CS237722B1 - A method for melting ionically conductive substances, in particular glass, by passing the electrical current through the melt and engaging it to perform the process - Google Patents

Abstract

The invention relates to the field of melting glass and similar substances by electric current and solves the problem of automatic regulation of the melting process of thyristor switches connected to a control circuit. Groups of electrodes are connected to their separately regulated sources cyclically so that in a given cycle only one group of electrodes is connected to the source. An antiparallel pair of thyristor switches is connected between the source and each electrode, while the antiparallel pairs of thyristor switches belonging to the group of electrodes are jointly connected to a timing element connected to a control element, which forms a power regulator, or possibly also a temperature regulator. The function of the timing control element can advantageously be performed by a microprocessor.

Description

The invention relates to the field of melting glass and similar substances by electric current and solves the problem of automatic regulation of the melting process of thyristor switches connected to a control circuit. Groups of electrodes are connected to their separately regulated sources cyclically so that in a given cycle only one group of electrodes is connected to the source. An antiparallel pair of thyristor switches is connected between the source and each electrode, while the antiparallel pairs of thyristor switches belonging to the group of electrodes are jointly connected to a timing element connected to a control element, which forms a power regulator, or possibly also a temperature regulator. The function of the timing control element can advantageously be performed by a microprocessor.

~gn £21 of ⁴

The invention relates to a method of melting ionically conductive substances, in particular glass, by passing an electric current through the melt, supplied to at least two groups of electrodes powered from separately regulated sources. The invention also relates to a circuit for carrying out this method.

When melting steel, the melt must pass through various stages of the melting process, i.e. melting, spreading and stabilization, i.e. different temperature zones according to the specified melting curve. In electric melting, this curve is set and regulated by the power input to the electrodes, their shape, size, degree of insertion into the melt and their mutual spatial arrangement. In normal operation, these factors, once set, cannot be easily changed.

In the publication of J. Stanek Electric melting of glass /SNTL 1976/ on page 297, a method and connection for its implementation are described, by which the voltage on individual pairs or groups of electrodes, connected to individual separately regulated sources, is regulated and thus the power distribution and thus the temperatures are set in individual zones. This method and connection are described and illustrated in Czechoslovak patent No. 118 306, according to which melting is carried out using pairs of electrodes placed next to each other, i.e. essentially horizontally. In French patent documents 2 424 884 and 2 423 453, melting takes place essentially vertically using groups of electrodes supplied from a separately regulated source and placed in different planes above each other.

However, even with this method and connection, the sources are interconnected to a certain extent via the electrodes and the conductive melt, so they influence each other and it is therefore not possible to independently regulate the temperatures in the individual zones in the area of the electrode groups during operation.

The above disadvantages are eliminated or substantially reduced by the method according to the invention, the essence of which consists in the fact that the groups of electrodes are connected to their separately regulated source cyclically, with only one group of electrodes being connected to the source in a given cycle. This is achieved by the circuit according to the invention, the essence of which consists in the fact that each electrode is connected to the source via an antiparallel pair of thyristor switches, with the antiparallel pairs of thyristor switches belonging to the group of electrodes being jointly connected to a timing element connected to the regulating element. The regulating element may be a power regulator, or alternatively also with a temperature regulator, the timing and regulating element may advantageously be formed by a microprocessor.

By connecting and disconnecting the electrode power supply circuits, electrical energy is supplied from the source or sources to the respective electrode groups in a pre-selected time interval when the phase voltage passes through zero, so that the electrode group circuits do not influence each other. The ratio of the time intervals of switching on the individual electrode groups ensures a distribution of power in the melting furnace that is advantageous for the melting process in the individual zones of the furnace, and the intervals can be changed as needed even during melting.

An exemplary embodiment of the invention is described below and schematically illustrated in the attached drawings, in which Fig. 1 is a block diagram of the connection of electrodes with a single-phase source, Fig. 2 is a block diagram of the connection of electrodes in three horizontal planes with a three-phase source, Fig. 3 is a time course of connecting electrode groups to the source without a delay, Fig. 4 is a time course of connecting electrode groups to the source with a delay and Fig. 5 is a time course of connecting electrode groups to the source without a delay and with phase regulation.

Source 1 /Fig. 1/ consists of a single-phase transformer, the secondary winding of which has terminals 2 and 3. To terminal 2, electrodes 8 and 1 are connected via antiparallel pairs £, í of thyristor switches with natural commutation, and to terminal J, electrodes IQ and 11 are connected via antiparallel pairs £, Z of thyristor switches with natural commutation in furnace )2. Antiparallel pairs £, 6 thyristor switches belonging to group g, 10 electrodes are connected together to a timer element 13. ^to which they are connected together to a timer element 12, to which are also antiparallel pairs £, Z of thyristor switches belonging to group 5, JJ. electrodes. Timer element JJ is connected to a regulating element 14 and both legs can be formed by a microprocessor JJ. The regulating element 14 forms a power regulator 15, or also a temperature regulator 16.

Fig. 2 shows a group of electrodes 60 comprising electrodes 37 to 39 and 52 to 54. a group of electrodes 61 comprising electrodes 40 to 42 and 49 to 51 and a group of electrodes £2 comprising electrodes 43 to 48. The individual groups of electrodes 60, 61, 62 are placed one above the other in a vertical electric melting furnace (not shown). The source 18 is a three-phase transformer, to the secondary windings of which the electrodes of phases R, S, T are connected so that the electrodes 37, 54 from the group of electrodes 6g, the electrodes 40, 51 from the group of electrodes 61 and the electrodes 43, 48 from the group of electrodes 62 are connected to the phase £. Similarly, electrodes 38, 53 from the group of electrodes 60, electrodes £1, 50 from the group of electrodes 61 and electrodes 44, 47 from the group of electrodes 62 are connected to phase S. Electrodes are connected to phase T

39. 52 from the group of 60 electrodes, electrodes 42. 49 from the group of 61 electrodes and electrodes ££, from the group of 62 electrodes.

In order for the individual groups 60. 6J_ _t 62 of electrodes not to influence each other and for current not to flow between their electrodes simultaneously, there must be antiparallel pairs 19 to 36 of thyristor switches between each electrode 37 to 54 and the source 18. Therefore, in phase £ there are antiparallel pairs 36. JJ of thyristor switches between * electrodes 37. 54 of the group 60 of electrodes and the source 18, antiparallel pairs JJ, 22 of thyristor switches between electrodes 43. 48 of the group 62 of electrodes and the source 18, antiparallel pairs 30. 25 of thyristor switches. Similarly, in the circuit, phase S, where between the electrodes 38. 53 of the group of 60 electrodes and the source 18 there are antiparallel pairs 35: 20 of thyristor switches, between the electrodes 41. 50 of the group of 61 electrodes and the source 18 there are antiparallel pairs 32. 23 of thyristor switches and between the electrodes 44. 47 of the group of 62 electrodes and the source 18 there are antiparallel pairs 28. 27 of thyristor switches. Similarly, in the circuit of phase T, the electrodes 39. 52 are separated from the source 18 also by antiparallel pairs 34. 21 of thyristor switches, the electrodes 42. 29 by antiparallel pairs 28. 27 of thyristor switches.

The antiparallel pairs 36. JJ, 34. JJ, 20. 21 belonging to the group of electrodes 60 are connected together to the timing element 55 and similarly to the group of electrodes 61 and 62, the timing element 55 is connected to the regulating element 58. The regulating element 58 forms a power regulator 56, possibly with a temperature regulator 57, and the timing element 55 and the regulating element 58 may be formed by a microprocessor 59.

The connection works as follows:

The timer 13 /Fig. 1/ sets the cycle time for which the antiparallel pairs £, 5t 1 of thyristor switches are to be opened or closed. If the antiparallel pairs £, 6 of thyristor switches are opened, the circuit is closed from the terminal 2 of the secondary winding of the source J. via the antiparallel pair £ of thyristor switches, the electrode g, the electrode 10 of the antiparallel pair 6 of thyristor switches to the terminal J of the secondary winding of the source 1, which supplies the group g, 10 of electrodes. After the set number of cycle periods has elapsed, the timer 13 closes the antiparallel pairs £., 6 of thyristor switches and thus interrupts the described circuit. Then the circuit is closed from the terminal 2 of the secondary winding of the source J, through the antiparallel pair £ of thyristor switches, electrode J, electrode 11. the antiparallel pair 2 of thyristor switches to the terminal J of the secondary winding of the source J, which supplies the group J, 11 electrodes. Switching from one group of 8, 10 electrodes to the other group J, 11 electrodes occurs at the zero of the alternating current in order to eliminate the direct current component.

Switching occurs either without a delay /Fig. 3/, or with a delay /Fig. 4/. The total power input to the furnace 12 is given by the ratio of the number of periods for which the electrodes 8, J, JJ, 11 are connected to the source 1.

In the connection according to Fig. 2, the function is similar to that according to Fig. 1 and thus differs, since each individual phase £, £, £ supplies three mutually independent circuits, which are galvanically separated from each other.

The regulation is carried out by the power regulator 15. 56, to which the data on the desired and actual power are fed. It can also be supplemented by a temperature regulator JJfc, 21. The total power input is regulated by the delay time /Fig. 4/, or phase /Fig. 5/. The function of the timer element 13. 22 and the control element 14. 58 can be performed by a microprocessor U, 22* The method and connection are intended for glass melting; it can also be used for melting other ionically conductive substances, e.g. glazes, salts, basalt, etc.

Claims (5)

A method for melting ionic conductive substances, in particular glass, by passing an electric current through a tannel supplied to at least two electrode groups powered by a separate regulated source or sources, characterized in that the electrode groups aa are connected cyclically to the sources, one group of electrodes is used per instrument. 2. Connection for carrying out the method according to claim 1, characterized in that each electrode (8 to 13, 37 to 54) is connected to the device (1,> 8) via an anti-parallel pair (4 to 7), 19 to 36) of the thyristor switches, wherein the antiparallel pairs (4 to 7, 19 to 36) of the thyristor switches belonging to the groups (8 and 10, 9 and 11, 60, 61, 62) of the electrodes are connected together to the timing member (13, 55). (connected to a control member (14, 58)). 3. The connection according to claim 2, characterized in that the control member (14, 58) forms a power regulator (15, 56). 4. Connection according to claim 2, characterized in that the control element (14, 58) forms the same temperature controller (16, 57). 5. Connection according to claim 2, characterized in that the timer (13, 55) and the regulator (14, 58) form a microprocessor (17, 59).