Combining virtual synchronous machine and feedforward torque control for doubly-fed induction machine based wind energy conversion systems

Thommessen, Andre; Hackl, Christoph M.

doi:10.36227/techrxiv.22012409.v1

Cited by 2 publications

(23 citation statements)

References 7 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Utilizing ( 13), power factor κ p := 2 3κ 2 (depending on the Clarke transform scaling factor κ; e.g. κ = 2/3 for amplitude-correct scaling), and load angle δ, the DFIM torque simplifies to [27]…”

Section: Doubly-fed Induction Machine (Dfim)mentioning

confidence: 99%

Virtual synchronous machine control for doubly-fed induction machine based wind energy conversion systems [long version]

Thommessen,

Hackl

2023

Preprint

View full text Add to dashboard Cite

<p>Facing the climate crisis, more and more renewable inverter-based resources (IBRs), such as wind energy conversion systems (WSs), replace grid-connected synchronous machines (SMs). SMs inherently provide balanced and sinusoidal grid voltages but also power system inertia, whereas standard grid-following (GFL) control of IBRs leads to decreasing power system inertia. This paper proposes grid-forming (GFM) control for doubly-fed induction machine (DFIM) based wind energy conversion systems (WSs) based on the virtual synchronous machine (VSM) concept with the following extensions: (i) Maximum power power tracking (MPPT) compensation for accurate inertia emulation, (ii) feedforward torque control (FTC) for fast power reference tracking, (iii) de-rated operation or reference power point tracking (RPPT) to provide additional power reserves, (iv) dynamic droop power saturation control to avoid excessive power overshoots (as available power reserves are taken into account), and (v) grid voltage control utilizing reactive power from both, DFIM stator and rotor-side back-to-back inverter. The modeling and control of the DFIM-based WSs is shown in detail and the grid model is based on the IEEE 9-bus test system. Comprehensive simulation results show that the GFM control enables unlimited power penetration of IBRs and that the grid frequency dynamics of VSM-based power systems can be interpreted and handled analogously to SM-based power systems. During normal operation, compared to existing VSM control without FTC, the proposed VSM control with FTC increases the wind energy yield, i. e. typical MPPT or RPPT performance is achieved, similar to the performance of GFL control. For high power penetration of IBRs, the proposed VSM control enables stable operation due to its inertia emulation or GFM capability, whereas GFL control tends to instability. During faults and system splits, the VSM provides higher power system damping than a real SM due to (i) virtual/internal damping that can be adapted by software (hence almost independently from the hardware, whereas the response of SM damper windings depends on the physical machine design and cannot be altered during operation), and due to (ii) faster droop control which adapts the virtual turbine power without the mechanical delays that dominate real turbine dynamics.</p>

show abstract

Section: Doubly-fed Induction Machine (Dfim)mentioning

confidence: 99%

Virtual synchronous machine control for doubly-fed induction machine based wind energy conversion systems [long version]

Thommessen,

Hackl

2023

Preprint

View full text Add to dashboard Cite

show abstract

“…Despite the research trend towards VSM control for inverters [11] or for type 4 WSs, based on full-scale backto-back converter configurations [17,21,22], the public research on VSM control for DFIMs or type 3 WSs is limited. There exist a few VSM control methods for DFIMs with grid synchronization loops [15,19,[23][24][25][26][27][28], but the electro-magnetic DFIM control loops in these papers differ significantly from those proposed in this paper. Usually, the following electro-magnetic DFIM control loops are employed: (i) no inner current or magnetic flux control loop [23][24][25], i. e. applying the VSM voltage amplitude and angle directly to the RSI, (ii) inner current control loop [19,26,27], (iii) inner magnetic rotor flux control loop [15], (iv) outer magnetic stator flux and inner stator current control loop [28].…”

Section: Introductionmentioning

confidence: 99%

“…There exist a few VSM control methods for DFIMs with grid synchronization loops [15,19,[23][24][25][26][27][28], but the electro-magnetic DFIM control loops in these papers differ significantly from those proposed in this paper. Usually, the following electro-magnetic DFIM control loops are employed: (i) no inner current or magnetic flux control loop [23][24][25], i. e. applying the VSM voltage amplitude and angle directly to the RSI, (ii) inner current control loop [19,26,27], (iii) inner magnetic rotor flux control loop [15], (iv) outer magnetic stator flux and inner stator current control loop [28]. For instance, the inner magnetic rotor flux control in [15] sets the active power by changing the angle between rotor and stator magnetic flux linkages and sets the reactive power by changing the magnetic rotor flux linkage amplitude, while this paper uses the inner rotor current control with the reference vector angle depending on the VSM rotor position based on [27].…”

Section: Introductionmentioning

confidence: 99%

“…Thus, a compromise between inertial support and MPPT performance has to be found. Lately, [27] proposed a feedforward torque control (FTC) for fast MPPT in combination with a freely spinning VSM, which achieves decoupling of the inertial response to RoCoF events and the MPPT during normal operation. However, [27] only considers ideal RoCoF events, i. e. neglects the interaction with the grid, whereas [11] considers the interactions of (V)SMs but only for VSM-controlled inverters, i. e. not for VSM-controlled DFIMs.…”

Section: Introductionmentioning

confidence: 99%

“…Lately, [27] proposed a feedforward torque control (FTC) for fast MPPT in combination with a freely spinning VSM, which achieves decoupling of the inertial response to RoCoF events and the MPPT during normal operation. However, [27] only considers ideal RoCoF events, i. e. neglects the interaction with the grid, whereas [11] considers the interactions of (V)SMs but only for VSM-controlled inverters, i. e. not for VSM-controlled DFIMs. Moreover, [27] only considers MPPT, but also RPPT or de-reated operation is desirable to provide additional power reserves for inertia emulation or droop control [22].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Virtual synchronous machine control for doubly-fed induction machine based wind energy conversion systems [long version]

Thommessen,

Hackl

2023

Preprint

View full text Add to dashboard Cite

show abstract

Combining virtual synchronous machine and feedforward torque control for doubly-fed induction machine based wind energy conversion systems

Cited by 2 publications

References 7 publications

Virtual synchronous machine control for doubly-fed induction machine based wind energy conversion systems [long version]

Virtual synchronous machine control for doubly-fed induction machine based wind energy conversion systems [long version]

Virtual synchronous machine control for doubly-fed induction machine based wind energy conversion systems [long version]

Contact Info

Product

Resources

About