Direct-drive wind turbine circuit topology with single-stage boost inverter

Abstract

An electrical generator (114) and a power electronics interface (115) for a direct-drive turbine (110). The turbine (110) may include a rotor (112) for transforming kinetic (from, e.g., wind, water, steam) into mechanical energy, the generator (114) for transforming the mechanical into electrical energy, and the power electronics interface (115) for conditioning the electrical energy for delivery to a power distribution grid (124). The interface (115) includes a three-phase single-stage boost inverter (120) for converting a lower DC voltage into a higher AC voltage, and which uses a synchronous reactance of the generator (114) as a DC-link inductance. The turbine (110) has neither the gearbox of indirect-drive designs nor the electrolytic capacitor bank of conventional direct-drive designs, while still allowing for a substantially smaller number of generator poles, resulting in reduced size, weight, complexity, and cost.

Claims

1. A direct-drive turbine comprising: a rotor configured to transform kinetic energy into mechanical energy; an electrical generator configured to transform the mechanical energy from the rotor into electrical energy; and a power electronics interface configured to condition the electrical energy from the electrical generator for delivery to a power distribution grid, the power electronics interface including an AC-to-DC converter configured to receive and rectify the electrical energy from the electrical generator, and a DC-to-AC boost inverter configured to receive the electrical energy from the AC-to-DC converter and convert a DC voltage into a relatively higher AC voltage, wherein the DC-to-AC boost inverter is configured to use a synchronous reactance of the electrical generator as a DC-link inductance, and wherein there is no capacitor and no inductor within or between the AC-to-DC converter and the DC-to-AC boost inverter.

2. The direct-drive turbine as set forth in claim 1, wherein the kinetic energy is provided by a flowing fluid medium selected from the group consisting of: liquids and gases.

3. The direct-drive turbine as set forth in claim 1, wherein the electrical generator is a permanent magnet electrical generator.

4. The direct-drive turbine as set forth in claim 1, wherein the electrical generator is a synchronous electrical generator.

5. A direct-drive turbine comprising: a rotor configured to transform kinetic energy into mechanical energy; a permanent magnet or synchronous electrical generator configured to transform the mechanical energy from the rotor into electrical energy; and a power electronics interface configured to condition the electrical energy from the electrical generator for delivery to a power distribution grid, the power electronics interface including an AC-to-DC converter configured to receive and rectify the electrical energy from the electrical generator, and a DC-to-AC boost inverter configured to receive the electrical energy from the AC-to-DC converter and convert a DC voltage into a relatively higher AC voltage and to use a synchronous reactance of the permanent magnet or synchronous electrical generator as a DC-link inductance, wherein there is no capacitor and no inductor within or between the AC-to-DC converter and the DC-to-AC boost inverter.

6. The direct-drive turbine as set forth in claim 5, wherein the kinetic energy is provided by a flowing fluid medium selected from the group consisting of: liquids and gases.

7. In a direct-drive turbine having a rotor configured to transform kinetic energy into mechanical energy, an electrical generator configured to transform the mechanical energy from the rotor into electrical energy, and a power electronics interface configured to condition the electrical energy from the electrical generator for delivery to a power distribution grid, the improvement comprising: the power electronics interface including an AC-to-DC converter configured to receive and rectify the electrical energy from the electrical generator, and a DC-to-AC boost inverter configured to receive the electrical energy from the AC-to-DC converter and convert a DC voltage into a relatively higher AC voltage, wherein the DC-to-AC boost inverter is configured to use a synchronous reactance of the electrical generator as a DC-link inductance, and wherein there is no capacitor and no inductor within or between the AC-to-DC converter and the DC-to-AC boost inverter.

8. The direct-drive turbine as set forth in claim 7, wherein the kinetic energy is provided by a flowing fluid medium selected from the group consisting of: liquids and gases.

9. The direct-drive turbine as set forth in claim 7, wherein the electrical generator is a permanent magnet electrical generator.

10. The direct-drive turbine as set forth in claim 7, wherein the electrical generator is a synchronous electrical generator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 (PRIOR ART) is a high-level schematic of an exemplary wind turbine having a conventional electrical generator and a conventional power electronics interface;

(2) FIG. 2 is a high-level schematic of a wind turbine having embodiments of an electrical generator and a power electronics interface of the present invention;

(3) FIG. 3 is a depiction of exemplary line-to-line voltage phasors and their sectors associated with the wind turbine of FIG. 2; and

(4) FIG. 4 shows voltage plots for the electrical generators of FIGS. 1 and 2 for comparison.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(5) Referring to FIG. 1 (PRIOR ART), an exemplary wind turbine 10 may broadly comprise a rotor 12 for transforming kinetic energy from wind into mechanical energy, and an electrical generator 14 for transforming the mechanical energy into electrical energy. The generator 14 includes a power electronics interface 15 which includes an AC-to-DC converter 16 for rectifying the electrical generator's output, a DC-to-AC inverter 18 for changing the rectified signal into a sinusoid having a desired frequency (e.g., 60 Hz), and an electrolytic capacitor bank 20 interposed between the rectifier 16 and the inverter 18 in order to smooth the voltage output of the rectifier 16. The output of the inverter 18 may be passed through a transformer 22 on its way to a power distribution grid 24. The use of the DC-to-AC inverter 18 to convert a variable frequency AC voltage to a line frequency, three-phase, balanced AC voltage makes it necessary for the electrical generator 14 to produce a specific AC voltage which, when rectified, gives the required DC-bus voltage. This minimum voltage requirement can be satisfied either by using a gearbox 26 to increase the drive speed of the generator 14 or by using a very large generator with a very large number of poles to produce the desired AC output voltage which after rectification can be fed to the inverter 18. Thus, if this is an indirect-drive wind turbine, then the gearbox 26 may be interposed between the rotor 12 and the electrical generator 14. The gearbox 26 allows for using a relatively small, light, simple, and inexpensive generator, but the gearbox 26 is a primary point of failure that can offset the advantages it allows for with regard to the generator. If this is a direct-drive wind turbine, then there is no gearbox and the electrolytic capacitor bank 20 is a primary point of failure, and the electrical generator may require one hundred or more poles, which makes it larger, heavier, more complex, and more expensive than the generator used in the indirect-drive wind turbine.

(6) Broadly characterized, the present invention provides an improved electrical generator and power electronics interface for use in a direct-drive turbine, wherein the resulting turbine has neither a gearbox nor an electrolytic capacitor bank (which, again, are the most failure prone components) and, furthermore, requires a substantially smaller number of poles than prior art electrical generators, resulting in reduced size, weight, complexity, and cost. Referring to FIG. 2, this is accomplished by replacing the DC-to-AC inverter 18 and the electrolytic capacitor bank 20 with a single-stage boost inverter 120. In one embodiment, the number of poles may be reduced to approximately one-fourth or less of the number or poles required by prior art electrical generators. Furthermore, the power electronics interface 115 of the present invention increases overall system reliability and facilitates further innovations in electrical generator design. In particular, the power converter 120 transfers power from a low DC voltage to a much higher three-phase AC voltage. This allows a PM or synchronous generator in a direct-drive wind turbine to produce a lower voltage and a higher current, which adds flexibility to the generator design process and allows designers to be more innovative and use less expensive and more efficient generators.

(7) An operational environment for and embodiment of the present invention are shown in FIG. 2 as broadly comprising, in a direct-drive wind turbine 110, the rotor 112, the electrical generator 114, the power electronics interface 115 including the AC-to-DC converter 116 and the single-stage boost inverter 120, the transformer 122, and the power distribution grid 124. In some embodiments, the rotor 112, the transformer 122, and the power distribution grid 124 may be substantially conventional. Although described herein primarily in the operational context of wind turbines, the electrical generator 114 and power electronics interface 115 of the present invention may also be used with other types of turbines, such as turbines making use of kinetic energy from substantially any flowing fluid mediums (whether liquids or gases), and is not limited to use in wind turbines.

(8) The single-stage boost inverter 120 can use a relatively low DC-bus voltage and does not require an electrolytic capacitor bank at the DC-bus. Thus, the inverter 120 may replace the DC-to-AC inverter 18 and the electrolytic capacitor bank 20 found in prior art power electronic interfaces 15. In one embodiment, the inverter 120 may be a three-phase single-stage boost inverter. FIG. 3 shows a depiction 210 of exemplary line-to-line voltage phasors and their sectors associated with an embodiment of the direct drive turbine 110. The switching pattern for the insulated gate bipolar transistors (IGBTs) of the inverter 120 may include six sectors and nine states (three charging states and six discharging states) with only two switches conducting at any given time. The charging states may boost the DC input voltage. There may be six sectors separated by six-line-to-line voltage phasors Vab, Vba, Vcb, Vca, and Vac. In this illustration, the DC-source, Vdc, is located in Sector (I). In each switching cycle there may be three time-intervals: One time-interval for charging the DC-link inductor, tc, and two time intervals for injecting current into two different phases. In other words, the six main switching states, and two zeros, with three switches conducting at any given instant in conventional space vector PWM (SVPWM) techniques, may be modified to six states with only two switches conducting at any given time, as well as three charging states in PPWM for the single-stage boost inverter 120. PPWM may be been formulated based on the phasor quantities, and not the space-vectors. Thus, there may be three states resulting from the three time-intervals in each switching cycle as follows. State-C may be the charging interval, tc, in which two switches in Leg-A, i.e., Sap and San, are closed and the DC-link inductor is being charged. State-D1 may be the first discharging time-interval in which the inductor current is directed into phases A and B. During this period of time, the upper switch of Leg-A, Sap, and the lower switch of Leg-B, Sbn, of the inverter may be closed. State-D2 may be the second discharging time-interval in which the inductor current may be directed into phases A and C. During this period of time, the upper switch of Leg-A and the lower switch of Leg-C of the inverter may be closed. When used in photovoltaic systems, such a single stage boost inverter requires a DC-link inductor, but as used by the present invention in wind turbines, it may utilize the synchronous reactance of the PM (or synchronous) generator as the DC-link inductance, which advantageously lowers system costs and losses.

(9) In the prior art, the AC three-phase output of the electrical generator 14 is rectified and smoothened by the large electrolytic capacitor bank 20 and then fed as input to the DC-to-AC inverter 18. The output of this inverter 18 is a three-phase signal, and, for this inverter topology, the rms value of the line-to-line voltage of the inverter output for a given input DC voltage can be found via the equation

(10) $V_{\mathrm{LL}}=V_{\mathrm{DC}}\left(\frac{\sqrt{3}}{2\sqrt{2}}\right)$
(considering modulation index=1 for the switching of the inverter 18).

(11) For example, if a 600 V L-Lrms voltage is desired at the inverter output, then the DC-bus voltage must be approximately 980 V. In order to have 980 V at the DC-bus line, the line-to-line rms voltage to be rectified must be approximately 725 VL-Lrms. Thus, the electrical generator 14 must produce approximately 725 V L-Lrms to have 600 V LLrms output from the inverter 18. Using the single-stage boost inverter 120, the same 600 VL-Lrms can be generated by the inverter 120 with a DC-bus voltage of 150 V, which in turn can be obtained from 110 VL-Lrms from the electrical generator 114. Thus, the single-stage boost inverter 120 of the present invention allows for reducing the generator output voltage by almost one-sixth (or less) of that required when using the DC-to-AC inverter 18. In turn, this allows for producing a smaller electrical generator with a fewer number of poles.

(12) FIG. 4 shows a comparison of the output voltage 310 required from a conventional system using a conventional electrical generator 14 and the output voltage 312 from an embodiment of an electrical generator 114 of the present invention for the same power delivered to the load. For this comparison, an output voltage of 208 V.sub.L-Lrms was generated at the inverter output of both systems which is feeding a three-phase balanced resistive load of 70 /phase. The voltage output of the electrical generator 14 for the prior art system (312 V.sub.L-Lrms, in this case) is more than four times higher than the voltage output of the electrical generator 114 of the present invention (67 V.sub.L-Lrms, in this case).

(13) For an electrical generator, E=4.44KfN, where frequency can be written as:

(14) $f=\frac{n_{\mathrm{rpm}}P}{120}$
where P is the total number of poles. Thus,

(15) $E=\frac{4.44K{\mathrm{Nn}}_{\mathrm{rpm}}P}{120}$
For the electrical generator used for both cases,

(16) $4.44K\frac{N}{120}=\mathrm{constant}$
and n.sub.rpm is dependent on the wind speed, i.e.,

(17) $4.44K\frac{{\mathrm{Nn}}_{\mathrm{rpm}}}{120}=\mathrm{constant}{}^{\mathrm{``}}C^{}$
where is the flux per pole. Therefore, E=CP. So in order to increase the voltage generated by the electrical generator, a higher pole surface is required. However, an electrical generator 114 coupled with the single-stage boost inverter 120 of the present invention requires less pole surface required by the prior art electrical generator 14 coupled with a voltage source inverter.

(18) Thus, embodiments of the present invention advantageously allow for, in turbines, eliminating primary points of failure, lowering preventative and actual maintenance costs, reducing downtime, and designing electrical generators that are smaller, lighter, less complex, and less expensive, and generally facilitating greater innovation in generator design.

(19) Although the invention has been described with reference to the one or more embodiments illustrated in the figures, it is understood that equivalents may be employed and substitutions made herein without departing from the scope of the invention as recited in the claims.