Tidal current energy is regarded as one of the most promising alternative energy resources for its minimal environmental footprint and high-energy density. The device used to harness tidal current energy is the tidal current turbine, which shares similar working principle with wind turbines. The high load factors resulting from the fluid properties and the predictable resource characteristics make marine currents particularly attractive for power generation. There is a paucity of information regarding various key aspects of system design encountered in this relatively new area of research. Not much work has been done to determine the characteristics of turbines running in water for kinetic energy conversion even though relevant work has been carried out on ship's propellers, wind turbines and on hydro turbines. None of these three well established areas of technology completely overlap with this new field so that gaps remain in the state of knowledge. A tidal current turbine rated at 1-3 m/s in water can result in four times as much energy per year/m2 of rotor swept area as similarly rated power wind turbine. Areas with high marine current flows commonly occur in narrow straits, between islands, and around. There are many sites worldwide with current velocities around 2.5 m/s, such as near the UK, Italy, the Philippines, and Japan. In the United States, the Florida Current and the Gulf Stream are reasonably swift and continuous currents moving close to shore in areas where there is a demand for power. In this study tidal current turbines are designed for several high tidal current areas around USA for a tidal current speed range from 1 m/s to 2.5 m/s. Several locations around USA are considered, e.g. the Gulf Stream; Mississippi River, St. Clair's river connecting Lake Huron to Lake St. Clair's; Colorado River within Cataract Canyon etc. Tidal current turbines can be classified as either horizontal or vertical axis turbines. In this study several designs from both the classifications are considered and modeled using SolidWorks. Hydrodynamic analysis is performed using SolidWorks Flow simulation software, and then optimization of the designs is performed based on maximizing the starting rotational torque and ultimate power generation capacity. From flow simulations, forces on the tidal current turbine blades and structures are calculated, and used in subsequent stress analysis using SolidWorks Simulation software to confirm structural integrity. The comparative results from this study will help in the systematic optimization of the tidal current turbine designs at various locations.
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机译:潮流能源以其最小的环境足迹和高能量密度被认为是最有前途的替代能源之一。用于利用潮流能量的设备是潮流涡轮机,它与风力涡轮机具有相似的工作原理。流体特性和可预测的资源特性导致的高负荷系数使海流特别适合发电。在这个相对较新的研究领域中,关于系统设计各个关键方面的信息很少。尽管已经在船用螺旋桨,风力涡轮机和水力涡轮机上进行了相关工作,但为确定动能转换在水中运行的涡轮机的特性所做的工作还很少。这三个完善的技术领域没有一个与这个新领域完全重叠,因此在知识状态中仍存在空白。在水中额定速度为1-3 m / s的潮流涡轮机,每年每平方米转子扫掠面积产生的能量是类似额定功率风力涡轮机的四倍。洋流高的地区通常发生在狭窄的海峡,岛屿之间和周围。全球有许多站点,当前速度约为2.5 m / s,例如在英国,意大利,菲律宾和日本附近。在美国,佛罗里达水流和墨西哥湾流是相当迅速和连续的水流,在有电力需求的地区附近向海岸移动。在本研究中,潮流涡轮机是为美国周围的几个高潮流区域设计的,潮流速度范围为1 m / s至2.5 m / s。考虑了美国各地的几个地点,例如墨西哥湾流;连接休伦湖和圣克莱尔湖的圣克莱尔河密西西比河;大瀑布峡谷内的科罗拉多河等。潮流涡轮机可以分为水平轴涡轮机或垂直轴涡轮机。在这项研究中,使用SolidWorks对两种分类的几种设计进行了考虑和建模。使用SolidWorks Flow仿真软件进行水动力分析,然后基于最大的起始旋转扭矩和最终发电量对设计进行优化。通过流动模拟,可以计算出潮流涡轮机叶片和结构上的力,并使用SolidWorks Simulation软件在随后的应力分析中使用该力来确认结构的完整性。这项研究的比较结果将有助于在各个位置进行潮流涡轮机设计的系统优化。
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