DE290457C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

Vr 290457 - CLASS 21g \ GROUP

SIEMENS-SCHUCKERT WERKE G. m. B. H. in SIEMENSSTADT b. BERLIN.

are switched on.

Patented in the German Empire on April 26, 1914.

In order to be able to operate metal vapor rectifiers in parallel, it is well known that Devices are provided which regulate the power distribution to the individual devices in the correct ratio. the The present invention relates to such a device.

To ensure correct current distribution to the parallel working anode branches of several

to reach ίο metal vapor rectifier, has been f is constant in the circuit of these branches or approximately constant impedances (choke coil) is turned on. The larger voltage drop occurring at the ends of such choke coils when there is a stronger passage of current causes in these arrangements that, with correct dimensioning, the

■ Choke coils distribute power to the individual Anode branches automatically in relation to the performance of the parallel connected Apparatus regulates. The parallel working anode branches of different metal vapor rectifiers can also be magnetically linked to one another to achieve correct power distribution, in such a way that that with correct current distribution in the individual branches there is no throttling is, however, a corresponding throttling when the current in a branch increases occurs in this branch.

According to the invention, the correct current distribution on two or more working in parallel Anode branches of various metal vapor rectifiers are regulated by the magnetic resistance of the in the anode circuits of a metal vapor rectifier switched on choke coils is enlarged in the normal operating range, if the of the direct current supplied to the direct current network by the other metal vapor rectifier is greater will, and vice versa. Such arrangements offer the advantage that in the normal operating range, in spite of small throttling in the anode branches, the regulation can be made very sensitive, and that furthermore for throttling the anode branches and maintaining direct current in the Cathode branches choke coils with a common iron core can be used.

Fig. Ι shows an embodiment of the invention. The direct current network N is fed with direct current by two mercury vapor rectifiers G ¹ and G ⁿ which work in parallel and which receive alternating current from the transformer secondary winding of a transformer T. To regulate the current distribution to the individual anode branches of the two mercury vapor rectifiers, two choke coils D ¹ and D ^{n are} provided according to the invention. Each of these inductor coils has four inductor windings Y ₁ , S ₁ and r _2> S ₂ or V ₁ , W ₁ and v _v W _{2 located} in the circuit of the anode branches A ₁ , A ₁ or B ₁ , B _{2 of the} same mercury vapor rectifier . Also owns

each choke coil also has a winding η or in through which the direct current of the other mercury vapor rectifier flows and which is arranged in such a way that the alternating force flow of the anode choke windings essentially does not pass through this coil.

To explain the mode of action, it should be assumed that we have two equal Apparatus have to do. The direct current windings on the individual choke coils are expediently adjusted so that the magnetic direct current induction during normal operation is near the knee of the iron's magnetization curve.

Any change in the strength of a metal vapor rectifier connected to the DC network supplied direct current caused as a result of the increasing or decreasing iron saturation a change due to the superimposed direct current lines of force in this arrangement the magnetic resistance of the anode branches of the other metal vapor rectifier upstream choke coil. An increase in the direct current emanating from the cathode of one apparatus increases the magnetic resistance in the anode branches of the other apparatus lying choke coil and reduces its impedance or that at the ends of this Choke coil with constant current passage occurring voltage drop. Through this if the second metal vapor rectifier is triggered in a double sense, in turn to participate in the supply of electricity to the direct current network. Because every enlargement of the The current delivered by the first apparatus to the direct current network has a larger current Voltage drop across the series reactor of this apparatus and a reduction in size the voltage drop across the series reactor of the second apparatus.

The shape of the iron core of the choke coils D ¹ and D ^{n shown} in FIG. 1 prevents the anode branches of one metal vapor rectifier and the choke windings connected in the direct current circuit of the other apparatus from influencing each other. Another choke coil serving to smooth the direct current can be dispensed with if the choke coils D ¹ and D ^{n are} suitably dimensioned, as already mentioned.

If more than two metal vapor rectifiers are to work in parallel, then, as FIG. 2 shows, the direct current supplied by a rectifier can be fed via the direct current windings to the choke coils of two other apparatuses. The individual choke coils are expediently equipped with two windings carrying direct current η ¹ , 1η ¹ or _:

n ¹¹ , m ¹¹ , etc., which are traversed by the currents of two other metal vapor rectifiers. Devices can be provided which prevent the superimposed direct current lines of force in the individual choke coils from decreasing too much during normal operation if one or more metal vapor rectifiers are not switched on. For this purpose, only the second direct current windings on the choke coils, which are intended to receive the current of the metal vapor rectifier which is currently out of operation, are allowed to flow through the current of any other metal vapor rectifier in operation. It is not necessary for the two DC windings of a choke coil to be excited by the current of two different apparatuses.

Fig. 3 shows an embodiment of the invention in which two three-phase rectifiers work in parallel on a direct current network. The influence of the magnetic resistance of the multiphase choke coil D ¹ or D ⁿ _{connected to the anode branches of one apparatus by the current g 0} delivered to the direct current network by the other metal vapor rectifier G ⁿ or G ¹ takes place in this arrangement through a winding η or 111 on the bridge] och the polyphase inductor. Each anode branch A ₁ , A ₂ , A ₃ or B ₁ , B ₂ , B ₃ leads here, analogously to the single-phase arrangement of the inductor coils in FIG. 1, via three windings q _lt g ₂ , q ₃ and T ₁ , r ₂ , r ₃ etc. on separate iron legs k _lt k ₂ , k ₃ or K ₁ , K ₂ , K _{3 of} the series choke coil, which are arranged in such a way that they create an alternating force flow in the direct current of the other metal vapor rectifier Do not allow winding η or m.

Instead of multi-phase reactors, multi-phase rectifiers working in parallel can be used Of course, several single-phase choke coils can also be used as shown in FIG.

Claims (4)

Patent Claims: 1. Device for parallel operation of several metal vapor rectifiers, at those to improve the parallel operation choke coils in the AC supply lines are switched on, characterized in that the impedances of these inductors in the opposite sense change like the strength of one or more other rectifiers working in parallel to the direct current network Currents. 2. Facility for parallel operation several metal vapor rectifiers according to claim i, characterized in that the change in the impedance values of the individual choke coils due to the superposition is caused by direct current lines of force, which is caused by one or more windings on the individual choke coils are generated whose DC excitation currents either from the to the ίο DC power supplied by one or more other currents that work in parallel Rectifiers are dependent on or are identical to these currents. 3. Device for parallel operation of several metal vapor rectifiers after Claim 2, characterized in that the iron cores of the individual throttle »Reel except for those switched on in the anode branches Windings still excited one or more of the direct current from other rectifiers working in parallel Windings are applied and arranged such that a mutual transformer Influence of the windings of the anode branches and the direct current windings practically avoided will. 4. Device for parallel operation of several metal vapor rectifiers for Multiphase current according to Claim 1, 2 or 3, characterized in that in the Anode branches of each polyphase rectifier are turned on are, whose iron core shapes and winding arrangements the creation of an alternating force flow in the vom Virtually exclude direct current excited windings. . 1 sheet of drawings.