SU1103364A1 - Induction-heating melting installation - Google Patents

Abstract

1. INDUCTION MELTING INSTALLATION, containing an oscillating circuit connected to a furnace transformer with a switching capacitor switching unit, the power outputs of which are connected to contactors switching capacitors, and the control input to the output of the phase angle sensor and inductor, characterized in that accelerating the tuning of the oscillating circuit, the installation is equipped with a pulsed exciter, the output of which is connected to the circuit, and the input to the output of the cycle generator, and a digital converter ode. the input of which is connected to the circuit, the first output is connected to the first input of the comparison unit connected by the second input to the counter, and the three outputs to the first inputs of the three I elements, to the second inputs of which the second output of the converter is connected, and the outputs of the two I elements are connected to two additional the inputs of the switching unit, and the output of the third I-element with the inhibiting input of the cycle generator. 2. Installation according to claim 1, characterized in that the period digital converter comprises serially connected nu-organ, a delay element, a fourth And element and a first trigger, the output of which is connected to the input of the second trigger connected with the second input of the fourth element And, and to the first input of the fifth element I, (L connected with the second input with the filling generator, a output with the input of the counter, the input of the converter being the input of the zero-organ, the first output - the output of the counter, and the second output - the output of the second trigger. with about Aude

Description

The invention relates to induction heating and can be used in the smelting and foundry industry of the metallurgical industry.

A device for automatically controlling the electric mode of an inductive installation is known, comprising measuring and power factor control units of a power oscillating circuit, actuators, an additional transformer, switching elements, a control unit. The principle of operation of the device is that, in order to eliminate current surges and switch on the induction furnace to a predetermined power factor, the furnace is previously connected to an auxiliary supply transformer with a low output voltage, adjust the load circuit, after which the auxiliary transformer is disconnected and transformer 1.

The drawbacks of such a device are the presence of an additional power transformer and switching elements, as well as the need for additional switchings in the power circuit when the device is turned on and off.

The closest to the technical essence of the invention is an induction melting installation comprising an oscillating circuit with a switching capacitor switching unit, the power outputs of which are connected to contactors switching capacitors, and the control input to the output of a sensor of the inductor phase angle 2.

The device serves to turn on the induction furnace at a predetermined power factor and prevent current overloads during subsequent switching-off of the kiln plant after draining. This is achieved by the fact that, as the furnace is tilted and the metal is drained, an alternate predetermined shutdown of the section of the compensating capacitor bank occurs.

This device is characterized by low reliability due to the presence of a mechanical sensor and insufficient accuracy, since the capacitance required for compensation is determined indirectly (the angle of inclination of the furnace). In addition, the device prevents the furnace installation from turning on to an uncompensated circuit only directly behind the discharge of the liquid metal, i.e. in other operating modes (switching on after furnace loading, switching on after voltage removal, erroneous switching on, etc.), switching on the furnace with current overloads is not excluded, which entails the operation of current protection, emissions of charge materials, reduction of the service life of the power electrical equipment, even when using lower stages of the supply transformer. If the power supply is unregulated, then turning on the kiln installation with an unconfigured circuit presents considerable difficulty due to the operation of the current protection. Commercially available ARIRS controllers for adjusting the power factor of the furnace oscillating circuit ensure that the electric melting mode is maintained only when the furnace is operating, the same furnace installation usually occurs on an uncompensated circuit, which even with a low supply voltage

0 causes frequent actuation of current protection, emissions of molten metal with the furnace lid open and frequent failure of electrical equipment. The purpose of the invention is to accelerate the tuning of the oscillating circuit.

 To achieve this goal, an induction melting installation containing an oscillating circuit connected to a furnace transformer with a switching unit of compensating capacitors, power

The Q outputs of which are connected to contactors switching capacitors, and the control input with the sensor output of the phase angle of the loop inductor, is equipped with a pulsed exciter whose output is connected to the loop and the input to the output of the cycle generator and a digital converter of the period whose input is connected to the circuit, the first output - to the first input of the comparison unit connected by the second input to the counter, and the three outputs to the first inputs of the three elements I, to the second

The 0 inputs of which are connected to the second output of the converter, the outputs of the two elements AND are connected to two additional inputs of the switching unit, and the output of the third element I to the inhibiting input of the cycle generator. A period digital converter contains a null-organ, a delay element, a fourth And element and a first trigger, the output of which is connected to the input of the second trigger connected to the second input of the fourth And element, and to the first input of the fifth And element connected by the second the input with the filling generator and the output with the input of the counter; the input of the converter is the input of the zero-organ, the first output is the output of the counter, and the second output is the output of the second trigger. FIG. 1 is a block diagram of the proposed installation; in fig. 2 is a period digital converter circuit; in fig. 3 voltage plots on the oscillating circuit of the furnace installation during operation of the device.

 The induction melting installation 1 includes a furnace transformer 2, current and voltage sensors 3 and 4, inductor 5 and compensating capacitors 6 that make up an oscillating circuit, a phase angle sensor 7 whose inputs are connected to current and voltage sensors, and outputs to the connection unit 8, which controls the executive contactors 9 of the switching capacitors of the furnace. The structure of the device also includes a cycle generator 10, the output of which is connected to the input of a pulsed exciter 11 connected to an oscillatory circuit. A digital period converter 12 is also connected to the latter, the outputs of which are connected to the first inputs of the elements 13, 14 and 15 and to the first input of the comparison block 16, the output of the counter 17 is connected to the second input of the comparison block through the element 13 that connects with the first additional input of the switching unit 8, the second output through the element 14 and with the generator of cycle 10, the third output through the element 15 and 15 with the second additional input of the switching unit. The digital converter circuit includes a zero-body 18, a delay element 19, a fourth element And 20, triggers 21 and 22, a filling generator 23, a fifth element And 24, and a counter 25. Plug the zero-body 18 to the load oscillating circuit, the output through the delay element 19 is connected to the first input of the element 20. The output of the element 20 and through the first trigger 21 is connected to the second trigger 22 and to the first input of the element 24, the second input of which is connected to the filling generator 23. The output of the element 24 is connected to the counter 25, and trigger output 22 is connected to the second input lementa and 20. The input digital converter period serves as an input-zero body 18, and the output - the output latch 22 and the output of the counter 25. The device operates as follows. Immediately before switching on the furnace transformer 2, the command “Start-up to turn on the generator of cycle 10, which with a certain frequency of 1 / T cycle begins to send signals to turn on the pulse driver 11. When a pulse driver, for example, including a voltage source, storage capacitor, bit the thyristor and the limiting choke, the precharged capacitor is connected to the oscillatory circuit of the load with the help of a discharge thyristor and the oscillating oscillations are excited in it with some frequency of 1 / T. The voltage of the circuit is fed to the input of period digital converter 12. At the output of the digital converter in each cycle of operation of the device, a binary code number is recorded that is proportional to the period of free oscillations of the load Tj, T g and Tz. At the output of counter 17, when the device starts up with a new pulse, a binary code number is recorded that is proportional to the voltage period of the Tset network. In comparison block 16, these values are compared, and the Comparison block is constructed in such a way that when the input values () are equal, output If the first number A is more than the second B, i.e. the period of natural oscillations of the induction furnace circuit is larger than the period of the mains voltage, the signal appears at the first output, and if A is less than B, then the signal appears at the third output. Next, the signal from the first output of the comparison unit, in the presence of the signal "Counting through the element I 13, is fed to the first input of the switching unit 8, which, by acting on the executive contactors 9, turns off the unit section of the compensating capacitor battery. The signal from the third output of the comparator when the signal is present. The account through the element 15 is fed to the second input of the switching unit 8, which, by acting on the executive contactors, connects the unit section of the compensating capacitor battery. The voltage plots of the oscillating circuit of the load in FIG. 3 illustrates triple trip of the device, with the first two triggers output a signal at the third output of the comparator unit, causing the connection of a single section of the compensating capacitor battery. At the same time, the period of free oscillations of the circuit is increased. Suppose that during the third cycle of operation of the device, the period of free oscillations of the load circuit Tz becomes equal to the period of the network voltage Tseti. then, at the end of the cycle, the signal appears at the second output of the comparison unit and, if there is a signal "Counting through the element 14", the signal goes to the cycle generator 10, prohibiting further operation of the device ,. The same signal can be given permission to turn on the linear switching device (not shown in Fig. 1). Inclusion is made on a power oscillating circuit tuned to resonance, therefore current overloads, tripping of protection, etc. are excluded. The period digital converter operates as follows. At each triggering of the pulsed exciter 11 in the load circuit, damped free oscillations with a period T are excited. The voltage from the circuit goes to the zero-body 18, at the output of which pulses are formed at the time of voltage passing through zero values. The first zero-organ impulse, corresponding to a voltage transition on the load circuit from a positive to a negative value through a delay element 19, eliminating false triggering of the zero-body at the time of a sudden voltage on the load circuit, and And 20, the second input of which is recorded a single signal is fed to the input of the counting trigger 21 and flips it. At the inverse output of the trigger 22, a single signal appears, which, arriving at the first input of the element 24, gives permission for the receipt of filling pulses from the generator 23 to the counter 25. When the second pulse is applied to the input of the trigger 21 corresponding to the voltage transition the contour from negative to positive, the trigger returns to its original state, a zero signal at its output prevents the passage of 24 pulses from the generator 22 output to the counter 25 output through the And element. At the same time The trigger 22 is triggered and bans the passage of pulses from the nullorgan 18 through the element 20. Thus, after each triggering of the pulsed exciter 11 at the output of the period digital converter (output of the counter 25), a number in binary code proportional to the period of free oscillations of the load circuit is recorded. It should also be noted that before each cycle of operation of the device, the elements 21 to 22 must be restored to the initial state indicated in FIG. 2 without brackets, the setting pulse is applied simultaneously with the triggering of the pulsed exciter 11. The first full half-period of damped oscillations of the load circuit is used for the measurement, since it gives the most accurate picture of the nature of the free oscillations of this circuit. The logical part of the device is made on the basis of integrated circuits of the 511 series. Zero-organ 18 is assembled according to the scheme using the OR-NOT element, the input zero-organ transformer is step-up with a transformation ratio of 1:10, since the damped voltage on the power circuit when a pulsed exciter is triggered does not exceed 1 -1.2 V. At a nominal voltage on the circuit, the transformer is disconnected and connected to it only for the duration of the device operation (in order to avoid transformer failure). Comparison unit 13 is also implemented on the elements of the 511 series according to a digital null-organ scheme for bitwise comparison of binary codes. The number of bits to be compared in this scheme is selected depending on the required accuracy of the power loop setting. As a switch unit, an end stage cascade of an automatic control unit ARIR can be used, commercially available in the industry. The use of a standard unit significantly reduces the cost of the proposed device for small-scale production and facilitates its implementation in practice, since the device works with an ARIR unit, which comes complete with an IAT-6 induction melting furnace. Compared with the prototype, the proposed device allows the induction furnace to be turned on without current overloads, the consequence of which is the operation of power current-limiting devices, under any possible switching conditions of the furnace (after loading, after the supply voltage disappears, when there is an erroneous connection, etc.) and eliminates the use of a mechanical sensor with its low accuracy and reliability.

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Claims (2)

1. Induction melting installation, comprising an oscillating circuit connected to the furnace transformer with a switching unit for compensating capacitors, the power outputs of which are connected to contactors switching capacitors, and the control input is connected to the output of the phase angle sensor of the loop inductor, characterized in that, in order to speed up the setting oscillatory circuit, the installation is equipped with a pulse exciter, the output of which is connected to the circuit, and the input to the output of the cycle generator, and a digital period converter the input of which is connected to the circuit, the first output is to the first input of the comparison unit connected by the second input to the counter, and three outputs are connected to the first inputs of three AND elements, to the second inputs of which the second output of the converter is connected, and the outputs of two AND elements are connected to two additional inputs of the switching unit, and the output of the third element And - with the inhibitory input of the cycle generator. 2. Installation according to π. 1, wherein the digital converter comprises a period nulorgan serially connected delay element and a fourth element and a first flip-flop, whose output is connected to the input of the second flip-flop, associated You are a _geared with the second input of the fourth AND elements that S and the first the input of the fifth element And, L · connected by the second input to the filling generator, and the output - with the counter input, and the input of the converter is the input of the zero-organ, the first output is the output of the counter, and the second output is the output of the second trigger. >