DE686971C - Method for the selective shutdown of parts of a network - Google Patents

Description

Method for the selective shutdown of parts of a network It is known, a rectifier with vapor or gas discharge paths by means of the grid control switch off in the event of short circuits in the load circuit or internal short circuits. It is also known to use such a rectifier when it feeds a lighting network the grid control in. to start up the Spannurig for the purpose of removing the unusual, to start the cold lighting network after eliminating the cause of the fault.

One tries the usual considerations that are otherwise for the selective Disconnection of sick power supplies apply to be transferred to converters, so shows it see: that, although with rectifiers, the usual points of view are largely Can take into account, but not with the converter, d. H. a facility for immediate Conversion of alternating current of one frequency into alternating current of another frequency by means of Grid-controlled vapor or gas discharge paths with essentially arc-shaped Discharge, and this is mainly due to the fact that during the reversible operation the discharge paths can only be slightly overloaded. So it can be done with consideration the low overload capacity of an inverter cannot be waited for, until the switch of the sick power supply. falls; on the other hand, it contradicts all Requirements of the selectivity. Inverter from the network., So also from the healthy ones Divide, separate.

In the context of the present invention, it is now possible to master the initially contradicting demands regarding selective shutdown and with regard to the overload capacity of the respective inverter discharge paths thereby make it possible for the overcurrent that occurs in the event of malfunctions to initially block the circuit the grid of the converter causes instantaneous and that then according to the invention The citter voltage is canceled and the operation rides steadily increasing grid modulation = is continued, with the. selective withdrawal of the sick power supply in cooperation with the. Power switches takes place. With 'this one The method according to the 'invention_ will firstly be the converter at the moment of the occurrence of the fault, secondly, the sick power supply is relieved by the - Raising the voltage by means of the grid control in cooperation with the power switches without overloading the converter - selectively - disconnected, that is the essential for. the present invention, and furthermore, operation in Figs. healthy. Power supplies because of the brevity with which the process takes place in not affected in any way. This last requirement determines the time between instant switch-off and switch-on of the converter.

For the following considerations it should be assumed that the converter where ° feeds the consumer network; and for the time being it should be based on figs: i to 3 the raising of the voltage after the disconnection process will be explained. In the embodiment According to Fig. i, a converter is assumed in which all the Umformuhg performing main discharge paths have a common cathode potential; combined in a single multi-anode discharge vessel with a common cathode can be. From the main circuits of the grid-controlled steam or gas discharge lines is in the present case only the mercury cathode 4 of a multi-anode iron vessel shown. It is further assumed that each of the two groups of discharge paths only three discharge paths each with the grids i`, z '"3.' or ", 2", 3 "contains; furthermore, there is only one control path for each grid circle to simplify the overview specified, namely the one for rectifier operation. For all grid circles is a negative bias voltage 5 is provided, which via resistors C 'and 6 "the grids is supplied and has a blocking effect. The onset of the discharge in the discharge path is controlled by control pulses that are generated by means of auxiliary discharge paths-io ', iö ", 2d, _ 20", 3ö ', 30 "can be supplied. For the auxiliary discharge paths, as for the main discharge paths, grid-controlled discharge paths with essentially arc-shaped discharge: The anode voltage is one from the higher-frequency Network removed by means of a rotary transformer 7 and in means of a transformer 12 or 22 or 32 supplied alternating voltage. Appropriate phase position is used. Likewise, the grid circles receive the auxiliary discharge routes except where applicable required bias voltages a control alternating voltage of rectangular or approximately rectangular waveform, which is also taken from the higher-frequency network. Furthermore, the aforementioned auxiliary discharge paths are in. Low frequency clock controlled, in the present case in groups by another; in row switched auxiliary discharge path ioo 'or ioo ": The grid circles of these two Auxiliary discharge sections each receive one derived from the low-frequency network Alternating voltage with the appropriate phase position, which - in the present case, the rotary transformer 8 is taken. To achieve precise control effects @ it is necessary that the control alternating voltage supplied to the grid circles of the auxiliary discharge paths s zoo 'and ioo " deviate from the sinusoidal shape and an essentially rectangular curve shape must accept. Although, of course, other options are also provided for this can; in the present case, the transformation of the transformer 103 presented, essentially sinusoidal alternating voltage - through further auxiliary discharge paths ioi 'and ror "take place, -whose lattice circles from the low-frequency network a rotary transformer 9 and a `grid transformer io2 an alternating voltage appropriate phase position is supplied. Since in general the low-frequency network is only single-phase, those are necessary for the primary winding of the rotary regulators S and 9 further phase voltages in a manner known per se by means of inductive or capacitive To win pseudo-resistances.

In the context of the invention, the start-up is the one supplied by the converter AC voltage in the arrangement according to Fig. I is caused by the fact that only the rotary control 9 is adjusted <In Fig three-phase trapezoidal curve converter illustrated, and that is of simplicity assumed due to ohmic load. It can be seen that the alternating voltage is more similar This is regulated in the same way as in the case when two `` parallel '' in opposite directions Discharge paths with a clear current flow direction as a controllable alternating current resistance serve, d. H. when starting up, the alternating voltage is based on the iSo ° phase position built up in the leading sense across the phase positions ß1 and ß2. Is noticed still,. that when the converter is operated alone, it is advisable to use only the rectifier operation The control under consideration is influenced. For this, however, you have to have power gaps accept.

Another possibility of increasing the alternating voltage is to be explained with the aid of the circuit diagram in Fig. 2. which shows a simplified grid control compared to Fig. z. The control of the auxiliary discharge paths i o ', 10 ", 20', 20 ', 30', 30" by the further auxiliary discharge paths ioo 'and iöd' takes place in the same way as in FIG Auxiliary discharge sections iö; ih "etc: a control alternating voltage with a sharp or approximately sharp waveform supplied by the transformers, ii; 21 or 31; the control of the auxiliary discharge paths ioo 'and ioo" is simplified in that the grid transformer 103 already supplies a curve shape deviating from the sinusoidal shape. In this embodiment, as can be seen from Fig. 4b, each primary phase voltage involved in building up the desired alternating voltage is regulated. It is therefore initially desirable for the individual components of the grid control to be retained, but to be shifted in phase by amounts that are equal in time. The rotary controls 7 and 8 must therefore be coupled to one another, as is indicated schematically. It must be ensured that with a frequency ratio of 3: i, the rotary controller assigned to the higher-frequency network is equipped with a correspondingly higher number of pole pairs or, if the number of pole pairs of the two rotary controllers is the same, the clutch of the two rotors must be coupled via a transmission gear corresponding to the frequency ratio. From Fig. 4b it can also be seen that the build-up of the component of each phase voltage takes place from the iSo ° phase position in the leading sense over the phase positions β 'and β " Control effect as in Fig.2 (see Fig.4b) in that the shape of the grids i` and i ". etc. of the control voltages supplied to the main discharge paths is changed. The auxiliary discharge paths iö; io "ETC. supplied voltages for anode and grid circuit are separate rotary transformers 7 and 7 'removed, and there is the start-up of the AC voltage in the sense of Fig. 4b alone by moving the knob 7', that the rotary encoders 7 and 8 remain unchanged A coupling between these two rotary transformers is therefore not required here. With regard to Fig can be provided.

How the switch-off process and the restarting of the AC voltage take place will be explained on the basis of Fig.5, which essentially corresponds to Fig.3. Two control paths are assigned to each grid of a main discharge path, of which only the one for rectifier operation is numbered. If, for example, a violent overcurrent occurs, the low-frequency transformer 103 is saturated with the aid of current transformers 14, which are expediently switched into the three-phase supply lines of the converter, and one or more auxiliary discharge paths 15. As a result, the grids i ', i ", etc. of the main discharge paths no longer receive any pulses corresponding to the rectifier operation, but still receive pulses corresponding to the inverter operation, because the transformer corresponding to the transformer 103 becomes, as can be seen from the drawing , not saturated. Simultaneously with the response of the auxiliary discharge path 15 , as indicated by dashed lines, the drive 7 ″ of the rotary controller 7 'is controlled in the sense of a downward regulation so that the rotary controller receives the starting position required for start-up. In between, the auxiliary discharge path i5 is short-circuited by a self-holding relay, as a result of which the discharge existing there is interrupted, but the saturation of the transformer 103 is maintained. A pulse relay 16 is coupled to the self-holding relay and separates all control paths. After the interruption has taken place, the self-holding relay opens, and the saturation of the transformer 103 is thus canceled. In the meantime, the rotary control 7 'has reached its starting position and closes an auxiliary circuit, which in turn switches the pulse relay on again. The drive 7 ″ of the rotary control 7 'is acted upon, so that the alternating voltage can now be increased.

The above considerations relating to Fig. 5 require one Supplement for the case that the converter works in parallel with other energy sources. During the switch-off process, those corresponding to rectifier operation are removed Impulses like. above; but at the same time it must be ensured that the inverter = corresponding impulses may only continue to exist so long that the Half-wave of the alternating current flowing through properly reach the zero value can. For example, this can be done when using two multi-anode discharge vessels each with a mercury cathode, each assigned to a half-wave of the alternating current are to achieve thereby; that the cathode emission sustaining sub-arc circle interrupts. If you were to let the inverter operation continue, this would generally be an energy supply from the low-frequency single-phase network enter the higher-frequency three-phase network via the converter to be switched off. Otherwise, the further switching processes run until the saturation is canceled of Transformer 103; as already explained above. Whether the knob 7 'downregulates during the peeling process or does not matter here, because after unsaturation of the transformer so is the grid control first with its secondary parts, including the rotary controls, so that the from The voltage supplied by the converter and the mains voltage are synchronous, d. h: regarding ° Match size and phase. Only when the synchronization process is finished The converter can be switched on with the aid of the pulse relay 16. ' It is recommended, in addition to the instant shutdown in the event of severe overcurrent to provide for such a regulation; that if the nominal current limit is exceeded slightly depending on the current, the voltage supplied by the converter is regulated down by man`-acts in a corresponding way on the drive-of the rotary control (s) ..

It follows that in normal operation. the desired Waveform of the alternating voltage is ensured, but when: -or if the nominal current limit is exceeded, a deformation. the voltage curve entry.

Claims (7)

PATENT CLAIMS -1. Procedure for the selective shutdown of parts a network made up of converters; with grid-controlled vapor or gas discharge sections is fed, with the overcurrent occurring in the event of disturbances blocking the grid of the converter effected without delay; characterized in that after some Half waves the. The grid lock has been lifted and the operation is steadily increasing Grating is continued; being the selective shutdown of the sick Power supply takes place in cooperation with the power switches. 2. The method according to claim z for converting, the main discharge paths of which are controlled via each, a group of grid-controlled auxiliary discharge paths (see above; 20, 30) for rectifier or inverter operation. Each group is preceded by a further auxiliary discharge path (zoo), the grid of which is a low-frequency control voltage taken from another rotary regulator. is fed to a substantially rectangular curve shape, characterized in that; that in the event of malfunctions of the transformer, the control voltage of the group of auxiliary sentladungsstrecken for rectifier operation upstream further. Auxiliary charge path supplies; With the help of current transformers connected to the three-phase current supply lines of the converter, saturation is achieved so that at the same time the rotary control supplying the higher-frequency or low-frequency voltages for the auxiliary discharge paths is immediately brought into the starting position and, when it is reached, automatically acts on the auxiliary circuits, which release the control paths and the rotary control Immediately influence it in such a way that the voltage is gradually increased again. 3. Arrangement for carrying out the method according to claim 2, characterized in that the Current transformers affect the grid circle of an auxiliary discharge path (15), at whose discharge start switched on the transformer saturation and then through a self-holding relay short-circuiting the discharge path is maintained; with: to which a control path opening pulse relay (i6) is coupled. 4. Arrangement for carrying out the method according to claim 2 or 3, characterized in that that auxiliary relays are provided, which after interruption of the control path through the pulse relay (16) interrupt the self-maintenance relay and thus the transformer saturation current circuit to open; before the rotary control has reached the starting position. 5. Procedure according to Claim 1 or the following, characterized in that both the grid and Anode voltages for the auxiliary discharge paths controlled by the higher frequency supplying rotary controls as well as the low-frequency control voltages for the other auxiliary discharge lines are brought to their starting position and then operated jointly in the sense of a start-up, 6. Arrangement for Implementation of the method according to claim 5, characterized in that the two Rotary control directly or via a 'gear ratio' corresponding to the frequency ratio are coupled to one another and that the rotary control assigned to the high-frequency network equipped with a higher number of pole pairs corresponding to the frequency ratio is. 7. Arrangement for carrying out the method according to Claims 1 to 4, thereby marked, that for the delivery of the auxiliary discharge paths controlled by the voltage of higher frequency supplied grid or anode voltages separate rotary controls are provided and that in the event of faults only the one delivering the grid voltages of the auxiliary discharge path Knob is turned down and then turned up again. B. Arrangement for implementation of the method according to claims i to q., characterized in that in the grid circles those provided in each control path, controlled with low-frequency voltages Auxiliary discharge sections, a further auxiliary discharge section is provided in each case, their grid and anode voltage to the low-frequency one via separate rotary controls Network is taken, and that only the grid voltages of this additional in the event of interference Control dials supplying the auxiliary discharge path down and then up again will.