sent to the second input of the second zone 14, the output of which through the first the input of the second switch of the first zone passes to its second output, and consequently, to the third input of the first adder 11 of the first zone and executes the input of the second switch 23 to the second d of the control y-, the scheme of this zone. Tawhted is set to controller 5, providing a proportional decrease in the speed of flow.

The number of zones at which the limiting element triggers the major element depends on the requirements for the quality characteristics of the material being processed and is set within 30-70% of the total number of zones. Due to the fact that the failure to preheat the material in the last zone can only be eliminated by: reducing the speed, the output signal of the detector 13 of the restrictions of this zone can be independently BTO-J jpoMy to the input of element 22 OR turn on the draw speed correction circuit. In this way, the consequences of an exit of a zone are eliminated in a limited way, when an uncompensated temperature deviation occurs due to technological limitations, the material is further heated in the next subsequent zone and at the same time a corresponding increase in the temperature stabilization task in one of the previous zones.

The proposed set of blocks and links between them allows an increase in the productivity of the unit and an improvement in product quality.

The invention can be used in all cases when a certain controlled process steam is controlled in a multi-zone drawdown installation.

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the But at the same time, it is also necessary to eliminate the cause at the same time, i.e. accordingly increase the temperature in the previous zone. In all zones except the first, this is done as follows. If, for example, a third zone has entered the restriction, then the output of the adder -11 gradually accumulates a deviation signal also to the first input of the second adder 14 of the same name, from the output of which passes to the first (inverse) input of the second switch 16 of the second zone. If the second zone is not in limiting mode (a single signal at the second (control) input of the switch 16 of the second zone is missing), then the first (normally switched on) switch output -16 of the second zone will not receive the compensated signal of the third zone deviation the input of the first adder 11 of the second zone, ensuring a corresponding increase in the level of

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blocking the second zone (output for limitations on technological parameters) by the output signal of the detector 13 of this zone, the switch 16 will be transferred to the second position, in which the uncompensated signal of the third zone reject will be sent to the second input of the second zone 14, the output of which through the first the input of the second switch of the first zone passes to its second output, and consequently, to the third input of the first adder 11 of the first zone and is processed by the control- circuit of this zone. Thus, when an uncompensated temperature deviation occurs due to technological limitations, the material is further heated in the next adjacent zone and at the same time a corresponding increase in the temperature stabilization task in one of the previous zones.

The proposed set of blocks and links between them allows an increase in the productivity of the unit and an improvement in product quality.

The invention can be used in all cases when a certain controlled process variable is controlled in a multizone stretcher installation.

If there are restrictions on other technological parameters.

Claims (1)

Invention Formula A device for controlling the temperature of multi-zone draw installations, containing a multi-zone bypass furnace, each zone of which is equipped with a fuel raising actuator and an electrically operated draw with regulator and speed adjuster, the output of which is connected to the first input of the speed regulator, about l Further, in order to increase the productivity of the unit and improve product quality, it additionally contains, for each zone, a sensor and temperature setter, the first adder, temperature controller, the first a switch and an indicator of limitations of technological parameters, for all zones except the last, the AND element, the element NOT and the first and second switches, for all zones except the first and last, the second adder, and the majority element common to all zones, the element OR, the third adder and the second switch, and for each zone the output of the setpoint and temperature sensor are connected respectively to the first and second inputs of the first adder, the output of which is connected to the input of the temperature regulator, the output of the temperature regulator for the first input of the first switch, the second input of which is connected to the output of the limiter of technological parameters, and the output is connected to the executor of the fuel supply, for all zones except the last, | the output of the limiter of technological parameters is connected to the first input of the element I, the second input which is connected to the output of the element NOT, the input of the element NOT of this zone is connected to the output of the signaling device of the technological parameters of the subsequent zone, the output of the first adder and the output element And are respectively connected to first and second inputs of the first switch, per- .vy each output of the first switch JO  , 25 the zone, except the last, is connected to the third input of the first adder of the subsequent zone, the second output of the first switch of each zone, except the last one, starting from the first zone, is connected to the corresponding input of the third adder, for all zones except the first and last, the output of the first adder connected to the first input of the second adder, the output of the first adder of the last zone is connected to the corresponding input of the third adder, the first and second outputs of the second switch of all zones, except the first 5 and last, are connected respectively to tvert th input of the first adder and a second input of the second adder, the first input of the second switch of each zone, except for the penultimate 20 and the latter is connected to the output of the second adder of the next zone; for the penultimate zone, the first input of the second switch is connected to the output of the first adder of the last zone, the second input of the second switch of each zone, except the last one, is connected to the output of the process parameterization limit indicator, the first L1 second outputs the second switch of the first zone is connected respectively to the input of the third, common to all zones, the adder and to the third input of the first adder of this zone, the outputs of the detectors are limited The technological parameters of each zone, starting with the first signaling device, are connected respectively to the inputs of the majority element, the output of which is connected to the first input of the ISh1 element, the second input of which is connected to the signaling device of the limitations of the technological parameters of the last zone, the output of the RSHI element and the output of the third adder are connected respectively to the first and the second inputs of the second switch, the output of which is connected to the second input of the speed controller, the first output of the second switch of the first zone is connected to the third im input of the first adder of the same zone, and the second output of the second switch of the first zone is connected to a first input of the third adder. thirty 35 40 45 50