DE703095C - Device to facilitate commutation in discharge vessels with vapor or gas filling and extinguishing grid control - Google Patents

Description

Device to facilitate commutation in discharge vessels with steam or gas filling and extinguishing grid control The invention relates to a device to facilitate commutation in discharge vessels with vapor or gas filling and grid control. It's lately. special grid structures, so-called extinguishing grids, which make it possible to prevent the burning arc to extinguish arbitrarily at any time by electrical influence in discharge vessels, without having to wait for the natural zero crossing of the anode current. With such Devices can generate leading reactive currents when the rectifier is operating, so that these facilities when connected to AC networks with lagging current the network and the other existing reactive power generators (generators, synchronous compensators, static capacitors).

If the anode current is prematurely extinguished, step through the extinguishing grid large overvoltages due to the leakage reactance of the transformer winding, which impair the proper functioning of this extinguishing grid. As a result of these surges can e.g. B. except flashover in the system also on the grids themselves inter-cathode spots be formed so that direct ignitions take place on the extinguishing grid, whereby their effectiveness is canceled. One has tried to fix these surges by attaching of capacitors e.g. B. to eliminate or between two peeling anodes to limit at least to permissible values. Because these capacitors are large in size received, their use means a considerable increase in the cost of the system.

According to the invention, the overvoltages that occur are reduced to one Fraction reduced and special capacitors as a result dispensable made that the secondary winding of the anodes of the discharge vessel feed Transformer is connected in polygon finitely led out star point, wherein each side of the polygon is formed from two or more partial windings,.: their Connection points are led to anodes with extinguishing grids, and that also the "DF windings on the pillars of the transformer are arranged so that the leakage reactance between the secondary partial windings and the primary winding small, the capacitance between the partial windings is large: Examples are shown in the drawing of the invention schematically in Fig. i and 4 with rectifier discharge vessels Mercury cathode shown, the Fig.2, 3 and y show the winding map Secondary winding of the transformer designed as a cylinder winding according to Fig. i. 6 to 5 show diagrams of the svorgangs occurring during a commutation Currents based on the substitute scheme Fig. 9.

In the figures, a denotes the discharge vessel with the mercury cathode b, the anodes c and the extinguishing grids cl in front of them. The sides of the polygon, e.g. B. AB or: 11-B1 (Fig. I), are divided into four partial windings i to, 1, which are connected in series and at their connection points A to E or. A1 to El the anodes c are connected. The number of partial windings is expediently dimensioned in such a way that the phase angle formed by the end points of each partial winding and the star point is smaller than ``. [edr partial wrap; can consist of 3 or more coils. The 2.1 anodes to be fed from the transformer can be distributed over two or more discharge gradients. Each of the partial windings i to q. Of each polygon side is arranged on the columns of the transformer in such a way that the leakage reactance between them and the primary winding (not shown) is small, however, the capacity between the partial windings is large.

At the moment when the connection point D! lying anode the current should take over, the associated grid receives a positive impulse, while the Lattice of the anode to be erased, located at connection point C, is negatively charged will. If one thinks of the distributed capacitance between the partial windings 2 and 3 concentrated in a capacitance i ¢ (FIG. 9) between the connection points C and Di, occurs at the moment of the blocking of the anode lying at connection point C. Current from partial winding t and 2 via this capacitance to the receiving anode at the connection point D- over, which is also fed directly from the partial winding 3. The partial winding 2 is during the short moment, since the lying at the connection points C, L @ Anodes burn at the same time, short-circuited; the current direction of this partial winding 2 is then reversed, this process by discharging the capacitance between C and D- is significantly accelerated.

This effect can be seen more clearly when looking at the processes 6 to B. As FIG. 6 shows, at time x the am Points D, connected anode power on. It is from the partial winding E, L: or 3 fed directly and from the partial winding A C or i against the capacitor 14, and its current 23 thus rises to the direct current assumed to be constant, which is reached at time @. The grid of the anode connected to point C. is blocked at time x, so that the current 12 of this anode is within the interval a_,, 3 decays The sum of the anode currents within this interval is here constant equal to the direct current delivered at the cathode. The currents in the partial windings result from Fig.; where, for the sake of simplicity, is aigenomines that the A and E flowing currents i and 3 within. of the entire considered time interval, d. H. remain approximately constant during the entire commutation process, strictly speaking, only their sum remains constant.

The current in the partial winding 2 commutates within the time interval x, Y, the current change occurring more rapidly from the time @ onwards, since the entire current flowing from the partial winding A, C or i is now. Current of the anode connected to D is delivered. The resulting current in capacitor 14 is shown in FIG. B. The commutation of the current therefore only takes place in partial winding C, D, or 2, since the current direction in partial windings A, C or i or E during the entire commutation process , Dl or 3 remains unchanged. In this way, the leakage inductance of the entire winding A, B in FIG. B. C, D !, the same effective; ie in the place of a current; A turn with a large inductance occurs several current turns with a correspondingly lower inductance, as a result of which, instead of one overvoltage surge, several surges with a much smaller amplitude occur, which results in less stress on the insulation.

In the manner just described, after '/ 24 the period at the connection point D: lying anode replaced by the anode lying at connection point F.

For the purpose of mutual decoupling of the individual coils of the partial windings and the coils are used to extend the spreading path. of the partial windings over distributed along the entire length of the column. To at the same time the capacity between two to increase detaching anodes and thereby reduce the residual overvoltages at the same time those working one after the other and lying on the same transformer column Part windings are mixed with one another. A good mix can be z. B. achieve that the four partial windings i up to the entire length of the column be designed as a multi-concentric cylinder winding, for reasons uniform voltage distribution between the upper end of a partial winding and the lower The beginning of the next following is connected, as shown in FIG. To this In addition to reducing the leakage reactance in the turning circle, this is also wise the leakage reactance between the partial windings and at the same time a considerable Increase in capacity between the individual partial windings achieved what a smooth handling of the commutation process is an advantage. The four partial windings a _ polygon side can also be broken down into winding sections (coils) and the Winding sections (coils) of at least two parts of this polygon side , mixed in on the same diameter on the same column of the transformer: be arranged with each other. In Figure 3 the four partial windings are mixed in on the same diameter. The reduction of the leakage reactance of the peeling off The larger the phase, the more it appears through the polygon circuit used phase number. As a common 6-phase polygon circuit, the Stray reactance reduced approximately in the ratio i: 2 compared to the star connection. When using 24 phases according to the example Fig. I, the leakage reactance is im Turning circle compared to star connection to about. 1/2. (1 / .l) 2 = 1 / s2 = 3% reduced.

Fig. ¢ shows an embodiment of the circuit of the secondary winding of the transformer for a 36anode operation, where z. B. two discharge vessels with 18 anodes each can be used. The specified polygon is derived from a normal 6-phase polygon in such a way that the windings of the individual polygon sides are lengthened by a certain amount beyond the corner points of the hexagonal polygon. Each polygon side A, B consists of the partial windings i to 6. It is readily apparent that a similar polygon, as shown in FIG. 2, can also be developed for 24 anodes in place of the circuit example given in FIG.

In Figure 5, the execution is as a further embodiment of the invention of the secondary winding is shown as a multiple spiral winding. Here is also aims to increase the capacity between the detaching anodes, i.e. also between the successive partial windings of the same column as large as possible make by the turns of these partial windings coil by coil in the same winding plane are arranged and wound in the order of the partial windings. A further increase in capacity results from the fact that these turns from wide. thin copper tape and wrapped flat. You can finally get the copper cross-section of the partial windings in several parallel-connected partial cross-sections with the same Subdivide the bandwidth and reduced thickness and parallel the resulting coils switch, whereby the capacity is increased in proportion to the subdivision.

5 shows such a spiral winding with four partial windings per polygon side and three turns each. for each coil and partial winding, with two parallel branches in each partial winding. The partial windings i to ¢ each polygon side of the secondary winding e, z. B. AB and A, -B, (Fig. I), are divided into two parallel-connected coil pairs f1, f2 and f ", /1.2 or g1, g2 and all, g12, the coils of the coil pairs are connected in series. The coils are made of flat copper in multiple spiral windings with three turns per coil and each part winding so that the turns lie on top of one another in the order of the part windings. One coil of each coil pair is wound from the outside in, the second from the inside out. so that the connections of the coils come to lie on the inside and the connections A to B on the outside. The winding connections and the coil connections are only drawn on the coil pairs f), f2 and f ", f12, they are for g), b 2 and g) ), g, 2 exactly the same. These pairs of coils on the opposite sides of the polygon are arranged with the pairs of coils ftl, Jt2 and h "/ t" of the winding of the diagonal XY (FIG. I) along the transformer column of the primary winding i, distributed and mixed with one another. The coils of these coil pairs ftl, h2 and ltll, h12 are also wound from flat copper as spirals and connected in series, but are not subdivided. The coil pairs of the three windings of a column are now grouped mixed with one another in such a way that a coil pair of the polygon side AB with a coil pair of the polygon side A, -B ,. and one of the diagonals XY follow one another in the order as shown in FIG.

The transformer circuits specified in the exemplary embodiments do not represent an exact 24 or 36 phase system, because the individual phase angles own different size. However, the unequal phase angle is essential for operation of the discharge vessels is not a disadvantage, but it is a disadvantage for those in the transformer connections to be carried out a considerable simplification, since the connections of winding parts of different legs are reduced to a minimum. The successive sections can be designed with the same number of turns will. The advantages of the small leakage reactance of the turning circle and the large capacity The alternating phases can of course also be made with circuits of exact multiphase polygons can be achieved in which both the lying between the individual tapping points The voltages and the individual phase angles are the same.

Instead of a cylinder winding, the transformer winding can also be used as a Disc winding are carried out. It is advantageous to have the primary winding such To switch transformers in delta.

Claims (3)

PATENT CLAIMS: 1. Device to facilitate commutation in discharge vessels with steam or gas filling and extinguishing grid control for the Voltage regulation and improvement of the power factor, characterized in that the secondary winding of the transformer feeding the anodes of the discharge vessel is connected in polygon with lead out star point, with each side of the polygon is formed from two or more partial windings, their connection points to anodes are performed with extinguishing grids, and that also the partial windings on the pillars of the transformer are arranged so that the leakage reactance between the secondary Part windings and the primary winding small, the capacity between the part windings is great. 2. Device according to claim 1, characterized in that each partial winding each side of the polygon is distributed over the entire length of the column of the transformer. 3. Device according to claim 2, characterized in that the transformer winding is designed as a disc winding or as a cylinder winding. 4. Set up after Claim 3, characterized in that the partial windings of a polygon side as concentric cylinder windings arranged on the same column of the transformer are. 5. Device according to claim 3, characterized in that the partial windings each side of the polygon are intermingled on a column of the transformer. 6. Device according to claim 5, characterized in that the partial windings one Polygon side divided into winding sections and the winding sections of at least two partial windings of this polygon side on one and the same diameter the same column of the transformer are arranged mixed with one another. 7th Device according to Claims c to 5, characterized in that the connection points the phase angle formed by the partial winding of a polygon side with the star point is smaller as '-' is. 3 B. Device according to claim 1 to 7, characterized in that the secondary winding is designed as a spiral winding, so that each coil is the same many ! Turns of the partial windings working one after the other of the same Column, the turns in the order of the partial windings and in the same winding plane lie on top of one another. 9. Device according to claim 8, characterized characterized in that in order to increase the effective capacity, the spiral winding off made of flat-wound copper tape as large as possible and as thin as possible will. i o. Device according to claim 9, characterized in that for the purpose of increasing the effective capacitance each partial winding made up of two or more parallel-connected Windings with a correspondingly smaller cross-section, but the same bandwidth will be produced.