SU1721842A1 - Resistance electrothermic installation with heaters with high positive temperature resistance coefficient - Google Patents

Abstract

The invention relates to electrical engineering. The purpose of the invention is to increase the operational reliability and service life of heaters. Monitoring the state of the power unit 3 and the unit 4 of the power leads, the current in the heaters 40 and their temperature using the sensor 31c using the logic unit 1 and the controller 2 allows to solve the set task. 1 il.

Description

The invention relates to electrothermal and can be applied in furnaces with electric heaters, for example, from silicide molybdenum, whose resistance increases from 10 to 15 times when heated from a cold state to the required working temperature.

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

The drawing shows the scheme of the proposed installation.

The installation contains a logic unit 1, a regulator 2, a power unit 3, a unit 4 of power conductors, a current signal converter 5.

Logic block 1 contains the first 6 and second 7 elements AND, the first 8, the second 9, the third 10 and the fourth 11 elements NOT, the first 12 and second 13 elements OR, and the MEMORY element 14.

Regulator 2 contains an analog input signal converter 15, a control unit 16, a scaler 17, a comparator 18, a program block 19, a switch 20, an analog output signal converter 21. The control block 16 contains an adder 22 and a PID controller 23, a block of control signals 24 and an operator console 25 (a controller manual control unit).

The power unit 3 contains the power protection devices 26 and the switching device 27, the thyristor voltage regulator 28, the power voltage converter 29, the sensor 30 for monitoring the closed state of the power unit.

Thyristor voltage regulator 28 contains a control unit 31 and a power thyristor unit 32, performed on power thyristors 33 and 34, connected in anti-parallel manner.

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The power supply unit 4 includes a current sensor 35, a cooling water presence sensor 36, a closed current power supply sensor 37, and power supplies 38.

In addition, the drawing shows an electric furnace 39 with electric heaters 40 and a temperature sensor 41,

The voltage on the electric heaters 40 is measured by the device 42, and the current flowing through them is measured by the device 43.

The initial state is characterized by the disconnected state of logic unit 1, as a result of which its first output and, accordingly, the first input of the power unit 3 and the control input of the power switching device 27 do not have a logical unit signal, which ensures the disabled state of this device. The power unit 3 and the power supply unit 4 are in a closed state, which ensures the safety of the operating personnel during operation due to the impossibility of contact with equipment under voltage. The closed state of these blocks is monitored by the respective sensors 30 and 37, which generate signals of the logical unit arriving at the inputs of the logic unit 1. In connection with the disabled state of the power switching device 27, there are no logical unit signals at its control output. The power unit of protection 26 of the power unit 3 is turned on, but the supply voltage from the workshop switchgear is not supplied to the input of this unit. Cooling water flows through the internal cavities of power current leads 38 of power current block 4, which is monitored by sensor 36. At the same time, when there is cooling water, a logical unit signal is generated at the output of this sensor and is fed to the input of logic unit 1.

There are no signals at the output of the current sensor 35 of the power conductor unit 4 of the 4, the first output of this unit, the input and output of the current signal converter 5, which has a built-in current level sensor. There are no signals on all the other inputs and outputs of controller 2, except for the input, where there is a logical unit signal coming from the output of the second element OR 13. Subsequently, this signal goes to the input of program block 19, which ensures that it is switched to stop mode formed due to the disconnected state of the logic unit 1. At the inputs of elements 8,9,12, there are no signals, and

the formation of a signal of a logical unit at the output of the element OR 13 is provided by the state of resetting the element MEMORY 14, in which at its output there is no signal of a logical unit, which leads to the formation of the same signal at the output of the third element NOT 10, the input and output of the second element OR 13 It is possible to form at the second output of this block.

0 signal of a logical unit by applying to the second input element OR 13 the same signal from an external device, which is fed to the second element OR 13.

Using the controller 25 of the controller 5 of the torus 2, the PID controller 23 of the control unit 16 is disconnected from the output signal of the adder 22.

The on and off state of logical block 1 provides 0 s by switching on and off the MEMORY 14 element of this block, which will be discussed in more detail when describing the start and stop modes of the installation; while turning on and off the logical

5 of block 1 are performed by applying signals of a logical unit, respectively, to the eighth and twelfth inputs of the elements of this block.

To prepare the installation for start-up, it is necessary to apply the network voltage to the input of the power unit 3 from an external switchgear. This voltage then enters through the power inputs of the pre-energized power protection device 26, as a result of which the network voltage also appears at the power outputs of this device and the power inputs of the power switching device 27. By applying a short-term signal of a logical unit to

0, the reset input of program block 19 is reset to its initial state for starting operation. The switch 20, when there is no logical unit signal at its third input, is prepared for

5 work on a setting signal, which is implemented by software block 19. Using controller 25 of controller 2, a logical unit signal is generated to the PID controller, which connects it to the output of the adder 22 of the same block. On the power converter 29 of the power unit 3, the required maximum undervoltage level is set, necessary for

5 works of electric heaters 40,

The installation works as follows.

Signaling a logical unit to the first input of the MEMORY 14 element and through the first element OR 12 to the third input

the first element And 6, the first and second inputs of which receive, respectively, the signals of the logical unit from the outputs of the first 8 and second 9 elements are NOT. The presence of a signal of a logical unit at the first element, And b, allows you to generate at its output a signal of a logical unit that is fed to the input of the fourth element NOT 11. At the same time, at its output and the second input of the element MEMORY 14 there is no such signal, as a result of which The output produces a logical unit signal, which arrives at the first input of the second element, And 7, on the second and third inputs of which there are also signals of the logical unit. At the output of the second element And 7, a signal of a logical unit is formed, which through the first output of logic unit 1 and the first input of power unit 3 is fed to the control input of the power switching device 27, which is turned on, applying voltage to the thyristor power unit 32 of the thyristor controller 28. At the same time, at the control output of the apparatus 27 and the second input of the first element OR 12, a signal of a logical unit is generated, which makes it possible in the future not to send the same signal to the first input of the logic block. Moreover, from the output of the MEMORY 14 element, the signal of the logical unit arrives at the input of the third element NOT 10, which leads to the disappearance of the same signal at its output and the first output of the program block 19, which allows it to be started up.

The software block 19 of the controller 2 generates at its output a signal which, through the second input of the switch 20 and the third input of the control unit 16, is fed to the adder 22. The temperature sensor 41 forms at its output a signal characterizing the thermal state of the working space of the electric furnace 39 and, accordingly, electric heaters 40 From this sensor, the signal goes through the converter 15 of the input analog signal to the input of the comparator 18 and through the first input of the control unit 16 to the adder 22. Subsequently, the signals received by The first and third inputs of the control unit 16 are summed algebraically in the adder 22, as a result of which a deviation signal is generated at its output, which then goes to the PID controller 23 of the control unit 16. At its output, a control signal is generated that arrives at the input of the converter 21 analog output signal. At its output, a unified control signal is generated, coming through the second input of the power

unit 3 to the control unit 31 of the thyristor voltage regulator 28, with which at the output of the power thyristor unit 32 of this regulator is formed a voltage supplied to the power voltage converter 29. This converter generates at its output a voltage supplied by This is followed by block 38 of electric heaters 40. The heating of the electric furnace 39 and around these electric heaters is heating up. In the process of this heating, it is necessary to take into account the specific properties of the electric heaters 40. To do this, it is necessary to continuously monitor the current flowing through them, which is performed by the current sensor 35 of the power supply unit 4. The magnitude of the current measured by this sensor enters the current signal converter 5, where it is compared with its predetermined value, which is set with the help of its built-in setpoint device. When the measured current value is exceeded with respect to the output current signal converter 5, a discrete signal is generated, which is fed to the input of the scaler 17, which is triggered, as a result of which a signal is output at its output through the second input of the control unit 16 to the adder 22, where it is summed with the signal present at the first input of the adder 22.

The sum of these signals becomes greater than the signals at the third input of the adder, which after algebraic summation results in a change in the sign of this sum and, ultimately, a decrease in the control signal at the output of the PID controller 23, as well as a unified control signal at the controller output. Subsequently, this leads to a decrease in the voltage at the output of the thyristor regulator 28, power converter 29, and electric heaters 40 until the discrete signal disappears at the output of the current signal converter 5. Thus, direct control of the current of the electric heaters makes it possible to organize their current protection by changing the supply voltage to them depending on the value of this current and at lower levels. The device provides the ability to control and not from the program block 19, but by some level of the master signal supplied to the first input of the switch 20.

To do this, it is necessary to transfer the program block 19 to the reset mode by applying a discrete signal to its second input.

the time of availability of which is determined by the service personnel. The same signal must be sent to the third input of the switch 20, which will ensure that at its output a driving signal present at its first input, and the time of the presence of a discrete signal at the third input of the switch 20 is also determined by the service personnel / Current protection organization of electric heaters this case is carried out as described above.

In order to prevent an unacceptable (emergency) state of the thermal environment in the working space of the electric furnace, the voltage is removed from the electric heaters. In this case, at the output of the comparator 18, a signal of a logical unit is formed, which is fed to the input of the second element HE 9, with the result that the signal of the logical unit disappears at its output and the second input of the first element And 6. This leads to the absence of the same signal at the output of this element, the input of the fourth element NOT 11, at the output of which and the second input of the element MEMORY 14, a signal of a logical unit is formed, with the result that this element is transferred to the state where at its output the first input the second element And 7 and its output, as well as the first output of the logic unit 1, the signal of the logical unit disappears. Subsequently, the same signal is not supplied to the control input of the power switching device 27, as a result of which it is turned off, removing power from the thyristor voltage regulator 28, the power voltage converter 29 of the power supply unit 4 and electric heaters 40. At the same time, the signal disappears logical unit at the control output of the power switching device 27, the second input and output of the first element OR 12, and the third input of the first element AND 6,

In order to ensure trouble-free operation of the electric heaters and power leads of the unit 38 of the unit 4, when the cooling water disappears, voltage is also removed from the electric heaters.

In this case, the output of the sensor 36, the input of the first element Ib and its output, as well as the input of the fourth element NOT 11 disappears the signal of the logical unit, which further leads, as described above, to stopping the supply of voltage to the electric heaters.

It is important to ensure the safety of service personnel during operation, which is achieved by monitoring the closed state of the power unit 3 and power unit 4 of the power conductors.

In the presence of voltage on the electric heaters, the opening of any of the

blocks or both of them together leads to the removal of voltage from them. In this case, the signal of the logical unit at the output of the sensors 30 or 37 or at the output of the one and the other disappears, which eventually leads to

0 the absence of the same signals at both inputs of the second element I 7, its output, the first output of logic unit 1 and the control input of the power switching device 27, which is turned off,

5 relieves voltage from electrical heaters. The operation of the remaining elements of logic block 1, leading to the disconnection of the MEMORY item 14 of this block, is similar to that described above.

0 In all cases described above and leading to the removal of voltage from electric heaters, the element MEMORY 14 is disconnected, which leads to the formation at the second output of the logic

5 block 1 of the signal of the logical unit and the transfer of the program block 19 of the controller 2 to the stop mode.

To stop the logic unit 1, a logical signal is sent to its second input.

0 unit, which enters the input of the first element NOT 8, at the output of which, as well as the first input of the first element Ib and its output, such a signal disappears. At the input of the fourth element NOT 11, the signal of the logical unit is missing, and at its output it This ultimately leads to the disconnection of the MEMORY 14 element and, accordingly, to the disconnection of the voltage supply to the electric heaters, the formation of a logical unit signal at the output of the logic unit 1 and its further supply to the first input of the program block 19 of this regulator .

The installation allows to increase the reliability in operation of heaters and their durability.

Claims (1)

Claims of the invention Resistive electrothermal installation with heaters with a high positive temperature coefficient of resistance, comprising a power unit consisting of series-connected power protection apparatus, switching apparatus, thyristor controller 5 a voltage with a control unit, and a power converter and a sensor for monitoring the closed state of a power unit, a unit of power current leads, consisting of power current leads connecting the output of the power converter voltage with heaters, current sensor, cooling water sensor and sensor of the closed state of the power electrical power supply unit, logical block with elements NOT and MEMORY, regulator consisting of an analog input converter connected to the first input of the block adder control, the output of the adder through the PID controller; connected to an analog output converter from a program block whose output through a switch is connected to the third input of the adder, from a control unit, the installation temperature sensor connected to the input of the analog input signal converter, and the output of the analog output controller of the regulator connected to the control the input of the control unit of the thyristor voltage regulator, and the Start button of the installation, characterized in that, in order to increase the operational reliability and service life Heaters, a comparator, a scaler and a block of setting signals are entered into the controller, and two AND elements are added to the logic block, three additional NOT elements and two OR elements, the dock sensor is connected to the first input of the scaler through the input current signal converter, the output which is connected to the second input of the adder, and the second input the scaler is connected to the first output of the driver unit, the second output of which and the output of the analog input converter are connected to the inputs of the comparator, and the third output of the driver unit and the output of the program block are connected to the first and second inputs of the switch, the first and second elements the OR element and the output of the water availability sensor are respectively connected to the four inputs of the first element AND, whose output through the fourth element is NOT connected to the second input of the MEMORY element connected to you ode to the first input of the second element AND directly and through the third element NOT to the first input of the second element OR, the first inputs of the MEMORY element and the first OR element are combined and connected with the Start button, the second input of the first OR element is connected to the control output of the switching device, The second and third inputs of the second element I are connected to the outputs of the sensors of the closed state of the power block and the power current block, and its output is connected to the control input of the switching device, the output of the second element OR is connected to vomu entry program block, wherein the comparator output is connected to the input of a second NOT member. 3 Network