DE631299C - Arrangement for grid control of a multi-phase rectifier or inverter operated with synchronous isolators and vapor or gas discharge paths - Google Patents

Description

When converting very high DC voltages (greater than 50 kV), one turns with advantage synchronous separators in the main circuits of the steam or gas discharge lines at. These synchronous separators are switching drums that operate normally during the passage of current through the discharge paths Do not influence operation - the commutation processes are then exclusively caused by the vapor or gas discharge paths - but during the blocking period the otherwise positive or negative reverse voltage on the vapor or gas discharge paths turn off or reduce to an approximate value. For grid control of multi-phase rectifiers or inverters operated with synchronous isolators and steam or gas discharge paths there are now some peculiarities.

On the one hand, the provision of the individual control voltages (preload and AC voltage) difficulties, since the switching arrangement is generally such is that the individual discharge paths are neither common anode nor common Have cathode potential, on the other hand, for reasons of operational safety, a Monitoring of the grid control by the functioning of the synchronous separator or a Monitoring of the functioning of the synchronous separators by the grid control is desirable.

The present invention relates to such a converting device with synchronous separators and grid-controlled discharge paths, which are preferably arranged in a Graetz circuit, in which the grid control by special shift drums, which are in a rigid phase relation to the in synchronous isolators are brought to the main circuits; this solid relationship can be done in a simple manner by providing a common drive motor for synchronous separators and grid control rollers can be guaranteed. It is noted that with Conversions with very high DC voltages per se also include other known circuits could be used, but the Graetz circuit is preferred because it makes the most efficient use of the Main transformer results.

The invention relates to a special design of these lattice circles and the Control in such a way that the individual discharge paths are essentially only obtained a blocking potential for a short period of time which is essentially the commutation time at the end of the current carrying period of the relevant

*) The patent seeker stated as the inventor:

Dr.-Ing. Claus Fröhmer in Berlin-Siemensstadt.

charge path including the point in time at which the synchronous separator closes the anode circuit the discharge path opens, includes. Besides, -, according to the invention, an i ^ | short-term creation of a blocking potential jp Provided before the start of the current supply in order to ensure an exact discharge start. According to a further development of the Invention are for the supply of the short-term blocking voltages to the control grid two mutually exclusive control paths are provided. This comes first Line consider the arrangement of two separate control rollers for each control circuit, One of them is the control before, the other the control after the passage of current takes over, and the invention further provides that the necessary high blocking voltages taken from the two neighboring phases for the discharge paths of a phase will. The control rollers can, however, be used in a suitable manner for the discharge paths of the various phases are combined so that, for example, a control roller for the bias of all Discharge paths belonging to the same shaping device are provided, as well as a control roller for their subsequent blocking.

The idea of the invention should be based on the illustrations and an exemplary embodiment are explained in more detail.

In Fig. Ι of the drawing, the voltage curves e _x , 0 ₂ , e ₃ of phases 1, 2, 3 of the main transformer (Fig. 2) are shown. Of the discharge paths 10 'and 10 "connected to phase 1, each works during 120 ⁰ of e _t , namely io' during the positive half-cycle of e _1; 10" during the negative half-cycle of s _x (see Fig. 2 ). It results z. B. for the time t _x that the discharge paths 10 'and 30 "connected to phase 1 or 3 carry the current, namely the discharge path 30" has shortly before or shortly after the zero crossing of the differential voltage (03- ^ 2 ) takes over the current from the discharge path 20 ", depending on whether inverter or rectifier operation is present. At time i ₂ , the current is to be commutated from 10 'to 20'. To avoid another incorrect insertion of 10 ', the grid from 10 This can be achieved by applying a direct voltage, the production of which, however, encounters difficulties and high costs at high voltages, as are common in operation with synchronous isolators makes that shortly after t ₂ the synchronous separator 4 'relieves the discharge path 10' of the reverse voltage. It therefore only needs during the time t _x to t ₃ and given If necessary, in order to ensure the exact phase position of the restart, negative blocking potential to be applied to the grid of 10 ' _{during the time i G} to t _7.

This blocking potential, which is only temporarily supplied to the grids by means of the grid indexing rollers 4o ' _v ,' 4o '", 40 /' and 40 / ', which are basically designed like the Syrichron separators 4' and 4", can be seen in the neighboring phases. ι voltage curve of the three phases shown, it follows that in the time J ₁ to t _a, the voltage of phase 3, in the time t _e to t _7, the voltage of phase 2 runs negative against that of phase I. Therefore, only need The use of rotating switches for the grid control appears to be particularly favorable here, since a motor rotating synchronously with the mains frequency must be available to drive the main switching rollers This also has the advantage that when the network oscillates, the synchronism between the grid control and the main shift drums can never be disturbed, which is a great advantage for operational safety. How the circuit is expediently carried out in detail is shown in Fig. 2. On the left the normal three-phase Graetz circuit with the synchronous separators is shown, on the right the control roller arrangement for the grids, one each for blocking the passage of current in a discharge path. For the discharge paths 10 ', 20' and 30 ', the grid control rollers 40% and 4o'"are provided for blocking before and after the passage of current, respectively. For the discharge sections 10 ", 20" and 30 ", corresponding control rollers 40 '% and 4o""are available. In the discharge paths 10 ', 2o' and 30 ', the formation of the grid circles can be carried out in a known manner using S current limiting resistors 11, 12, 21, 22, 31 and 32, since the cathode potential is fixed. In the case of the discharge paths 10 ", 20" and 30 ", the anode potential can be used instead of the initially undefined cathode potential Advantageously, a series connection of capacitor 15 and Ohmic resistor 16 or 25, 26 or

35) 30 used. For the circle grid cathode Then, similar to the discharge paths io ', 20' and 30 ', resistances occur 13, 14, 23, 24, 33, and 34 are used.

The grid control described above can also be used for voltage regulation, particularly in the case of rectifiers. You then have to rotate synchronous separator and grid control rollers evenly against the mains voltages, z. B. by rotating the stator of the drive motor for all shift drums. If one adheres to the principle of avoiding particular negative bias voltages, one must also adjust the phase position of the terminals 1 ', 2! and change 3 'removed control AC voltages, including z. B. rotary transformers can be used. However, resistors 5 ', S "and 5'" connected in polygons can also be provided, if necessary using control transformers. With rectifier operation you can z. B. conveniently regulate the onset of each discharge in a range from 30 ° to 150 ^{0 of} the positive half-wave of the anode voltage.

Claims (4)

Patent claims: i. Arrangement for grid control of a multiphase, with synchronous isolators and Steam or gas discharge lines operated rectifier or inverter, in particular in Graetz circuit, in which the control of the grids is carried out by switching drums that have a rigid phase relationship are brought to the synchronous separators, in particular by means of a common drive motor for synchronous separators and grid control rollers, characterized by such a training ■ tion of the grid control that the individual discharge paths through the same only for short periods of time each Period are blocked, of which the · one before the end of the current passage begins and ends after the passage of current has ended, and any further time segment that may be present for the grid blocking each time before the current flow of the in the discharge path to be detached preceding the current conduction begins and in the one for the initiation of the discharge ends at a certain point in time. 2. Arrangement according to claim 1, characterized in that the discharge paths a phase before the start of the passage of current or when the current is terminated, negative to be supplied Control potentials can be taken from the following or the preceding phase. 3. Arrangement according to claim 1 or 2, characterized in that two mutually exclusive control paths are provided. 4. Arrangement according to claim 3, characterized by the use of two Control rollers for each grid circle. 1 sheet of drawings DUCKLED IN DEB