METHOD FOR GENERATING AN INDUCTIVE REACTIVE POWER BY MEANS OF AN ELECTRICAL LOAD APPARATUS, ELECTRICAL LOAD APPARATUS, AND ELECTROLYSIS APPARATUS

Abstract

A method for generating an inductive reactive power for a public grid by an electrical load apparatus, in which, in a first operating mode of the electrical load apparatus, an alternating current of the public grid is transformed by a transformer device and the transformed alternating current is provided for an electrical load of the electrical load apparatus. In a second operating mode of the electrical load apparatus that is different from the first operating mode, the transformer device is short-circuited in a phase-controlled manner by a switching device of the electrical load apparatus, wherein the switching device is phase-controlled such that, depending on a phase angle of the phase control of the switching device by the transformed alternating current, the inductive reactive power for the public grid is generated by the switching device.

Claims

1. A method for generating an inductive reactive power for a public grid by means of an electrical consumer apparatus, the method comprising: in a first operating mode of the electrical consumer apparatus, transforming an AC current of the public grid by means of a transformer device, and providing the transformed AC current for an electrical consumer of the electrical consumer apparatus, in a second operating mode of the electrical consumer apparatus that is different to the first operating mode, short-circuiting the transformer device in a phase-controlled manner by means of a switching device of the electrical consumer apparatus, wherein the switching device is phase-controlled in such a way that the inductive reactive power is generated by means of the transformed AC current for the public grid by means of the switching device depending on a phase gating angle of the phase control of the switching device, and additionally controlling the inductive reactive power by means of a tap changer of the transformer device.

2. The method as claimed in claim 1, wherein the switching device has a rectifier circuit and an isolating switch, wherein the isolating switch is closed to short-circuit the transformer device and the phase gating angle is controlled by means of the rectifier circuit by clocked actuation of the rectifier circuit.

3. The method as claimed in claim 2, wherein the transformed AC current is phase-controlled by means of a six-pulse bridge circuit as the rectifier circuit.

4. The method as claimed in claim 3, wherein the inductive reactive power is generated by means of the rectifier circuit in such a way that it corresponds to an installed apparent power of the transformer device.

5. The method as claimed in claim 4, wherein the rectifier circuit is operated with a rated current of the rectifier circuit to generate the inductive reactive power.

6. The method as claimed in claim 1, wherein the switching device is controlled with a phase gating angle of at least greater than 75°.

7. An electrical consumer apparatus for generating an inductive reactive power, comprising: at least one transformer device, and a switching device, wherein the electrical consumer apparatus is designed to carry out a method as claimed in claim 1.

8. An electrolysis apparatus for carrying out electrolysis in a first operating mode and for generating an inductive reactive power for a public grid in a second operating mode, comprising: at least one electrolysis device, wherein the at least one electrolysis device comprises the electrical consumer apparatus as claimed in claim 7.

9. The electrolysis apparatus as claimed in claim 8, wherein the electrolysis apparatus has a tap changer for coarse regulation of the electrolysis and a thyristor switch for fine regulation of the electrolysis in the first operating mode.

10. The method as claimed in claim 6, wherein the phase gating angle is greater than 80°.

11. The method as claimed in claim 6, wherein the phase gating angle is greater than 85°.

12. The method as claimed in claim 6, wherein the phase gating angle is greater than 90°.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] In the figures:

[0025] FIG. 1 shows a schematic view of an embodiment of an electrolysis apparatus with an embodiment of an electrical consumer apparatus; and

[0026] FIG. 2 shows a schematic reactive power/active power graph of an embodiment of the electrolysis apparatus.

DETAILED DESCRIPTION OF INVENTION

[0027] FIG. 1 shows a schematic view of an embodiment of an electrolysis apparatus 10 with an embodiment of an electrical consumer apparatus 12. In this exemplary embodiment, the electrical consumer apparatus 12 is in particular in the form of an electrolysis device. The electrolysis apparatus 10 is designed for carrying out electrolysis in a first operating mode and for generating an inductive reactive power Q.sub.IND (FIG. 2) for a public grid 14 in a second operating mode, and has at least one tap changer for coarse regulation of the electrolysis and one thyristor switch 16 for fine regulation of the electrolysis in the first operating mode. The electrical consumer apparatus 12 also has at least one transformer device 18 and a switching device 20. The electrolysis apparatus 10 also has a first switching element 22 for isolating a DC side 24 of the electrolysis apparatus 10 and a second switching element 26 for isolating the DC side 24 from the public grid 14.

[0028] In particular, an AC current is provided by the public grid 14. In particular, the present FIG. 1 shows only one phase of the AC current. The method can additionally also be operated with three AC phases from the public grid 14 the electrolysis apparatus 10.

[0029] In the method for generating the inductive reactive power Q.sub.IND for the public grid 14 by means of the electrical consumer apparatus 12, in a first operating mode of the electrical consumer apparatus 12, the AC current of the public grid 14 is transformed by means of the transformer device 18, and the transformed AC current is provided for an electrical consumer 28 of the electrical consumer apparatus 12.

[0030] In a second operating mode of the electrical consumer apparatus 12 that is different to the first operating mode, provision is made for the transformer device 18 to be short-circuited in a phase-controlled manner by means of the switching device 20 of the electrical consumer apparatus 12, wherein the switching device 20 is phase-controlled in such a way that the inductive reactive power Q.sub.IND is generated by means of the transformed AC current for the public grid 14 by means of the switching device 20 depending on a phase gating angle of the phase control of the switching device 20.

[0031] The present exemplary embodiment shows, in particular, a method for generating the inductive reactive power Q.sub.IND for the public grid 14 by means of the electrolysis apparatus 10, in which, in a first operating mode of the electrolysis apparatus 10, AC current of the public grid 14 is transformed by means of the transformer device 18 of the electrolysis apparatus 10 on an AC side 30 of the electrolysis apparatus 10, and the transformed AC current is provided to an input side 32 of a rectifier circuit 34 of the electrolysis apparatus 10 and the transformed AC current is converted into a DC current by means of the rectifier circuit 34 and the DC current is provided on an output side 36 of the rectifier circuit 34 for the electrolysis device for electrolysis on the DC side 24 of the electrolysis apparatus 10. In this case, provision is in particular made, in a second operating mode of the electrolysis apparatus 10 that is different to the first operating mode, for an isolating switch 38 of the electrolysis apparatus 10 to be closed on the output side 36 and for the output side 36 to be short-circuited by means of the isolating switch 38 and for the inductive reactive power Q.sub.IND to be generated for the public grid 14 by means of the rectifier circuit 34 and the transformed AC current.

[0032] In other words, FIG. 1 shows in particular that the switching device 20 can have the rectifier circuit 34 and the isolating switch 38, wherein the isolating switch 38 is closed to short-circuit the transformer device 18 and the phase gating angle is controlled by means of the rectifier circuit 34 by clocked actuation of the rectifier circuit 34.

[0033] In particular, provision can be made in this case for the rectifier circuit 34 to be provided as a six-pulse bridge circuit and in particular as a B6C circuit. Therefore, provision is made for the transformed AC current to be phase-controlled by means of the six-pulse bridge circuit as the rectifier circuit 34.

[0034] Provision is also in particular made for the inductive reactive power Q.sub.IND to be generated by means of the rectifier circuit 34 in such a way that it corresponds to the installed apparent power of the transformer device 18. The rectifier circuit 34 is operated in particular with a rated current of the rectifier circuit 34 to generate the inductive reactive power Q.sub.IND.

[0035] Provision can also be made for the inductive reactive power Q.sub.IND to be additionally controlled by means of a tap changer of the transformer device 18.

[0036] In particular, provision can be made for the switching device 20 to be controlled with a phase gating angle of at least greater than 75°, in particular greater than 80°, in particular greater than 85°, in particular greater than 90°.

[0037] In particular, the invention therefore makes use of the fact that the electrolysis apparatus 10 has the line-commutated rectifier, in other words the rectifier circuit 34, for high-power and high-voltage electrolysis. In order to be able to regulate the electrolysis, the tap changer for coarse regulation and the thyristor switch for fine regulation are installed in the rectifier circuit 34 connected upstream. This regulation allows the operating point to be approached precisely, since all the electrolysis cells that correspond to the electrical consumers 28 in the present exemplary embodiment are connected in series. Since the rectifier circuit 34 is line-commutated, for fine control it requires inductive control reactive power that is very low compared to the active power. In the case of the normal electrolysis set-up, power P (FIG. 2) can be drawn and inductive reactive power Q.sub.IND can be provided to a small extent. Both of these only function when the electrolysis is in operation, however. Additional grid services therefore do not need to be provided in the first operating mode.

[0038] In order to now provide an additional grid service for the public grid 14 even when there is no electrolysis taking place, the inductive reactive power Q.sub.IND that in particular can be just as high as the installed apparent power of the transformer device 18 is provided when the switching elements 22, 26 are open and, in the following exemplary embodiment, when the isolating switch 38 is closed. The isolating switch 38 is therefore installed downstream of the rectifier circuit 34. Said isolating switch short-circuits the DC side 24; the rectifier circuit 34 can therefore be driven to the rated current in a regulated manner. Since this occurs with a phase gating angle of approximately 90°, however, only pure reactive power Q.sub.IND is fed back to the public grid 14. As a result, with this modification, an additional grid service can be provided if the grid operator requests this.

[0039] Therefore, the inductive reactive power Q.sub.IND can be provided by simply fitting the isolating switch 38 in an already existing system of the electrolysis apparatus 10, which system can be used especially in the case of weak medium voltages. The costs of the isolating switch 38 are extremely low in comparison to thyristor-controlled reactors and inductors hard-wired to the grid that are used in accordance with the prior art, for example. Therefore, the isolating switch 38 is proposed, which closes if necessary, that is to say in the second operating mode, while the two existing switching elements 22, 26 open for electrolysis.

[0040] FIG. 2 shows a schematic view of a reactive power/active power graph. In particular, the inductive reactive power Q.sub.IND is plotted on the abscissa and the active power P is plotted on the ordinate. During electrolysis, the electrolysis apparatus 10 in particular has a first operating range A1. In other words, during electrolysis, virtually only active power P is generated, and low inductive reactive power Q.sub.IND. In particular, the operating range A1 therefore shows the first operating mode of the electrolysis apparatus 10. The electrolysis apparatus 10 is extended by a second operating range A2 by closing the isolating switch 38, in other words by short-circuiting the DC side 24. In the second operating range A2, virtually only inductive reactive power Q.sub.IND is generated, and only low active power P.

[0041] Overall, the invention shows extended provision of inductive reactive power Q.sub.IND in the form of grid system power from electrolysis.