DE339182C - Process for voltage regulation of metal vapor rectifier systems with the help of inductors connected to the circuit of the anodes - Google Patents

Description

Choke coils are often used in the anode circuit of metal vapor rectifiers switched on, which either serve to extinguish individual arcs in rectification-S ter or an even load of anodes or rectifiers working in parallel to achieve.

It is now an object of the present invention to provide these reactors for a further purpose

ίο to make subservient, namely the voltage regulation of the rectifier systems. In general, these reactors are not well suited to regulating the voltage of the rectifier lying network, as their tension

is just a function of the current, namely of the anode current, which is a partial current of the main current drawn from the rectifier is. If one wanted to make the voltage regulation as independent as possible from the main current, one would have to have the influence of the the load of the variable main current on the voltage drop through the choke coil limit by "dimensioning them in such a way that they are even with a small number of turns and a small value of the main current is in a highly saturated state. In this case you would get relative large current range an almost constant, proportional to the number of turns of the choke coil Voltage drop, so that you can change the voltage of the rectifier network by changing could regulate the number of turns of the inductor in the desired manner. This rule would be but only imperfect for several reasons, since the turns off only a gradual and intermittent regulation of the voltage is permitted and independence the voltage of the load on the way of the saturation by the main current itself can only be reached imperfectly. Probably this is especially true for polyphase rectifiers, where the anode current is the 1, the conditions are more favorable than in the case of a sinoidal course of the current curve, because the instantaneous rise of the current to almost its amplitude value is the Influence of saturation favors, but in reality it occurs nevertheless under the influence of Inductance of the circuit a certain flattening of the current curve, and thereby the dependency of the throttled voltage on the load current is not completely eliminated.

According to the present invention, however, the voltage regulation should not be influenced of the main current, but by one fed by a constant direct current source additional excitation winding take place. For this, these are due to wave current fed choke coils the conditions are particularly favorable, as the shaft current magnetized only in one sense and the. DC excitation can be set so that that it works in the same way. One must, however, the reaction of the alternating current to eliminate the DC excitation by special means, e.g. B. by switching on a self-induction in the DC exciter

circle. While now in general the introduction of an AC-fed choke coil with a superimposed direct current field in alternating current systems, the installation of a special one DC source, so a complication and increase in the cost of the system required makes, this can be dispensed with in rectifier systems if one according to the invention uses the rectifier voltage itself for its own regulation. Herein lies a special one Advantage of applying this principle to rectifier systems.

Accordingly, the subject matter of the invention is a method for voltage regulation of metal vapor rectifier systems with the aid of choke coils connected to the circuit of the anodes, according to which each choke coil is excited by a direct current voltage in the same sense as by the anode current and the rectifier voltage is regulated by regulation this DC excitation takes place. With this regulation it is advantageous if the choke coils are close to their saturation state even with relatively small anode currents. In Fig. 2, F denotes the field curve of the choke coil, AWa the exciting ampere-turns through the anode current. For a specific current and a specific number of turns Z _{1 in} the choke coil, let AWa = 0 a. This number of ampere-turns would correspond to the field .F ₁ , and the EMF induced in the choke coil is proportional to the expression F ₁ · Z ₁ . If you now generate the direct current field Fg- in the choke coil by a constant direct current excitation AW _g , when the ampere turn AWa is added the resulting field will _{only marginally exceed the value F 1} because of the saturation, and it will be the value / 4TTg- + AWa = oa! corresponding field Fg- + Fi 'almost = F ₁ , whereby the EMF induced in the choke coil only corresponds to the expression Fv · Z _1. The addition of a relatively small direct current excitation thus causes a very considerable change in the inductor voltage and thus the overall voltage is regulated. Because of the high saturation, the increase in the anode current has no significant influence on the voltage conditions.

In Fig. 3 an arrangement suitable for single-phase current is shown, on which the method is to be explained. T means a single-phase transformer with the primary winding P and the secondary winding S. The anode currents fed to the rectifier G are taken from the terminals I and II of the secondary winding. These flow through the windings Z ^ ₁ and Za, the choke coils D ₁ and D ₂ to the anodes A ₁ and A _{2 of} the rectifier G, the cathode K of which feeds the + conductor of the direct current network N,

while the head of this network with the

The center of the secondary winding 5 is in a conductive connection. The two choke 6g coils D ₁ and D ₂ are now also excited according to the invention by a winding Zg ₁ and Zg ₂ , which are fed from the network N via the self-induction L and the regulating resistor R in series, and which the choke coils in the same Senses like Z _Al and Z _A “ excite. In order to regulate the voltage of the rectifier and therefore also that of the network N , the contact C of the regulating resistor R is adjusted in the desired sense. The inductor voltage is thereby increased or decreased, and since it is connected in series with the transformer voltage, the mains voltage is correspondingly decreased or increased.

This method adheres to the use of a special choke coil for each anode nor the great disadvantage that the choke coils are relatively large, because only during a fraction of a period the anode current flows. A significantly better use of the Choke coil is obtained if you place one of the anodes of different phases in groups Assigns a choke coil, it being advantageous if the phases of each group are the same in time Have a distance. The method then consists in that each associated with a choke coil Secondary phases of a transformer feeding the rectifier in groups of at least two phases excite the inductor in the same sense, and that at the same time the Choke coils excited by a direct current in the same sense as by anode current and the regulation of the rectifier voltage by regulating this DC excitation he follows.

4, which relates to a three-phase system, serve for explanation. It means N _w a three-phase network, T a trans-. formator with the primary winding P and the six-phase secondary winding S. The terminals of the six phases are labeled I, I ', II, II', III, III '. Lines lead from them via the excitation windings Za ₁ , Za ₁ ; Z _An , ZA _n ; Za ₁ R, zaxu; the choke coils D ₁ , D ₂ , D ₃ to the anodes Aj, Aj>, Aq Ar; Am, Am · of the rectifier G, the cathode of which is connected to the + conductor of the direct current network N _e . The —conductor of the network N _g is connected to the zero point ο of the secondary winding S. From the excitation windings Z _Al , Za ^ ■ · · · lie

Zai and Zai ' on the choke coil D ₁ and excite it in the? same sense, -.

ZyIj ₁ and Za # on the choke coil D ₂ and excite it in the same way,

ZyI ₁₁₁ and ZyI ₁₁₁ / on the choke coil D ₃ and excite them in the same sense.

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The choke coils D ₁ , D ₂ , D ₃ are therefore each assigned to a group of two secondary phases, the vectors of which are offset from one another by 180 °. To regulate the voltage, the choke coils also carry the DC _exciter windings Z _{Bv Zb 1} and Zb ₃ , which are connected in series and via the self-induction L and the regulating resistor 2? connected to the DC voltage of the system

to are. The direct current excitation is supposed to magnetize by the anode currents in the same sense as the excitation. By operating the regulating resistor R , the rectifier mains voltage is regulated accordingly.

The method described also allows compounding of the in a simple manner Rectifier voltage when you put the reactors apart from the DC voltage also from the main current of the rectifier also in the same sense as from Anode current excited. This results in an automatic increase in the direct current pre-excitation of the choke coils as a function of the main current, so that when the choke coils are highly saturated, the induced E. M. K. the choke coils decreases with increasing load. But this takes the Rectifier voltage in a corresponding manner, and the increase in the voltage drop is compensated for by the compounding.

A compounding is explained by Mg. 5a, but this is also explained in a different way differs from the example of FIG. Namely, while in Fig. 4 each anode current a phase group an excitation coil located on the associated choke coil flows through, is in Fig. 5a on each choke coil only a single excitation coil for the Anode currents present, which are the anode currents that do not coincide in time of the group concerned. This simplification is achieved in that each secondary phase group receives a special zero point and these group zero points Via one excitation winding each of the associated choke coils to the common zero point of the secondary system. In Fig. 5 a thus means

N _n , a three-phase network,

T a transformer with the primary winding P and the six-phase secondary winding 5.

Of the six phases, phases I, F form a group with the zero point O ₁ , II, II 'a group with the zero point O ₂ and III, ΙΙΓ a group with the zero point O ₃ . Lines go from these zero points _{O 1} , O _{2 and 3} via the excitation windings Za ₁ , Za., And Za ₃ , which are each located on a choke coil, to the common zero point O of the secondary system.

From 0 the connection line goes to the —conductor of the direct current network Ng- via the main current exciter coils Zh ₁ , Zh ,, and Zh. ,, which are connected in series and which magnetize the choke coils in the same way as Za ₁ , Za., Or Za ₃ - carry the choke coils but also the DC exciter windings Zb ₁ , Zb., _{and Zß 3} , which also generate DC fields in the same sense as Za ₁ , Za _% and Za ₃ . The series-connected direct current excitation coils Zb _1, Zb., Zb and ₃ are connected to the voltage rectifier, and in this circuit is for damping the self-inductance L and switched to regulate the regulating resistance R. The compounding is also made adjustable by means of the controllable resistor w . Instead of the magnetically separated three choke coils D ₁ , D ₂ and D ₃ of FIG. 5a, a common iron core according to FIG. 5b can also be used for the anode currents if a fourth leg is provided on which the DC excitation coils Zb and Zh sit which both magnetize in the same way as the excitation coils Za ₁ , Za, and Z ^ ₃ sitting on the three parallel legs - the number of excitation coils is smaller here, but the magnetic structure is less simple.

In the case of the multi-phase system, a further simplification is possible if you look at the number of the choke coils used by reducing the number of secondary phases as large as possible for each group, i.e. the number of groups as small as possible. if if the number of secondary phases is numbered in cyclical order, the result is the minimum in groups, when you put the even-numbered phases into a group, the odd-numbered ones Combines phases into a second group. (Summing up all phases too a single group is ruled out because then the excitation coil for the anode current is not of wave current, as it is necessary for voltage regulation, but instead of a direct current would flow through it.) The two Groups formed in this way are each assigned a choke coil, as shown in FIG. 6 and 7 show. In each group the time interval between neighboring phases is the same, so that the wave currents of the individual excitation coils have a regular periodic course have (see Fig. 6 a).

In Fig. 6, N _w again means a three-phase network,

T a three-phase transformer with the primary winding P and the two secondary winding groups S ₁ and S ₂ , of which S _{1 contains} phases I, II, III, S _2, on the other hand, phases I ', II' and III '. The phases of group S ₁ have the zero point O ₁ , those of group S ₂

the zero point o ₂ . Choke coil D _{1 is} assigned to group S ₁ , and choke coil Z) _{2 is} assigned to group S _2. While the external terminals of the secondary phases are now connected to the anodes of the rectifier G , the zero points O ₁ and O _{2 are brought together} via the excitation coils Z ^ ₁ and Z4 to form the common zero point 0 of the secondary system. The zero point ο is connected to the conductor of the direct current network via the main current exciter coils Zh ₁ and Z / j connected in series. The DC excitation coils Zb ₁ and Zb ^ are again connected in the previously described way to the voltage of the rectifier and permit the regulation of this voltage with the aid of Regulierwiderstandes R. On the choke coils D ₁ and D ₂ but are still one further coil Z is _Cl or Z _c , indicated, soft connected to one another

ao and represent an electrical interlinking of the choke coils. They serve that To influence voltage at the electrodes of the rectifier in such a way that an unequal Current distribution to the two groups and extinction of the arc of one phase is avoided.

In action. 7, finally, the two groups S ₁ and S ₂ only have the common zero point o, but, as before, phases I, II, III and Γ, Π ', ΙΙΓ are assigned the choke coils D ₁ and D ₂ , which in this case each carry three excitation coils acting in the same direction for the anode currents. In this case it is shown in FIG. 7 it is possible to give the two choke coils a common DC exciter coil, in which the E.M.Ke. almost cancel. The early saturation of the choke coils plays an important role in the control method described b: as this prevents the main current from having an undesired influence on the regulated voltage of the direct current network in the large load range.

Claims (7)

Patent Claims: r. Procedure for voltage regulation of metal vapor rectifier systems with the help of inductors connected to the circuit of the anodes, characterized in that, that every choke coil, except through the anode current, through a direct current in the same sense as from the anode current is excited, and that the voltage regulation of the network connected to the rectifier by regulating this DC excitation he follows. 2. The method according to claim i, characterized in that the DC excitation voltage the voltage of the rectifier itself is used. 3. The method according to claim 1 and 2, characterized in that the scheme the DC excitation takes place at choke coils, which are already at relatively small Excitation currents are in a state of high saturation. 4. The method according to claim 1 to 3, characterized in that the in groups secondary phases of at least two phases each associated with a choke coil the transformer feeding the rectifier excite each inductor in the same sense, that at the same time each inductor by a direct current voltage in the same Senses is excited, and that the regulation of the rectifier voltage is carried out by regulating this DC excitation. 5. The method according to claim 4, characterized in that the regulation of the DC excitation is carried out on reactors belonging to different phase groups, which are electrically linked to each other, 6. The method according to claim 4, characterized in that each of a group associated secondary phases receive a common zero point, and that the current flowing to each of these zero points goals excitation current for the anode current excitation the associated choke coil is used. 7. The method for voltage regulation according to claim 1 to 6, characterized in that that apart from the anode current and the controllable direct current excitation there is one with these excitations in the same sense effective excitation is used by the rectifier main current. For this purpose ι sheet of drawings.