%0 Journal Article %1 nie2018technical %A Nie, Bingchuan %A Li, Jiachun %D 2018 %J Renewable Energy %K china energy renewables turbines wind %P 391 - 399 %R https://doi.org/10.1016/j.renene.2018.05.081 %T Technical potential assessment of offshore wind energy over shallow continent shelf along China coast %U http://www.sciencedirect.com/science/article/pii/S0960148118306037 %V 128 %X Offshore wind resource assessment seems to be urgently needed due to the rapid development of offshore wind energy in the coming decades. Technical potential of offshore wind energy over the sea area shallower than 250 m along China coast is investigated. To avoid erroneous estimation of wind power density, a statistical model considering sea state effect is proposed. Long-term CCMP wind field data are examined using that model to reduce uncertainties. Further, influential factors including wind power density, water depth, wind turbine size, wind farm layout and various spatial constraints are analyzed on the GIS platform. Technical potential under different scenarios are presented and discussed. It shows that wind resource at Taiwan Strait is particularly abundant, where wind power density at 70 m height can be above 900 W/m2. Technical potential is quite sensitive to the size of wind turbine. Taking the layout S1 (8 × 15 turbines in each farm, 8 rotor diameters apart between wind turbines, 20 km buffer region between neighboring farms) as an example: the total technical potential of the study area is 613 GW for rotor radius 60 m, and that for rotor radius 90 m is 1264 GW; the growth rates of technical potential with rotor radius is 19.3 GW/m roughly. Spatial constraints has significant impact on the region with water depth less than 50 m, where only 48.1% of area is available for developing wind energy and the technical potential there is about 23% of that of the study area.

@article{nie2018technical, abstract = {Offshore wind resource assessment seems to be urgently needed due to the rapid development of offshore wind energy in the coming decades. Technical potential of offshore wind energy over the sea area shallower than 250 m along China coast is investigated. To avoid erroneous estimation of wind power density, a statistical model considering sea state effect is proposed. Long-term CCMP wind field data are examined using that model to reduce uncertainties. Further, influential factors including wind power density, water depth, wind turbine size, wind farm layout and various spatial constraints are analyzed on the GIS platform. Technical potential under different scenarios are presented and discussed. It shows that wind resource at Taiwan Strait is particularly abundant, where wind power density at 70 m height can be above 900 W/m2. Technical potential is quite sensitive to the size of wind turbine. Taking the layout S1 (8 × 15 turbines in each farm, 8 rotor diameters apart between wind turbines, 20 km buffer region between neighboring farms) as an example: the total technical potential of the study area is 613 GW for rotor radius 60 m, and that for rotor radius 90 m is 1264 GW; the growth rates of technical potential with rotor radius is 19.3 GW/m roughly. Spatial constraints has significant impact on the region with water depth less than 50 m, where only 48.1% of area is available for developing wind energy and the technical potential there is about 23% of that of the study area.}, added-at = {2018-12-07T11:10:42.000+0100}, author = {Nie, Bingchuan and Li, Jiachun}, biburl = {https://www.bibsonomy.org/bibtex/2c77dc4397017d00174b091ed8cffb49a/pbett}, description = {Technical potential assessment of offshore wind energy over shallow continent shelf along China coast - ScienceDirect}, doi = {https://doi.org/10.1016/j.renene.2018.05.081}, interhash = {8168ce64975eafba1f98dec819cc4b11}, intrahash = {c77dc4397017d00174b091ed8cffb49a}, issn = {0960-1481}, journal = {Renewable Energy}, keywords = {china energy renewables turbines wind}, pages = {391 - 399}, timestamp = {2018-12-07T11:10:42.000+0100}, title = {Technical potential assessment of offshore wind energy over shallow continent shelf along China coast}, url = {http://www.sciencedirect.com/science/article/pii/S0960148118306037}, volume = 128, year = 2018 }