Integrative Control and Design Framework for an Actively Variable Twist Wind Turbine Blade to Increase Efficiency

Volume 2A: 44th Design Automation Conference Pub Date : 2018-08-26 DOI:10.1115/DETC2018-86098

H. K. Nejadkhaki, John F. Hall

{"title":"Integrative Control and Design Framework for an Actively Variable Twist Wind Turbine Blade to Increase Efficiency","authors":"H. K. Nejadkhaki, John F. Hall","doi":"10.1115/DETC2018-86098","DOIUrl":null,"url":null,"abstract":"A methodology for the design and control of a variable twist wind turbine blade is presented. The blade is, modular, flexible, and additively manufactured (AM). The AM capabilities have the potential to create a flexible blade with a low torsional-to-longitudinal-stiffness ratio. This enables new design and control capabilities that could be applied to the twist angle distribution. The variable twist distribution can increase the aerodynamic efficiency during Region 2 operation. The suggested blade design includes a rigid spar and flexible AM segments that form the surrounding shells. The stiffness of each segment and the actuator placement define the twist distribution. These values are used to find the optimum free shape for the blade. Given the optimum twist distributions, actuator placement, and free shape, the required amount of actuation could be determined. The proposed design process first determines the twist distribution that maximizes the aerodynamic efficiency in Region 2. A mechanical design algorithm subsequently locates a series of actuators and defines the stiffness ratio between the blade segments. The free shape twist distribution is selected in the next step. It is chosen to minimize the amount of actuation energy required to shape the twist distribution as it changes with Region 2 wind speed. Wind profiles of 20 different sites, gathered over a three-year period, are used to get the free shape. A control framework is then developed to set the twist distribution in relation to wind speed. A case study is performed to demonstrate the suggested procedure. The aerodynamic results show up to 3.8 and 3.3% increase in the efficiency at cut-in and rated speeds, respectively. The cumulative produced energy within three years, improved by up to 1.7%. The mechanical design suggests that the required twist distribution could be achieved by five actuators. Finally, the optimum free shape is selected based on the simulations for the studied sites.","PeriodicalId":138856,"journal":{"name":"Volume 2A: 44th Design Automation Conference","volume":"32 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2018-08-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Volume 2A: 44th Design Automation Conference","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1115/DETC2018-86098","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

A methodology for the design and control of a variable twist wind turbine blade is presented. The blade is, modular, flexible, and additively manufactured (AM). The AM capabilities have the potential to create a flexible blade with a low torsional-to-longitudinal-stiffness ratio. This enables new design and control capabilities that could be applied to the twist angle distribution. The variable twist distribution can increase the aerodynamic efficiency during Region 2 operation. The suggested blade design includes a rigid spar and flexible AM segments that form the surrounding shells. The stiffness of each segment and the actuator placement define the twist distribution. These values are used to find the optimum free shape for the blade. Given the optimum twist distributions, actuator placement, and free shape, the required amount of actuation could be determined. The proposed design process first determines the twist distribution that maximizes the aerodynamic efficiency in Region 2. A mechanical design algorithm subsequently locates a series of actuators and defines the stiffness ratio between the blade segments. The free shape twist distribution is selected in the next step. It is chosen to minimize the amount of actuation energy required to shape the twist distribution as it changes with Region 2 wind speed. Wind profiles of 20 different sites, gathered over a three-year period, are used to get the free shape. A control framework is then developed to set the twist distribution in relation to wind speed. A case study is performed to demonstrate the suggested procedure. The aerodynamic results show up to 3.8 and 3.3% increase in the efficiency at cut-in and rated speeds, respectively. The cumulative produced energy within three years, improved by up to 1.7%. The mechanical design suggests that the required twist distribution could be achieved by five actuators. Finally, the optimum free shape is selected based on the simulations for the studied sites.

查看原文本刊更多论文

提高效率的主动变扭风力机叶片综合控制与设计框架

提出了一种变扭风力机叶片的设计与控制方法。叶片是模块化的，灵活的，和增材制造(AM)。增材制造技术有可能制造出具有低扭转-纵向刚度比的柔性叶片。这使得新的设计和控制能力可以应用于扭转角分布。可变扭转分布可以提高区域2运行时的气动效率。建议的叶片设计包括刚性梁和柔性AM段，形成周围的外壳。每个节段的刚度和执行机构的位置决定了扭转的分布。这些值用于找到叶片的最佳自由形状。给定最佳的捻度分布、致动器位置和自由形状，就可以确定所需的致动量。所提出的设计过程首先确定了区域2中最大气动效率的捻度分布。随后，机械设计算法定位一系列执行器，并确定叶片节段之间的刚度比。下一步选择自由形状的捻度分布。选择它是为了最小化所需的驱动能量，以塑造扭曲分布，因为它随区域2风速的变化。在三年的时间里收集了20个不同地点的风廓线，用来获得自由形状。然后开发一个控制框架来设置与风速有关的捻度分布。通过一个案例研究来演示所建议的过程。气动结果表明，在切割速度和额定速度下，效率分别提高了3.8%和3.3%。三年内的累计发电量提高了1.7%。机械设计表明，五个执行机构可以实现所需的捻度分布。最后，通过对研究场地的模拟，选择出最优自由形状。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Volume 2A: 44th Design Automation Conference

自引率

0.00%

发文量