Abstract
With the increasing penetration of renewable energy generation, the frequency stability of a power grid can be significantly threatened. A doubly-fed induction generator (DFIG) participates in the frequency support of a power grid by releasing kinetic energy (KE) to boost the frequency nadir (FN). However, during rotor speed restoration, it is difficult to counterbalance the size of a second frequency drop (SFD) and the rotor speed recovery duration. This paper proposes an improved torque limit-based inertial control (TLBIC) to raise the FN by releasing less kinetic energy while guaranteeing rapid frequency stabilization with reduced SFD. To this end, when detecting a disturbance, the DFIG enhances the active reference power to the torque limit, and then the active power reduces smoothly based on an exponential function until the maximum power point tracking (MPPT) curve is met, and the rotor speed reverts to the initialization operating condition along the MPPT curve. A simulation system model with various wind power penetrations is established in EMTP-RV. Results show that the proposed scheme boosts the FN at a high level with less KE and guarantees rapid frequency stabilization.
Highlights
Wind power generation has developed rapidly due to the shortage of fossil fuel and worsening environmental situations
To approach the above issues, this paper addresses an improved torque limit-based inertial control (TLBIC) scheme to raise the frequency nadir (FN) by releasing less rotational energy while guaranteeing rapid frequency stabilization with reduced second frequency drop (SFD)
When the doubly-fed induction generator (DFIG) operates at maximum power point tracking (MPPT) mode, it does not participate in system frequency response including inertia response and governor response, its active power output and rotor speed remain unchanged
Summary
Wind power generation has developed rapidly due to the shortage of fossil fuel and worsening environmental situations. As the conventional TLBIC scheme, the proposed reference power increases instantly from PMPPT(ω0) to PTlim(ω0) at t0 (see A-B trajectory in Figure 4C), so as to provide short-term frequency response.
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