DE639532C - Device for achieving the same current consumption of the anodes of a polyphase rectifier, the number of phases of which is a multiple of 6 - Google Patents

Description

With two-phase connections of the supply transformers for mercury vapor rectifiers it has been shown that the two. Six-phase systems, which are offset by 30 el. degrees from one another tend to be unequal Take up partial loads. One reason for this lies in the harmonic harmonics of the tension of the feeding three-phase network. Various means have already been given to force an equal current consumption of the two six-phase systems. The effect, is in the previously known arrangements either by dividing the rectifier transformer in two six-phase transformers or by using. Anode chokes achieved. Both facilities are complicated and make the system more expensive.

According to the invention, in order to achieve the same current consumption of the anodes of a polyphase rectifier with η six-phase anode systems (n an integer) shifted relative to one another with regard to the phase position of the supplied voltage, the anodes of which are provided with grids controlled in a known manner, which can be used for direct voltage regulation , the ß six-phase anode systems η six-phase grid control devices. assigned, and the grids are controlled in such a way that the anode currents of that six-phase anode system, which has the greater current consumption, receive an ignition delay, while at the same time the anodes of the other system, which takes too little load, receive a corresponding advance of the ignition point.

In the drawing, exemplary embodiments of the invention are shown schematically in FIG Fig. Ι to 5 shown. The rectifier with its anodes, control grids, etc. is for Simplification of the presentation of the ■ subject matter of the invention omitted.

The two 30 ⁰ staggered winding systems of the three-phase twelve-phase transformer for supplying the not shown rectifier are denoted by I and II. The zero points of the two six-phase systems are combined, the conductor going out from the connecting line forms the negative conductor of the direct current network. In the line sections between the zero points of the two Sechsphasensysteme'und connecting the negative conductor are the ammeter e, f. The control grids of the of the two six-phase systems I, II fed anodes are separate potential distribution or contact apparatus a, b with in space fixed sliding contact rings and rotating Assigned brushes that separately connect the control grid to the control voltage source. The brushes of both Eontaktapparate a, b are driven jointly by the synchronous motor m. , Which is connected to the primary network c. . By. Displacement of the system axis of the synchronous motor as a result of a displacement of the grinding

contact at the voltage partial resistor d can also be achieved in a known manner, a regulation of the DC voltage by adjusting the brush angle

one or the other direction of the Z .j, " _t

point of the anodes in the leading or nearer * v ^; hasty sense is shifted. The sliding contact rings of the contact apparatus a, b are designed in the example shown as ring gears ίο or worm gears, with which z. B. worms g, h, which are arranged on the shaft / are in engagement, one of which is right-handed and the other left-handed, so. that the sliding contact rings a, b, which are arranged on the shaft Z ₁ , by rotating the shaft, for. B. by means of a handle, rotated in opposite directions. In this way, for example, in system I controlled by contact apparatus α, the ignition timing of the anodes is adjusted in the leading sense, and in system II controlled by contact apparatus δ, the ignition timing is adjusted in a lagging sense. The adjustment of the two Koiitaktrings takes place until the same load absorption in the two systems I, II is indicated on the ammeters e, f .

Instead of balancing the load by mutually adjusting the contact rings for the grid control as in the example in Fig The differential relay / 'contains the two current coils «^ n _%> whose armatures are connected by a balance beam and the contact pairs k _and k ₂ close and open One pair of contacts bridges the upper contacts, the lower contacts on the other pair of contacts bridged by the relay armature, so that the drive motor ρ for the worm spindle /, which adjusts the contact rings β, and b , is brought to start in one direction ο the other, whereby the Contact rings are adjusted against each other for so long and the ignition timing of the 'anodes of both systems is adjusted until the balance is present in the load on the anode currents.

The relay according to Fig. 2 can also be omitted if, according to Fig. 3, the zero points of the two six-phase systems I, II fed by the network are connected by a resistor 0 , to whose center tap the negative conductor of the direct current network is connected, and whose end points are ' the brushes of the DC motor / 7 are connected, which adjusts the worm spindle / for the adjustment of the contact rings α and b of the two contact devices against each other. The motor ρ is here; iif4tnd excited. Depending on which zero-point current predominates, the armature of the expensive engine receives a positive or negative voltage and starts moving in one or the other direction of rotation. In this figure, tn again means the synchronous motor tn driving the rotating brushes, the rotor of which can be adjusted in its spatial phase position by means of the voltage divider d.

The contact rings can also be rotated as shown in Fig. 4. Here there are two synchronous motors In ₁ , fn .. ₂ for driving the brushes of the contact devices a, b for the grid control, the rotors of which are fed with three-phase current from the network via three brushes each. The stators, which are provided with a normal, star-connected three-phase winding, receive the direct current excitation from a battery s, which is connected between phases 1 and 2 or 1 and 3. Phase 2 of one synchronous motor m _x is connected to phase 3 'of the other synchronous motor OTo, while phase 3 is connected to phase 2'. Furthermore, phases 1 and 1 'are connected to one another. Phases 2 and 3 are placed at the end points of the resistance ο , which is in the connection line between the zero points of the two systems I and II. If the current consumption of the two six-phase systems is the same, the battery current flows through the two phases 1 and 1 'and is evenly distributed over the two phases 2 and 3 or 2' and 3 'to get to the other pole of the battery via the resistor ο flow back. If, however, the current consumption of the two six-phase systems is unequal, either a positive or a negative voltage arises at the endpoints of the resistance. These cause a current in phases 2 and 3, which is superimposed on the battery current and weakens the current in one winding and strengthens it in the other. As a result, the magnetic field of the stator is rotated relative to the rotor, which causes a corresponding adjustment of the spatial phase position of the brushes of the contact apparatuses a, b . However, since phases 2 and 3 are interchanged compared to phases 2 'and 3', the rotation of the magnetic axis affects one synchronous motor in the opposite direction as it does the other. This brings about the desired adjustment in relation to one another.

If there are anode reactors with secondary windings, the Currents in these secondary windings

use the contact apparatus accordingly to adjust. The currents in the secondary windings of the anode reactors are namely proportional to the direct currents of the relevant S six-phase systems. So will separate six-phase anode coils are arranged for the two six-phase systems the secondary currents in these coils correspond to the direct currents of the six-phase

to systems proportional.

In Fig. S, the two secondary six-phase systems I, II of the three-phase twelve-phase supply transformer are each split into two star-connected three-phase systems, the zero points of which are connected to one another by suction throttles t. The anode choke coils with the six-phase primary windings W, which feed the anodes, and the secondary windings 2 are denoted by ν.

The secondary windings feed the primary windings of a three-phase differential transformer u, which are connected so that the secondary currents of the two six-phase systems run against each other. Here, Z ¹ U must be noted that one six-phase system is offset from the other by 30 el. Degrees, so that in one system a phase combination either in the secondary winding of the anode coil, as shown in this figure, or in the windings on the Differential transformer must be used. The counteracting secondary currents have different curve shapes in certain circuits, so that even if the direct currents or the fundamental harmonics of the mains frequency are of the same size, harmonic harmonics still remain. However, these upper harmonics are so much smaller than the fundamental harmonics and of so much higher frequency that they do not interfere with the control apparatus.

In the example shown in Fig. 5

Each six-phase system I, II has two six-phase anode choke coils connected in parallel assigned to feed the anode pairs working in parallel. The ones working in parallel Anodes can belong to a single rectifier or to two separate rectifiers.

The differential transformer, which is expediently a. Receives air gap, has a three-phase secondary winding, the ends of which are led to the three-phase fed stators of the synchronous motors tn _L> m ₂ . The centers of the three secondary windings are connected to the three phases of the primary network c . In synchronous motors, the rotors are excited with direct current via the voltage divider d; the motors drive the brushes of the contact devices a, b for the grid control. If the load on the two six-phase systems I, II is the same, a voltage of mains frequency does not occur between the two stators of the synchronous motors. In the case of unequal loads, _{however, R 5} is either one or the other, based on a predetermined point in time. Direction a voltage at the ends of the secondary winding of the differential transformer, κ occur. The interconnection of the phases is chosen so that the voltages supplied to the stators of the synchronous motors are shifted in their phase position in opposite directions, whereby the load compensation is effected according to the invention.

If there are two separate transformers for the two six-phase systems I, II, the differential transformer 11 can also be fed directly from the primary currents of the two transformers instead of the currents of the secondary windings ■ of the anode coils, as shown in Fig. 5.

Any other method of controlling the rectifier grids for the purpose Voltage regulation can be applied for the present purpose of load balancing, e.g. B. the voltage regulation by twisting the phase of the control voltages. Also these control voltages can with one. Differential transformer similar to that of Fig. 5 in their Phases are rotated against each other accordingly.

Claims (11)

Patent claims: 1. Device for achieving the same current consumption of the anodes of a polyphase rectifier with η six-phase anode systems (ti an integer) shifted against each other in terms of the phase position of the supplied voltage, the anodes of which are provided with grids controlled in a known manner, which can be used for direct voltage regulation, thereby characterized in that the η six-phase grid control devices assigned to the six-phase anode systems of the polyphase rectifier are controlled in such a way that the anode currents of that six-phase anode system which has the greater current consumption receive an ignition delay, while at the same time the anodes of the other system which takes a Z ¹ U small load , get a corresponding advance · of the ignition point .. 2. Device according to claim 1, characterized in that when used of contact devices for grid control with fixed grinding contact rings and a rotating grinding brush that represent the individual six-phase systems assigned contact apparatus adjusted in mutually opposite sense will. 3. Device according to claim 2, characterized in that the sliding contact rings the contact devices for the grid control of the two six-phase systems, their grinding brushes in common are set in rotation by a synchronous motor connected to the AC network, with sprockets on the circumference are provided, in which snails lying on a common thread intervene, one of which is right-handed, the other left-handed. 4. Device according to claim 3, characterized in that the worm shaft manually or automatically by devices that respond to the difference in the zero-point currents of the six-phase systems is rotated. 5. Device according to claim 4, characterized characterized in that the worm shaft is driven by a motor, its sense of rotation by one on the difference of the anode currents in the two Six-phase systems responding relay is affected. 6. Device according to claim 5, characterized in that the relay is a Balance beam relay with two of the zero point currents of the two six-phase systems is traversed coils, the armature of which has changeover contacts for the excitation of the drive motor of the worm shaft steer. 7. Device according to claim 5, characterized characterized in that the drive motor of the contact apparatus is a foreign-.eraegter A motor whose brushes are placed at the ends of a resistor, which is the zero points of the six-phase systems connects with each other, and at its center the negative conductor of the direct current network connected. 8. Device according to claim 5 or 7, characterized in that the individual Contact devices for the various six-phase systems of special synchronous motors are driven, the rotors of which are fed via slip rings from the alternating current network and whose star-connected stator windings are connected to a battery, on the one hand at the ends of the interconnected stator windings of phase 1, on the other hand at the center point • a resistor connecting the zero points of the six-phase systems is connected and that the ends of the remaining stator windings of phases 2 'and 3 in the individual motors interchanged are connected to the ends of this resistor. 9. Device according to claim 1 to 3 for rectifiers with working in parallel Anodes using anode inductors with secondary windings, characterized in that the currents in the secondary windings of the anode inductors fed to the primary windings of a differential transformer in the manner be that these currents are directed against each other, 'and that the three-phase The secondary winding of this differential transformer is the stators of the synchronous motors with DC excitation on the rotor side for the drive of the contact apparatus, and that finally the center taps the three-phase secondary winding of the differential transformer is connected to the AC network are. 10. Device according to claim 9, characterized in that a phase combination either in the secondary winding of the anode choke coil of the one six-phase system or in the windings of the differential transformer is provided. 11. Device according to claim 9 when using separate transformers for feeding the individual six-phase systems, characterized in that the differential transformer is on the primary side is fed directly from the primary currents of the two transformers. 1 sheet of drawings BERLIN ". Ι" .Μ · ί · ΐ; · "ΚΙ- IX YOU! Ii