SU1436283A1 - Electrothermal installation with heaters of silicon carbide - Google Patents

Abstract

The invention relates to electrical engineering. The goal is to increase the service life of silicon carbide heaters. The goal is achieved by ensuring the possibility of forming, on the guides of several levels of voltage n temperature, and automatic compensation of the aging of heaters. The installation is equipped for this purpose with a logic block, an AND element, a generator of square impulses, which is superbly controlled by an aperiodic element and a second master unit. With these blocks, a reduced voltage is applied, and when the intermediate value of t is reached, the required max. Voltage is applied. After reaching a given t-ry support it by forming a low voltage at t-re above the specified and the required max. nap} er at t-re below a given one. At the same time, aging of electric heaters from silicon carbide is monitored and the required voltage value is automatically set to compensate for this process. In addition, contactless connection with a chain is provided and adjustment is appropriate. voltage levels. 2 hp f-ly, 6 ill. - s (L 4 00 Od y 00 co

Description

The invention relates to electrothermal and can be applied in electric furnaces with silicon carbide heaters.

The purpose of the invention is to increase the service life of heaters.

Figure 1 shows the block diagram of the installation; figure 2 - switching unit; fig.Z - logical block; . 4 shows a comparison unit and discrete signal operators; in FIG. 3 a step block; 6 shows a discretely controlled aperiodic element.

The device contains a power supply source I - a network, switching 2 and logic 3 blocks, temperature sensor 4, first 5 and second 6 temperature setters, comparison unit 7, generator of 8 discrete signals, element 9, generator 10 of signals pulses, step block 11, discretely controlled aperiodic element 12, threshold element 13, voltage divider 14, control unit 15, power thyristor 4 pulse 16.

The switching unit 2 (FIG. 2) consists of a switch unit 17 and an electroplating element 18, as well as a power device, 19 protection, a power switching device 20 and a galvanic separation element 21.

Logic block 3 (fig.Z) contains the element LHS 22, the first element is AND 23, the second element is NOT 24, the second element is AND 25, the first element is NOT 26 and the element MEMORY 27.

Comparison unit 7 (FIG. 4) comprises an amplifier 28, a first 29, and a second 30 reference elements.

Shaper 8 discretes signals (figure 4) contains the first 31 and second 32 threshold elements with co-embedded in each of them the control devices.

The step block 11 (FIG. 3) contains a counter 33 with a finite predetermined number of outputs.

The discrete-controlled aperiodic element 12 (Fig. 6) contains the H & Co element (capacitor) 34, first 35.1, second 35.2 ,, .., 35., K-th 35.k permanent resistors, where k is the final specified number of these resistors, the first 36 and second 37 temporary resistors, the first 38.1, the second 38.2, 38.P-2, 38.P-1, and 38.p are magnetic-controlled elements, where n is the final specified number of these el.e

elements, magnetic control elements 39.

The power supply unit 15 (Fig. 1) holds a voltage-stabilizing source 40 and an amplifier 41, consisting of diodes 42-45, resistors 46-49, low-power thyristor 30. In addition, the control unit I3 contains a diode 31, a capacitor 32 and resistor 33

The power thyristor controller 1B is made on the power touristors 34 and 35, connected in opposite directions.

FIG. A voltage control device 36 and an electric furnace 37 with electric heaters 38 made of silicon carbide are shown.

Corrective unit 39 (FIG. 1) contains an element. NOT 60, magnetically controlled element 61 and variable resistor 62.

The installation works as follows.

The initial state is characterized by setting the I 7 switch to a position in which there are no logical 1 signals at its outputs, the power switching device 20 is turned off, there is no voltage on the power thyristors 34 and 33 of the power thyristor controller 16, on all outputs of the step block 11 no logical signals I.

When the state is turned off, there are no signals from logical 1 on the second and fourth inputs of logical block 3, which leads to the absence of the same signal at the output of the second element I 23 and the first output of this block. The first element 26 of the logical block 3 generates a signal of logical I, which translates the element MEMORY 27 of this block into a state in which the output of the logical block 3 also lacks a signal of logical I.

In the discrete signal generator 8, the first threshold element 31 is in the open state and there is a logical i signal at its output and the first output of this generator. The second threshold element 32 is in the closed state and at its output, as well as the second output of the former 8 discrete signals, the signal {logical 1 is absent.

Logic 1 signals are absent at all inputs of discrete-controlled aperiodic element 12, which means that the conductive part of the magnetically controlled elements 38 and 39 are disconnected and, accordingly, the constant 35.1 - 35.k and variable and 36 and 37 resistors are bypass . The storage element capacitor 34 is not charged.

The power to the control unit 15 is not supplied, as a result of which the output of the amplifier 41 and, accordingly, this unit has no control signals supplied to the corresponding power thyristors 54 and 55, the power thyristors 54 and 55 of the power thyristor unit 16.

Poro-ovine ele -21gg 13 is in the closed state.

Variables The first resistors 36 and 37, included in the sampling-o-controlled aperiodic element 12, are set to the position at which the resistance of the variable resistor 36 is equal to its zero value and the variable resistor 37 to its maximum value.

To prepare the device for operation, the switch 17 is transferred to a position where at one of its outputs and the first output of this element a signal 1 is formed, with which the power switching device 20 is turned on, as a result of which the power outputs are applied through the corresponding power outputs of this unit thyristors 54 and 55 of the thyristor power controller 16.

After that, the rotation of the variable resistor 37 sets the initial voltage on the new electric heaters 58 made of silicon carbide - electric furnace 57. The voltage is controlled by the device 56, and the magnitude of this voltage is generated by the pulse-phase method by changing the angle - neither power thyristors 54 and 55. Then, by rotating the variable resistor 36, they are installed on electric heaters 58 of silicon carbide for an amount of reduced voltage, which is also controlled by device 56. that the process of forming the angle of unlocking the power thyristors 54 and 55 of the power thyristor re

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five

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25

thirty

35

40

45

50

55

the stator 16 is synchronized with the mains sinusoidal voltage that the thyristors simultaneously feed at, as well as the amplifier 41 and the stabilized voltage source 40.

In the discrete-controlled aperiodic element 12, the voltage rise rate is controlled by the cumulative element 34. This control is accomplished by discretely commissioning or outputting from it the corresponding resistors connected in series with this cumulative element. The input of these resistors into operation or their withdrawal from it is performed with the help of the corresponding magnetically controlled elements 1t 38 and 39.

The control pulses, which are applied to the power thyristors 54 and 55, are formed in a perceptible manner. The control electrodes of the power thyristors 54 and 55 of the CTiJioBoro thyristor controller 16 are connected via the first and second controllers of the control unit 15 to the cathodes of the diodes 42 and 44 connected in series with the corresponding dimmer resistors 46 and 47 of the bridge amplifier 41. Two other arms - diodes 43 and 45. The diagonal of the direct current of this bridge is connected in series with a limiting resistor 48 and a low-power thyristor 50, After the storage element 34 entering into the discrete-controlled

aperiodic element 12, charges - 1 s at a given speed to the required

voltage, it is compared in the threshold element 13 with the reference voltage supplied to it from divider 14. When these voltages are equal, the threshold element 13 is unlocked, as a result of which a control signal appears on the resistor 49. , to the control electrode of a low-power thyristor 50, which is unlocked, which ultimately leads to the formation of the supplying sinusoidal voltage of the control signals on the corresponding resistors 46 and 47, connected in series with their diodes 42 and 44, as well as unlocking the corresponding power thyristors 54 and 55. It should be noted that the operation of the storage element 34, threshold element 13, low-power thyristor 50 also occurs synchronously with the frequency of

sinusoidal voltage, t, e in each half-period of this voltage is charged accumulative element 34 to the desired voltage at a speed that ultimately determines the time of unlocking power thyristors 54 and 55, as well as the subsequent discharge of the cumulative element 34, wherein, by using resistors 35 - 37, the charge rate of accumulative element 34, it is possible to regulate the moment of unlocking the threshold element 13, low-power thyristor 50, the corresponding power thyristors 54 and 55, which leads to the formation of different knowledge voltage is not applied to electric heaters 58 of electric furnace 57. Moreover, the greater the value of the total resistance in the accumulative circuit of the element 34, the slower the voltage build-up voltage on it, the later the unlocking of the power thyristors 54 and 55 and the smaller the voltage generated, on electric heaters x 58,

A decrease in the resistance in the accumulator element 34 leads to an increase in the voltage on the electric heaters 58. After the preparatory work is completed, the switch 17 is switched to the position where its outputs do not have logical 1 signals, while the voltage from the electric heaters 58 is removed .

The device works as follows. In the switching unit, the switch 17 is set to the position at which signals are generated on its outputs. One signal through the switch 3 7 is fed to the control input of the power switching device 20, as a result of which it is turned on, applying voltage through the power outputs of its unit to thyristors 54 and 55 of the thyristor unit 16, also to amplifier 41 and the source 40 of the stabilized voltage of the shredding unit 15. The other signal of the switch 17 of the switching unit 2 is supplied to the galley separation element 18, as a result of which a logical I signal is generated at its output and the second output of this unit.

At the control output of the power switching device 20, a signal is generated which is applied to the element

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21 of the galvanic separation of the switching unit 2, as a result of which a logical 1 signal is generated at the outputs of this element and the control output of this unit.

From the second output of the switching unit 2 and its control output, the signals of the logical 1 are received, respectively, to the fourth and third outputs of the logghetious unit 3.

Signals logic 1 from the third and fourth inputs of logic block 3 are received respectively on.

5 of the inputs of the first 23 and second 25

elements And this block. The logical 1 signal from the fourth input of the logical block 3 is also fed to one of the inputs of the first element AND 23 and the input of the element NOT 26, with the result that the signal of logical 1 disappears at the output of this element and the reset input of the MEMORY element 27.

With the help of the first temperature setting unit 5, its preliminary value is set, and with the help of the second setting unit b, its operating values are set. Analog signals from these drivers are received through the second and third inputs.

0 of the comparison unit 7 to one of the inputs of the first 29 and second 30 comparison elements, respectively, which form at their outputs analog signals proportional to the mismatch between the corresponding signals specified by the first 5 and second 6 setters and the current temperature value received from the temperature sensor 4 through the first input of the comparison unit 7 to its amplifier 28 to the other inputs of the respective first 29 and second 30 reference elements.

The error signals from the outputs of the first 29 and second 30 reference elements are transmitted through the corresponding first and second outputs of the comparison unit 7 to the first and second inputs of the imager 8 discrete signals.

From these inputs, signals are received respectively at the first 3 and second 32 threshold elements, which have built-in setters, with which the threshold of these elements is adjusted depending on the error signal, while the first of them controls the error signal at the first input of the driver

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8 individual signals, and the second - at its second input. Moreover, at the output of the first threshold element 31 and the first output of the generator 8 discrete

A logical signal 1 is generated, the presence of which will be until those nopj until the signal from the temperature sensor 4 becomes more than the one specified by the first unit 5, the dark rector of the lean unit 59, as a result of the procedure. On the input of the second threshold element 32 and the second output of the 8 discrete signal generator, a logic signal appears when the signal from the sensor 4 of temperature 15 that 12 becomes greater than that of which the conductive part turns on and the variable resistor 62 shunts the first variable - resistor 36 of a discretely controlled aperiodic element. This leads to the fact that the first variable resistor 36 and the variable resistor 62 o-once are connected in parallel (the first resistance, which

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-; enta OR 22 5 result volume from input signal

with the second setpoint Thus, the electric furnace in the electric furnace 57;: in the first code, formir-; - :, signals from 5; vl & koi, which the sand input of the logic block through one of the inputs to the input element HE is NOT 24, which is absent at the output of the second element AND 25 and is also absent at the output of the second element And 25 and the first input of the logic unit 3. At the second output of which there is no such signal either, since it is not present at the output of the first element AND 23 and the element MEMORY 27.

The absence of logic 1 signals at the outputs of logic 3 and step 11 blocks leads to the fact that all the resistors of the d-amplified-controlled aperiodionic element 12 are bridged. This makes it possible to form an amount of undervoltage on electrically heated heaters 58 of silicon carbzad silicon, and the device switches to the mode set by the first unit of temperature 5. The preheating of the electric furnace 57 begins, and the device provides the possibility of accelerating this preliminary heating, which is provided by the corrective unit 59, whose input is connected to the second output of logic unit 3, and the outputs are connected to the corresponding inputs of the discrete-controlled aperiodic element 12, as a result, the series-connected magnetically controlled element 61 and the variable resistor 62 of the correction unit 59 are connected in parallel

but the first variable resistor of the discrete-controlled aperiodic element 12. In the absence of a signal at the second input of logic unit 3 and the input element HE 60, a logical signal is generated at the output of the last one, which affects the magic control element 61 of the correction unit 59, resulting in 12

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whereby the conductive part is turned on and the variable resistor 62 shunts the first variable — the resistor 36 of the discretely controlled aperiodic element. This leads to the fact that the first variable resistor 36 and the variable resistor 62 are connected in parallel,

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which leads to the formation of a higher level of low voltage, which will be greater than the previously formed one. This speeds up the pasoi peB of electric furnace 57.

When the signal from sensor 4 of the current circuit becomes larger than the signal from the first setpoint temperature 5, then this leads to a malfunction of the first threshold element 31, the signal disappears at its output and the first output of the imager 8 discrete signals logical 1, This signal is also missing at the first input of logic unit 3, the input and output of its element OR 22 and the input of element NOT 24, as a result of which at the output of this element and one of the inputs of the second element AND 25 appears sig5ia-l logical 1. The presence on both outputs of the second The AND 25 signal of logic 1 leads to the appearance of the same signal at its output and the first output of logic unit 3, which acts through the control input of the discretely controlled aperiodic element 12 on the control part of the magnetically controlled element 39, the conductive part which opens, as a result. As a result, variable resistors 36 and 62 are shunted, which makes it possible to form the total voltage across the electrolytic heating bodies x 58.

1 When the signal from temperature sensor 4 continues to increase, ultimately, the second threshold element 32 opens,

the result at its output, the second output of the imaging unit 8 discrete signals and the second input of logic unit 3, a signal appears logical, 1. This signal in logic unit 3 is fed through the element OR 22 to the input of the element-NOT 24, as a result of which the signal of logical 1 at its output disappears, one of the inputs of the second element I 25 and the first output of logical unit 3. At the same time the signal of logical 1 from the second input logic unit 3 is fed to one of the inputs of the first element AND 23 and in the presence of the same signals on its other inputs, the signal of logical 1 is formed at the output of the first element AND 23. This signal converts the element MEMORY 27 into the state at which its outputand the second output of the logic unit 3 appears non-vanishing signal logical 1, arriving at one of the inputs of the element And 9, as well as the input correction; of the current block 59 and the input of its element NOT 60, at the output of which the logical 1 signal disappears, as a result of which the wire is disconnected

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temperature until a logical signal 1 appears at the second output of the imager of 8 discrete signals, which again leads to the formation of a common blue voltage. Thus, the formation of a full or low voltage is maintained by the mode of operation of the device set by the second unit 6 temperature.

When the device maintains the mode set by the second temperature setting unit 6, the aging of the silicon carbide heaters and the formation of influences that take this aging into account is controlled.

If the signal of the Logtska 1 disappears at the output torus of the generator of 8 discrete signals, the signal of logical 1 appears at the first output of logical block 3 and this leads to the formation of full voltage on the electrical heaters 58 of silicon carbide. At the same time, the signal of logical 1 from the first output of logical block 3 is fed to one of the inputs of the element 9.

The presence of logical signals 1

25

The common part of the magnetically controlled element-ZO at both inputs of the element And 9 leads

This 61, which ultimately leads to the exclusion of the shunt effect of the variable resistor 62 during further operation of the device,

From this point on, the device goes into the temperature set by the second setpoint point b, while at the first output of logic unit 3, the signal of logical 1 disappears, which

of temperature 6, then this causes k to disappear the signal of logical I at the first output of the logic block

leads to the disconnection of the conductive signal temperature from the second setpoint of the magnetically engraved element 39, to the shunting of the variable resistor 36, and consequently, the formation of a low voltage on the electric heaters 58 of silicon carbide, the value of which is determined only a variable resistor 36. A decrease in the signal from the temperature sensor 4 begins, which leads,

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3 and, accordingly, at the output of the element 45 And 9. The generator of 10 rectangular pulses is turned off, and a pulse is formed at its output. This indicates that the silicon carbide heaters 58 provide the required power.

If, when the generator is turned on, 10 rectangular pulses form a pulse at its output after a pause, this indicates that.

ultimately, the disappearance of the logical 1 signal at the second output of the imager 8 discrete signals and the appearance of the same signal at the first output of the logic block 3. This again shunting the overgg electric heaters 6 from the carbide resistor 36 and the formation of silicon does not give the required power - total voltage on electrical heat. The pulse from the generator output 10 bodies x 58 of silicon carbide. Again, the rectangular pulses receive an increase in the signal from the sensor 4 to the control input of the step block.

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Formed1) the same signal at its output. This signal starts the generator of 10 square-wave pulses, which begins its work with the formation of a pause. If during this pause, a logical I signal appears at the second output of the imager 8 discrete signals, which indicates that the signal from sensor 4 is exceeded

of temperature 6, then it causes k to disappear the signal of logical I at the first output of the logic block

signal temperature from Vtorogr

40 temperature signal from the second set

0

3 and, accordingly, at the output of the element 45 And 9. The generator of 10 rectangular pulses is turned off, and a pulse is formed at its output. This indicates that the silicon carbide heaters 58 provide the required power.

If, when the generator is turned on, 10 rectangular pulses form a pulse at its output after a pause, this indicates that.

The gg heaters 6 of silicon carbide do not give up the required power. A pulse from the generator output of 10 rectangular pulses is fed to the control input of the step block.

11 and further to the control input of the counter 33, which generates at its first output and the corresponding output of its block a non-disappearing signal of logical 1, coming through the corresponding input of the discretely controlled aperiodic element 12 to the control part of the magnetic control element 38.1, the conductive part of which opens and shunts the resistor 35.1, and this ultimately leads to an increase in the voltage on the electrical heaters 58 of silicon carbide. Then again, a generator of 10 rectangular pulses forms. pause, while if it is turned off during this pause, it means that, electric heaters 58 of

Silicon carbide gives the required power to this light-signal device.

ness In the future, the device maintains the mode set by the second temperature setting unit 6 already at a new voltage level, etc.

When the generator is turned on for 10 rectangular pulses, it can generate any number of pulses, which lead to removal of the required power from electrical heaters 58 from silicon carbide.

As the electric heaters 58 of silicon carbide ages, the gradual formation of the signals of logic 1 at the outputs of the step block 11 and, accordingly, gradual shunting of the resistors of the discrete controlled aperiodic element 12 occurs, and

When the light signaling instrument is lit (figure 1), a reset step is performed

variable resistor 37 is shunted

This then makes it possible to obtain the maximum 40 block 11 by supplying a maximum voltage to the input at the output of the device and, accordingly, to electric heaters 58 of silicon carbide. In this case, the device maintains the mode set by the second temperature sensor 6 in such a way that when the variable resistor 36 is bridged, the maximum value of the voltage is generated.

device signal is logical 1, which leads to the absence of the same signals at all outputs of counter 3 and the corresponding outputs of step block 11. In order to turn on low-power thyristor 50, source 40 of stabilized voltage does not shunt control currents of power thyristors and 55, a diode 51, a capacitor 52 and a resistor 53 are inserted into the circuit of the control unit 15. At the same time, the reduction of the control current of the low power thyristor 50 at the moment of its activation is excluded

on electric heater 58 of silicon carbide 50, and when it is shunted - reduced.

A serial connection of the magnetically controlled element 38.n and one of the parts of the magnetically controlled element 39 allows, after switching on the magnetically controlled element 38, n to obtain the necessary difference between

maximum and low voltage values.

The device is switched off when the switch 17 is switched to a position where its output does not have a logical 1 signal. This leads to the switching off of the power switching unit and resetting

logic unit 3, at the outputs. which there are no signals from logic 1. Moreover, if the light-signal device connected to the output of the step block 11 (figure 1) does not light up before turning off the device, this means that electric heaters 58 made of silicon carbide have not exhausted their power opportunities. If before switching off the device, electric heaters do not give up the required power already.

In addition, the absence of a light signaling device (Fig. 1) indicates that all outputs of the stepping block 1I have signals of logic 1, and, if there are any, these signals remain after the device is turned off. This makes it possible, when the device is next turned on, to always start applying voltage to silicon carbide heaters 58 of the same magnitude as when the device was turned off before it was turned on.

When the light signaling device (Fig. 1) is burning, the step-by-step of the block 11 is reset by inputting

the signal device is logical 1, which leads to the absence of the same signals at all outputs of counter 33 and the corresponding outputs of step block 11. In order to turn on low-power thyristor 50, stabilized voltage source 40 does not shunt effect on control currents of power thyristors 54 and 55, a diode 51, a capacitor 52 and a resistor 53 are inserted into the circuit of the control unit 15. At the same time, the control current of the low-power thyristor 50 is not reduced at the moment of its activation.

The proposed installation increases the service life of the heaters and, consequently, increases the reliability of the entire installation,

Claims (3)

1. Electrothermal installation with silicon carbide heaters containing a thyristor voltage regulator supplied with a control unit, connected to the network via a switching unit, a sensor and a temperature setpoint connected to two inputs of the comparator unit, a discrete signal generator, a threshold element and a voltage divider, characterized in that, in order to increase the service life of the heaters, the installation is equipped with a logic unit, an AND element, a square pulse generator, a step unit, a discrete suppressor an aperiodic element and a second temperature sensor connected to the third input of the comparator unit, made two-channel, two of which through a discrete driver The signals are connected to the first and second inputs of the logic unit connected to the third and fourth inputs to the outputs of the switching unit. The first and second outputs of the logic unit are connected to the inputs of the element I, the output of which through the square pulse generator is connected to the control input of the step unit connected the outputs to the inputs of the discretely controlled aperiodic element, the power inputs of which are connected to the output of a stabilized power source connected through a voltage divider to the control input threshold element through which 50 0 5 five the control unit is connected to the output of the discretely controlled aperiodic element, the control input of which is connected to the first output of the logic unit. 2. Installation on n.l, about t of l and - Since the logical block contains two AND elements, two NOT elements, OR elements and MEMORY, the output of the first AND element is connected to the input of the MEMORY element, the first inputs are NOT connected to the control input of the first element elements AND, the output of the element OR through the second element is NOT connected to the second input of the second element AND, the first input of the logic unit is the first input of the element OR. the second input is the second input of the OR element and the second input of the first element I. The third input is the third input of the first element AND, the fourth input is the first input of the second element AND, parv output g the output of the second element AND, and the second output the element 3. Install on pi. and 2, characterized in that it is equipped with a correction unit containing a series-connected element NOT, a magnet control element and a variable resistor, the element input is NOT connected to the second output of the logic unit, and the output end of the resistor and one of the outputs of the magnetically controlled element connected to the inputs of the discrete-controlled aperiodic element. Shg / e .; Reset - CBemocaz device 1Ы V.1-o f8 .2 kpos. (to: approach (/) " Jig 7 f./fy /r/7W.J Tf ( n03-B5 KnOS.JS Fi.2 Item 8 BUT To pos. 2 0V 7A j d j / TWO: 1 KnW. e.J TO REF. 6 Knos.5fz. four To pos. R 1B. about .7 To pos. 12 To pos.15 Hn03J3 Turns (to pos. 11) FI.5 Knos.lS kpos