CN103306900B - 用于减轻离岸风力涡轮机中负载的方法和系统 - Google Patents
用于减轻离岸风力涡轮机中负载的方法和系统 Download PDFInfo
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Abstract
风力涡轮机的控制方法和系统,风力涡轮机属于离岸风厂,在负载测量系统故障情况下使用下面浆距矢量之一来计算每个叶片的变浆距指令:‑浆距矢量同时应用在负载测量系统正常工作的风厂的一个风力涡轮机中,‑浆距矢量的平均值同时应用在负载测量系统正常工作的风厂的一组风力涡轮机中;‑如果前面的浆距矢量无法使用,则使用从控制律得到的桨距矢量,所述控制律是从负载测量系统正常工作时的风力涡轮机的历史记录获得的,其将该桨距矢量定义为至少风速V的函数。
Description
技术领域
本发明涉及在风力涡轮机,且特别是离岸风力涡轮机中减轻由于风不对称产生的负载的方法和系统。
背景技术
当风力涡轮机叶片绕“转子盘”扫过,由于风切变、塔影效应、偏航误差和湍流作用,风力涡轮机经历风速和方向的改变。随着转子尺寸相对于湍流涡旋的典型尺寸增加,转子盘上湍流风速变化的重要性提高。
这些变化导致大的一个循环一次或叶片负载中的1P部件,和这些频率如2P、3P、4P等等谐频。对于三叶转子,这些负载部件在三个叶片之间会有120°异相,因此,毂和结构的其他部件将经历3P、6P等等的谐频,1P部件和其他谐频将抵消。
尽管,这个取消依赖于静止和直线性的假设,但当风力涡轮机与湍流的长度尺寸相比变得更大时,这些假设变得更少有效。
也就是说,来自1P部件和其他谐频的不对称负载不再抵消,且在这些频率上的负载分量非常有助于毂、轴、偏航轴承、塔架等的疲劳负载。
为了减少所述的损害效应,现有技术教会使用增加到总浆距控制的变桨距控制和偏航控制。用于减少所述不对称负载的浆距和/或偏航指令使用负载或由其产生的位移的测量来计算。
理论上,1P负载分量在大型风力涡轮机上特别大。可以通过在1P频率、三个叶片120°异相频率的变桨距操作来减少这些负载。这个在1P频率的变桨距操作通过控制用作输入、叶片平面外负载的控制算法来计算。
这个技术的实施例公开在US2006/002792中,描述了在风力涡轮机中减少负载并提供偏航对准的方法,包括在风力涡轮机中不对称负载的位移或力矩测量。这些测量的力矩或位移用于确定桨叶浆距角分量,努力减少或抵消不对称转子负载且使偏航系统容易对准。
如果上述位移或力矩的测量装置失效,结果是无法执行变桨距操作,现有技术指示在低产量水平运转风力涡轮机,来减少不对称转子负载,直到故障修复。
在离岸风力涡轮机的情况下,测量装置的维修可能延迟很长一段时间,涉及重要产量损失。
发明内容
本发明的一个目的是提供一个在具有用于抵消转子不对称负载的变浆距控制系统的离岸风力涡轮机的变浆距控制系统用的负载测量系统故障时,提高离岸风力涡轮机的电力产量的控制方法和系统。
本发明的另一个目的是提供一个在具有用于抵消转子不对称的变浆距控制系统的离岸风力涡轮机的变浆距控制系统用的负载测量系统故障时,减轻离岸风力涡轮机的负载的控制方法和系统。
一方面,控制方法遇到这些或其他目的,控制方法包括在负载测量系统故障情况下使用下面浆距矢量来计算每个叶片的变浆距指令的步骤:
-浆距矢量同时应用在负载测量系统正常工作的风厂的一个风力涡轮机(优选最靠近风力涡轮机)中,或浆距矢量的平均值同时应用在负载测量系统正常工作的风厂的一组风力涡轮机中;
-如果前面的浆距矢量无法使用,则使用从控制律得到的桨距矢量,所述控制律是从负载测量系统正常工作时的风力涡轮机的历史记录获得的,其将该桨距矢量定义为至少风速V的函数。
另一个方面,控制系统遇到上面提到的目的,控制系统用于执行对根据低于断流风速Vout的风速的预定功率曲线的风力涡轮机的调整,该调整包含基于负载测量系统的每个叶片的变浆距调整,其中,控制系统还用于执行替代调整,在根据替代功率曲线的负载测量系统失效情况下,相对于预定功率曲线减少电力产量,和包括用于抵消转子不对称负载的替代变浆距控制,用下面的浆距矢量来计算每个叶片的变浆距指令:
-浆距矢量同时应用在负载测量系统正常工作的风厂的至少一个风力涡轮机中,或浆距矢量的平均值同时应用在负载测量系统正常工作的风厂的一组风力涡轮机中;
-如果前面的浆距矢量无法使用,则使用从控制律得到的桨距矢量,所述控制律是从负载测量系统正常工作时的风力涡轮机的历史记录获得的,其将该桨距矢量定义为至少风速V的函数。
当风力涡轮机负载测量系统失效时,应用在风力涡轮机上的浆距矢量可以在提到的三种情况下从风厂的控制器获得或从另一个风力涡轮机(如果他们配备通讯装置)获得,或者在自己的风力涡轮机中获得(浆距矢量来源于控制律的情况下)。
结合附图、随后的发明的详细描述和所附权利要求使离岸风力涡轮机的上述方法和系统的其他合适的特征和优点变得清楚。
附图说明
图1是风力涡轮机的侧视剖面示意图。
图2是风力涡轮机的典型的功率曲线。
图3是显示总的浆距调整的浆距指令和在风力涡轮机叶片的循环中增加循环调整的浆距指令的图表。
图4显示用于本发明考虑的三种情况下风力涡轮机调整的功率曲线。
图5a和5b显示了根据本发明的变浆距控制的控制律。
具体实施方式
风厂的典型的离岸风力涡轮机11包括支撑吊舱21的塔架13,吊舱罩着将风力涡轮机转子的旋转能转换成电能的发电机19。风力涡轮机转子包括转子毂15和典型的三个叶片17。转子毂15或直接连接或通过齿轮箱连接到将转子15产生的扭矩传递给发电机19的风力涡轮机的发电机19,并提高轴转速,来获得发电机转子合适的转速。
风力涡轮机功率输出通常由调整转子叶片的浆距角和发电机扭矩的控制系统来控制。因此,风力涡轮机的转子转速和功率输出最初就被控制。
断流风速Vout以下,风力涡轮机控制系统用于根据曲线调整电力产量,该曲线定义了功率和速度之间获得理想输出的期望函数关系。这种类型的曲线是图2中的曲线25,显示了电力产量P从最小风速Vmin增加到标定风速Vn,且在标定功率值Pn保持不变,直到达到断流风速Vout时降为0。
为了实现所述调整,控制单元接受诸如风速V、发电机转速Ω、浆距角θ、功率P等来自已知测量装置的输入数据并分别发送输出数据到改变叶片17角度位置的浆距致动系统和改变电力产量参数的发电机指令单元。
控制系统还将变浆距指令应用到每个叶片,来减少由负载测量系统提供的数据计算的不对称负载。这个变浆距叠加到总浆距,用于根据图2的功率曲线25来调节电力产量。
图3中,线13代表应用在所有叶片上的总浆距指令,如沿一个叶片循环不变的浆距;而线33代表应用在沿一个叶片循环的一个叶片上的浆距指令,该浆距指令是将变浆距指令增加到总浆距指令的结果。
提供给每个叶片的变浆距指令产生如下:
-三个叶片平面外弯曲力矩信号B1、B2、B3(从来自负载测量系统的摆振(Flapwise)与挥舞(Edgewise)信号得出)转换成用帕克(Park)变换的两个正交的力矩My和Mz。
-每个轴的控制器产生浆距分量Z-Pitch和Y-Pitch,来减少或抵消不对称转子负载。
-浆距矢量,由模数M和参数A定义,用方程式M=(Z-Pitch2+Y-Pitch2)1/2,A=atan(Z-Pitch/Y-Pitch)来计算。
-浆距矢量由控制系统使用来计算应用到每个叶片的变浆距指令,首先用方程式Z-Pitch=Msin(A),Y-Pitch=Mcos(A)转换成两个正交的浆距角参数,然后用帕克(Park)变换的逆和转子方位角产生变浆距指令。
风力涡轮机的负载测量系统失效时,结果每个叶片的变浆距指令不能产生,发明目的是使用下面的浆距矢量来获得应用于每个叶片的变浆距指令:
-首先,浆距矢量同时应用在转子负载的负载测量系统正常工作的风厂的一个风力涡轮机中,或浆距矢量的平均值同时应用在负载测量系统正常工作的风厂的一组风力涡轮机中;
-其次(如果没有前面的浆距矢量可以使用),从控制律来获得浆距矢量,控制律基于负载测量系统正常工作时风力涡轮机的历史记录,定义浆距矢量至少作为风速的函数。
离岸风厂比在岸风厂的环境条件稳定性更高,允许风力涡轮机的负载系统损坏时使用可替换的浆距矢量来避免电力产量的损失。无论如何,当使用可替换的任何浆距矢量时,风力涡轮机的调整将依照次佳电力产量曲线来做以避免危险。
图4显示了分别显示了风力涡轮机标定状态、由于负载测量系统失灵而没有变浆距控制的状态和根据本发明具有可替换变浆距控制状态的功率曲线25、25’、25’’。
在上面提到的第一替换中,优选选项是用于最靠近的风力涡轮机的浆距矢量和用于风厂的浆距矢量的平均值。在第一种情况下,如果风力涡轮机具有通讯装置,涡轮机可以直接接受来自最靠近风力涡轮机的浆距矢量或其他情况下接受来自风厂控制器的浆距矢量。在第二种情况,风力涡轮机接受来自风厂控制器的浆距矢量。
上面提到的第二替换,是当第一替换由于如与风厂控制器的通讯问题而不能执行控制律时的选择,用于从负载测量系统工作正常时自己的风力涡轮机内的历史数据中获得且存储在风力涡轮机控制系统的储存装置中。
所述控制律可以是作为图5a和5b中显示的控制律的单变量规则或多变量规则,单变量规则中模数M和使用的浆距矢量的角度A只取决于风速V,多变量规则如控制律中模数M和浆距矢量的角度A取决于风速、风向。偏航位置、风切变和年周期,即,该规则将包含不同工作情况的不同曲线。
图5a和5b的曲线是二阶多项等式,从模拟离岸风力涡轮机行为带有接近1的相关因子的一套数据获得,从而,可以假定负载测量系统工作正常时,风力涡轮机控制系统使用的浆距矢量可以由上面提到的控制律来表现。
根据本发明的可替换的变浆距控制的执行是由典型的风力涡轮机控制器来实现,包括由该控制器决定的总浆距指令之后的变浆距分量。总浆距依旧是控制器关于报警和操作设置点的标准浆距参考。
根据本发明的变浆距控制的主要优点是:
-在这些用变浆距致动系统操作的离岸风力涡轮机中容易实现。
-当离岸风力涡轮机负载测量系统损坏时,可以提高涡轮机电力产量10%左右。
虽然已经结合不同实施例描述了本发明,从说明书应该理解可以做出元件的组合,变化或改进,且都在本发明的范围内。
Claims (11)
1.一种风力涡轮机的控制方法,风力涡轮机属于离岸风厂,风力涡轮机具有变桨距控制系统,用于基于负载测量系统抵消转子不对称负载,其特征在于,在负载测量系统故障情况下所述控制方法应用桨距矢量来计算风力涡轮机的每个叶片的变桨距指令,其中:
-应用在负载测量系统正常工作的风厂的一个风力涡轮机所使用的桨距矢量,或应用在负载测量系统正常工作的风厂的一组风力涡轮机所使用的桨距矢量的平均值;
-如果风厂的一个或多个风力涡轮机中所使用的桨距矢量无法获得,则应用从控制律得到的桨距矢量,所述控制律是从负载测量系统正常工作时的风力涡轮机的历史记录获得的,其将该桨距矢量定义为至少风速V的函数。
2.如权利要求1所述的风力涡轮机控制方法,其特征在于,风力涡轮机中应用的桨距矢量是用于控制最靠近的风力涡轮机的桨距矢量。
3.如权利要求1所述的风力涡轮机控制方法,其特征在于,所述控制律是风速V和下述变量中的一个或多个的函数:
-风向;
-风切变;
-偏航位置;
-年周期。
4.一种属于离岸风厂的风力涡轮机控制系统:
-控制系统连接到负载测量系统和测量装置,该测量装置是风力涡轮机的每个叶片的风速V、风向、桨距角θ、风力涡轮机的每个叶片的方位角位置ψ的至少一个的测量装置;
-控制系统至少连接到风力涡轮机的每个叶片的变桨距控制致动器和扭矩控制致动器;
-控制系统具有与风厂控制器通讯的通讯装置;
-控制系统用于根据预定功率曲线来实现风力涡轮机的调整,该功率曲线用于低于断流风速Vout的风速,包括基于负载测量系统对风力涡轮机的每个叶片的变桨距调整;
其特征在于,控制系统配置为在负载测量系统失效情况下,根据替代功率曲线执行替代调整,相对于预定功率曲线减少电力产量,并且包括应用桨距矢量来计算风力涡轮机的每个叶片的变桨距指令以抵消转子不对称负载的替代变桨距控制,其中:
-应用在负载测量系统正常工作的风厂的至少一个风力涡轮机所使用的桨距矢量,或应用在负载测量系统正常工作的风厂的一组风力涡轮机中所使用的桨距矢量的平均值;
-如果风厂的一个或多个风力涡轮机中所使用的桨距矢量无法获得,则应用从控制律得到的桨距矢量,所述控制律是从负载测量系统正常工作时的风力涡轮机的历史记录获得的,其将该桨距矢量定义为至少风速V的函数。
5.根据权利要求4所述的控制系统,其特征在于,风力涡轮机中所应用的桨距矢量是用于控制最近的风力涡轮机的桨距矢量。
6.根据权利要求4所述的控制系统,其特征在于,风力涡轮机中所应用的桨距矢量是用于控制风厂的一组风力涡轮机的桨距矢量的平均值。
7.根据权利要求4所述的控制系统,其特征在于,还包括与属于风厂的所有风力涡轮机通讯的直接通讯装置,其中,风力涡轮机中所应用的桨距矢量是用于控制最近的风力涡轮机的桨距矢量。
8.根据权利要求4所述的控制系统,其特征在于,控制律存储在风厂控制器中。
9.根据权利要求4所述的控制系统,其特征在于,控制律存储在控制系统的控制装置中。
10.根据权利要求8所述的控制系统,其特征在于,所述控制律是风速V和下述变量中的一个或多个的函数:
-风向;
-风切变;
-偏航位置;
-年周期。
11.一种离岸风力涡轮机,包括根据权利要求4所述的控制系统。
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