ELECTROMAGNETIC COMPATIBILITY FILTER OF A WIND POWER INSTALLATION

Abstract

Provided is a filter arrangement for a converter module, in particular for a power converter module of a wind power installation, comprising: a magnetic core, which is ring-shaped or tubular, with an opening, and is made of at least one ferro- or ferrimagnetic material, wherein the magnetic core is configured to receive at least a first phase of the converter module and a first conductor of a DC voltage for the converter module through the opening in such a way that the magnetic core forms a choke for the converter module and a choke for the DC voltage.

Claims

1. A filter arrangement for a converter module, comprising: a magnetic core, wherein the magnetic core is ring-shaped or tubular, has an opening, and is made of at least one material selected from ferromagnetic material or ferrimagnetic material, and wherein the magnetic core is configured to: receive, through the opening, at least a first phase of the converter module and a first conductor of a DC voltage for the converter module, and form a choke for the converter module and a choke for the DC voltage.

2. The filter arrangement as claimed in claim 1, wherein the converter module is part of a power converter module of a wind power installation.

3. The filter arrangement as claimed in claim 1, wherein the magnetic core is configured to: receive, through the opening, a second phase and a third phase of the converter module and a first conductor and a second conductor of the DC voltage for the converter module; and form a choke for the converter module and a choke for the DC voltage.

4. The filter arrangement as claimed in claim 1, wherein the magnetic core includes a combination of cores.

5. The filter arrangement as claimed in claim 1, wherein the filter arrangement has an inductance of between 1 microhenry (μH) and 1000 μH or the magnetic core has a permeability of between 100 henry/meter (H*m.sup.−1) and 20 000 H*m.sup.−1.

6. The filter arrangement as claimed in claim 1, comprising: a capacitance for the first phase, wherein the capacitance is an interference suppression capacitor or the capacitance is arranged downstream of the magnetic core in a direction of current flow.

7. The filter arrangement as claimed in claim 1, comprising: a capacitance for the first conductor, wherein the capacitance is an interference suppression capacitor or the capacitance is arranged downstream of the magnetic core in a direction of current flow.

8. The filter arrangement as claimed in claim 1, wherein the filter arrangement is an electromagnetic compatibility (EMC) filter or is configured to filter out high-frequency interference from an AC current generated by the converter module.

9. The filter arrangement as claimed in claim 1, wherein the converter module has a rated power of at least 300 kilowatt (kW), and the filter arrangement is configured for the rated power or a current generated from the converter module.

10. The filter arrangement as claimed in claim 9, wherein the converter module has a rated power of at least 600 kW.

11. The filter arrangement as claimed in claim 1, wherein: the magnetic core is dimensioned to be arranged in a switchgear cabinet; or the filter arrangement has support that is configured to mount the magnetic core horizontally in a switchgear cabinet.

12. The filter arrangement as claimed in claim 11, wherein the first phase runs perpendicularly through the opening.

13. A converter module, comprising: a connection for coupling the converter module to a DC voltage; an inverter module coupled to the connection; and a converter output coupled to the inverter module, wherein at least one filter arrangement is arranged at the converter output, wherein the at least one filter arrangement includes: a magnetic core, wherein the magnetic core is ring-shaped or tubular, has an opening, and is made of at least one material selected from ferromagnetic material or ferrimagnetic material, and wherein the magnetic core is configured to: receive, through the opening, at least a first phase of the converter module and a first conductor of the DC voltage for the converter module, and form a choke for the converter module and a choke for the DC voltage.

14. The converter module as claimed in claim 13, wherein three phases of the inverter module and two conductors of the DC voltage are routed through the opening.

15. The converter module as claimed in claim 13, wherein the converter module has a rated power of at least 600 kilowatt (kW).

16. The converter module as claimed in claim 13, wherein the converter module is housed in a switchgear cabinet.

17. A converter arrangement, comprising: a plurality of converter modules including the converter module as claimed in claim 13, wherein the plurality of converter modules are coupled in parallel with each other.

18. A wind power installation, comprising: the converter arrangement as claimed in claim 17.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0072] The present invention will now be explained in more detail below on the basis of the accompanying figures, wherein the same reference signs are used for identical or similar components or assemblies.

[0073] FIG. 1 shows schematically and by way of example a perspective view of a wind power installation in one embodiment.

[0074] FIG. 2 shows schematically and by way of example an electrical section of a wind power installation in one embodiment.

[0075] FIG. 3 shows schematically and by way of example a converter arrangement.

[0076] FIG. 4 shows schematically and by way of example a filter arrangement.

[0077] FIG. 5 shows schematically and by way of example a filter arrangement in a lower region of a switchgear cabinet.

[0078] FIG. 6 shows schematically and by way of example a converter arrangement.

DETAILED DESCRIPTION

[0079] FIG. 1 shows a perspective view of a wind power installation 100.

[0080] In this respect, the wind power installation 100 has a tower 102 and a nacelle 104. An aerodynamic rotor 106 with three rotor blades 108 and a spinner 110 is arranged on the nacelle 104. The rotor 106 is caused to effect a rotational movement by the wind during operation and in so doing drives a generator in the nacelle. As a result, the generator generates a current to be supplied, which is supplied to an electrical supply grid by means of a converter arrangement.

[0081] FIG. 2 shows schematically and by way of example an electrical section 100′ of a wind power installation 100, as preferably shown in FIG. 1.

[0082] The aerodynamic rotor 106 of the wind power installation is connected to the generator 120 of the wind power installation.

[0083] In this case, the generator 120 is preferably in the form of a six-phase generator, for example the generator has two electrically three-phase systems 122, 124 that are decoupled from one another on the stator side.

[0084] The generator 120 is further connected to an electrical supply grid 200, or linked to the electrical supply grid 200, via a converter arrangement 130 by means of a transformer 150.

[0085] In order to convert the electrical power generated by the generator 120 into a current iG to be supplied, the converter arrangement 130 has a plurality of parallel-connected converter modules 130′, 130″, which are substantially physically identical.

[0086] The converter modules 130′, 130″ have an active rectifier 134 at a converter module input. The active rectifier 134 is, for example, connected to a DC link circuit 135, which, for example, has capacitors 136 for the purpose of storage or smoothing. The active rectifier 134 is connected to the inverter 137 via the link circuit 135. In this case, the inverter 137 consists of a plurality of inverter modules 137′, 137″, 137′″, such as shown in FIG. 3, for example, and generates a total current iG to be suppled. In another embodiment, the rectifier 132 can also be of modular design, i.e., it can consist of a plurality of parallel rectifier modules, and/or the converter can be embodied as a back-to-back converter or direct converter, i.e., without a link circuit.

[0087] The converter modules 130, 130″ are brought together at a node 140 on the grid side to form a three-phase overall system 142, as shown in FIG. 3, for example.

[0088] In order to supply the electrical supply grid 200 with the total current iG to be supplied, the output of the wind power installation further has provision for a wind power installation transformer 150, which is preferably star-delta connected and connects the wind power installation 100 to the electrical supply grid 200.

[0089] The electrical supply grid 200, to which the wind power installation 100, 100′ is linked by means of the transformer 150, can be, for example, a wind farm grid or an electrical supply or distribution grid.

[0090] A wind power installation control unit (e.g., wind power installation controller) 160 is further provided for controlling the wind power installation 100 or the electrical section 100′.

[0091] The wind power installation control unit 160 is configured to detect the total current iG by means of a current detector (e.g., ammeter or multimeter) 162. Preferably, in particular, the currents of each converter module 137′ in each phase are detected for this purpose.

[0092] Furthermore, the control unit also has current detector 162.

[0093] The control unit 160 is thus in particular configured to control the entire converter 130 with its two converter modules 130′, 130″, in particular as shown in FIG. 3.

[0094] FIG. 3 shows schematically and by way of example the design of a converter arrangement 137′, 137″ with a filter arrangement.

[0095] The converter arrangement 130′, 130″ is connected to a DC voltage V_DC on the generator side and connected to an electrical supply grid 200 on the grid side.

[0096] The converter arrangement 130′, 130″ consists of a first inverter module 137′ and a second inverter module 137″, which are connected in parallel with each another.

[0097] Each of the inverter modules 137′, 137″ generates an AC current i11, i12, i13, i21, i22, i23, which is routed to three phases L1, L2, L3 in each case and overlaid at the node 140 to form a three-phase total current ig1, ig2, ig3 to supplied.

[0098] The converter arrangement 130′, 130″ is controlled, for example, by means of a wind power installation control unit 160 and switching signals S.

[0099] A filter arrangement 300′, 300″ as described above or below is arranged at the output of each of the inverter modules 137′, 137″, which filter arrangements are embodied in particular as described in FIG. 4 and/or FIG. 5.

[0100] FIG. 4 shows schematically and by way of example a filter arrangement 300, in particular between an inverter module 137 and an electrical supply grid 200.

[0101] The filter arrangement 300 comprises a magnetic core 310, an AC capacitance 320 and a DC voltage capacitance 330.

[0102] The magnetic core 310 is embodied as a combination of cores 312 in multiple parts and comprises an opening 314.

[0103] The three phases L1, L2, L3 of the inverter module 137 and the two conductors DC+, DC− of a DC voltage for the inverter module 137 are routed through the opening 314, in particular such that the filter arrangement forms both a grid choke and a common mode choke.

[0104] An AC capacitance 320 and a DC voltage capacitance 330 are furthermore arranged downstream of the magnetic core 310 in the direction of current flow.

[0105] FIG. 5 shows schematically and by way of example a filter arrangement 300 in a lower region of a switchgear cabinet 500.

[0106] The converter module 137 is arranged centrally in the switchgear cabinet and has three phases L1, L2, L3, which are connected to an electrical supply grid by means of terminals A1, A2, A3.

[0107] The converter module 137 is connected to a DC voltage for the converter module 137, which voltage is routed via two conductors DC+, DC−.

[0108] Both the phases L1, L2, L3 and the conductors DC+, DC− are routed through an opening 314 in the magnetic circuit 310.

[0109] The magnetic circuit 310 is in the form of a combination of cores made up of three ferrimagnetic rings 312, which are coupled to each other both mechanically and magnetically.

[0110] The filter arrangement 300 is therefore arranged, from an electrical point of view, on the grid side, i.e., downstream of the converter module 137 in the direction of current flow.

[0111] The DC voltage U.sub.DC comes from the link circuit 135, that is to say is arranged, from an electrical point of view, on the generator side, i.e., upstream of the converter module 137 in the direction of current flow.

[0112] FIG. 6 shows schematically and by way of example a converter arrangement 130.

[0113] The converter arrangement 130 is connected to a generator 120 of a wind power installation and to an electrical supply grid 200.

[0114] The converter arrangement 130 comprises three converter modules 130′, 130″, 130′″, which are connected in parallel with each other.

[0115] The converter modules 130′, 130″, 130′″ are in the form of back-to-back converters and comprise an active rectifier 134′, 134″, 134′″, which is connected to the generator, and an inverter 137′, 137″, 137′″, which is connected to the electrical supply grid, said rectifier and inverter being connected via a DC link circuit.

[0116] A filter arrangement 300 as described above or below is arranged at the output of each converter module 130′, 130″, 130′″.

[0117] The filter arrangements 300 each have an opening within a magnetic core, through which opening DC voltage of the DC link circuit and the output of the inverter 137′, 137″, 137′″ are routed.

[0118] The filter arrangements 300 are in particular embodied as described above or below.

[0119] In particular, the filter arrangements 300 are configured to minimize the circulating currents within the converter arrangement 130 and/or to prevent saturation of the ring cores of the filter arrangement.

[0120] The filter arrangement proposed herein allows in particular: [0121] compensation for the circulating currents and, apropos of that, significantly later saturation of the ring cores; [0122] an option to use smaller ring cores, which saves space inside the switchgear cabinets; [0123] an option of filtering using ferrite cores, where otherwise nanocrystalline material would be required; and [0124] a lower circulating current load on the rest of the system, in particular on the electrical system of the wind power installation.

LIST OF REFERENCE SIGNS

[0125] 100 wind power installation [0126] 100′ electrical section, in particular of the wind power installation [0127] 100″ detail of the electrical section [0128] 102 tower, in particular of the wind power installation [0129] 104 nacelle, in particular of the wind power installation [0130] 106 rotor, in particular of the wind power installation [0131] 108 rotor blade, in particular of the wind power installation [0132] 120 generator, in particular of the wind power installation [0133] 122 first electrical system, in particular of the generator [0134] 124 second electrical system, in particular of the generator [0135] 130 converter arrangement, in particular of the wind power installation [0136] 130′ converter module, in particular for the first electrical system [0137] 130″ converter module, in particular for the second electrical system [0138] 134 active rectifier, in particular of the converter module [0139] 135 DC link circuit, in particular of the converter module [0140] 136 capacitor, in particular of the DC link circuit [0141] 137 inverter [0142] 137′ inverter module [0143] 137″ inverter module [0144] 137′″ converter submodule, in particular inverter module [0145] 140 node [0146] 142 three-phase (overall) system [0147] 150 transformer [0148] 160 wind power installation control unit [0149] 162 current detector [0150] 200 electrical supply grid [0151] 300 filter arrangement [0152] 310 magnetic core [0153] 312 combination of cores [0154] 312′ ferro- or ferrimagnetic ring, in particular combination of cores [0155] 320 AC capacitance [0156] 330 DC voltage capacitance [0157] 500 switchgear cabinet [0158] L1, L2, L3 phases of a converter module [0159] DC+, DC− conductors of a DC voltage [0160] i.sub.G total current to be supplied [0161] U.sub.DC DC voltage [0162] u voltage of a phase [0163] i current of a phase [0164] S (switching) signal [0165] 1,2,3 indices

[0166] The various embodiments described above can be combined to provide further embodiments. These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.