About Wind farm path analysis
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6 FAQs about [Wind farm path analysis]
Why is PATH 1 formed inside a direct-drive wind farm?
Since Path 1 is formed inside the direct-drive wind farm, it reflects the internal damping characteristics of the direct-drive wind farm. In addition, Path 2 passes through the PCC of the direct-drive wind farm and the VSC-HVDC, so it can reflect the damping characteristics of the interaction between direct-drive wind farm and VSC-HVDC.
How to determine the damping path of a direct-drive wind farm (ddwfv)?
According to Fig. 6, the path analysis of the SSO can be carried out. The closed-loop containing the DC capacitor transfer function of the direct-drive wind farm is defined as the SSO mode damping path. As a result, the damping path of the DDWFV can be obtained, which is marked by the solid ellipse (Path 1, Path 2).
What is disturbance transfer path between direct-drive wind farm and VSC-HVDC?
According to the disturbance transfer path between direct-drive wind farm and VSC-HVDC, the disturbance transfer process and the coupling relationship between the subsystems are revealed. The stability criterion of the DDWFV is obtained and the damping characteristics of the system are studied.
How to determine suitable locations for wind turbine farms?
In the present study, a novel methodology is proposed to determine the suitable locations for wind turbine farms by analyzing from the environmental perspective. In the methodology, the life cycle assessment (LCA) of wind turbines is incorporated into the decision process. The criteria are ranked using analytical hierarchy process (AHP).
Does the roughness of the ground affect the efficiency of wind farms?
The roughness of the ground directly affects the efficiency of wind farms. The use of the important criteria such as landslide, ice zone, seismicity in this FAHP–GIS framework is one of the most important aspects of this study.
Can lbwa be used for offshore wind farm location determination?
Another study (Deveci et al., 2020) proposed a new Decision-Making Level-Based Weighting Assessment (LBWA) approach based on interval-valued fuzzy-rough numbers (IVFRN). LBWA approach was used for offshore wind farm location determination. In these current studies, the lack of the above-mentioned important criteria stands out.
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