CN109654162B - 主动复合变阻尼转动控制装置 - Google Patents
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Abstract
本发明涉及系统中振动的抑制领域,公开了一种主动复合变阻尼转动控制装置,其包括变阻尼模块和动力模块;变阻尼模块包括磁流变液箱和转动惯量轮,磁流变液箱内部填充满磁流变液,转动惯量轮设置于磁流变液箱内,磁流变液箱的两个圆形端面内设置有电磁线网;动力模块包括装置管腔、驱动器、编码器和变速器,驱动器固定在装置管腔内壁上,驱动器的一端安装有编码器,另一端与变速器连接,驱动器的驱动轴穿过变速器、伸入磁流变液箱与转动惯量轮的中心垂直固定。本发明的转动惯量轮的转动阻尼可以自动调节,调节精度高,调节范围广,系统应用范围大,本发明具有更大的鲁棒性,控制效果不会因结构形式改变以及外部荷载作用的改变而受到较大影响。
Description
技术领域
本发明涉及系统中振动的抑制领域,具体而言,涉及一种主动复合变阻尼转动控制装置。
背景技术
近年来,高速公路、铁路、桥梁、高层建筑、大跨度空间结构等不断兴建,海洋平台、宇宙空间站等结构也迅速发展。这些工程设施、结构在使用过程中往往会在外部荷载的作用下产生振动,严重的会产生摇摆,甚至发生破坏。为了解决由结构物振动引起的各种问题,振动控制技术应运而生。
结构振动控制技术主要分为以下四个方面:主动控制、被动控制、半主动控制以及混合控制。对于各种工程结构,恰当地安装振动控制系统能够有效地减轻结构的动力响应,减轻结构的破坏或者疲劳损伤。
结构的运动通常由平动以及扭转摆动组合而成。研究表明平动调谐质量阻尼器(英文名Tuned Mass Damper,TMD)、主动质量阻尼器/主动扭矩输出装置(英文名ActiveMass Damper/Driver,AMD)由于在扭转摆动中需要提供向心力而大大减弱控制效果甚至完全失去作用,因此对回转摆振控制几乎无效。然而具有回转摆振运动特性的结构运动形式极为常见,如:悬吊结构(吊钩、吊车等)的摆动;不规则建筑在风荷载作用下的扭转摆振;海洋平台在海浪、风、冰等耦合作用下的扭转摆振;宇宙飞船、空间结构在运行过程中,由于自身姿势调整以及太阳能帆板打开引起的扭转摆振运动;高速铁路机车,由于微小激励引起的车身的扭转摆振运动等。因此需要一种特殊的控制系统,使其可以自动克服(或摆脱)重力场对控制系统自身的影响(离心力作用),或者使控制系统自身的工作/运动规律与重力场解耦,系统自振不受重力影响,从而发挥控制系统有效控制作用。
总体来讲,现有的结构振动控制系统主要具有以下不足:第一,平动TMD控制装置只能控制结构的平动运动而对回转摆振控制无效;第二,平动AMD控制装置虽然可以控制回转摆振,但是控制效率极低,无法满足使用要求;第三,被动转动惯量调谐阻尼器对回转摆振运动控制有效,但是其需要针对结构自身进行复杂的调频,对某些复杂结构控制效率较低,效果不佳,存在鲁棒性低,可控性低,适用范围小等缺点;第四,主动不可变阻尼旋转控制系统适用范围小,控制力输出有限,控制效果有限;第五,主动不可变阻尼旋转控制系统能源利用率无法保证,无法满足经济性的需求。
本发明就是在这样的背景下产生的。
发明内容
本发明的主要目的在于针对以上问题提供一种主动复合变阻尼转动控制装置。
为了实现上述目的,本发明的主动复合变阻尼转动控制装置包括变阻尼模块和动力模块;
变阻尼模块包括磁流变液箱和转动惯量轮,磁流变液箱为圆管状,内部填充满磁流变液,转动惯量轮设置于磁流变液箱内,被磁流变液包围,磁流变液箱的两个圆形端面内设置有电磁线网;
动力模块包括装置管腔和固定在装置管腔内的驱动器、编码器和变速器,装置管腔为圆筒状,垂直固定在磁流变液箱圆形端面的中心处,驱动器固定在装置管腔内壁上,驱动器的一端安装有编码器,另一端与变速器连接,驱动器的驱动轴穿过变速器、伸入磁流变液箱与转动惯量轮的中心垂直固定。
进一步的,本发明还包括驱动器支架,驱动器通过驱动器支架固定在装置管腔内。。
进一步的,本发明还包括控制器,控制器通过线路与电磁线网、驱动器和编码器连接。
进一步的,转动惯量轮为中间向内凹陷的圆饼状,外表面设置有条形凹槽或凸起,以增大与磁流变液的摩擦和接触面积。
进一步的,驱动器的驱动轴通过法兰联轴盘与转动惯量轮连接。
进一步的,被控结构安装于装置管腔上,转动惯量轮平行于被控结构的转动面。
进一步的,驱动器、变速器和编码器同轴。
进一步的,变速器为减速器。
进一步的,驱动器为伺服电机或步进电机。
本发明具有以下有益效果:
(1)本发明的转动惯量轮的转动阻尼可以自动调节,调节精度高,调节范围广,系统应用范围大;
(2)本发明具有更大的鲁棒性,控制效果不会因结构形式改变以及外部荷载作用的改变而受到较大影响;
(3)本发明适用于适合结构发生转动、扭转或回转摆振运动的情况,适用范围广。
附图说明
图1是本发明结构示意图;
图2是本发明磁流变液箱结构示意图;
图3是本发明在单摆结构中安装示意图;
其中,上述附图包括以下附图标记:1、磁流变液箱;2、转动惯量轮;3、装置管腔;4、驱动器;5、编码器;6、变速器;7、被控结构;8、电磁线网;9、控制器;10、驱动器支架。
具体实施方式
下面结合附图对本发明作进一步说明。
本实施例以单摆结构模型为基本力学模型原型的结构为例;
如图1-3所示,本发明的主动复合变阻尼转动控制装置包括变阻尼模块和动力模块;变阻尼模块包括磁流变液箱1和转动惯量轮2,动力模块包括装置管腔3和固定在装置管腔内的驱动器4、编码器5和变速器6,被控结构7安装于装置管腔上,转动惯量轮平行于被控结构的发生扭转摆振的面。
磁流变液箱为圆管状,由两个圆形端面和一个圆筒围成一个密封空间,内部填充满磁流变液,转动惯量轮设置于磁流变液箱内,被磁流变液包围,转动惯量轮为中间向内凹陷的圆饼状,外表面设置有条形凹槽或凸起,这些条形凹槽或凸起可以增大与磁流变液的摩擦和接触面积;磁流变液箱的两个圆形端面内设置有电磁线网8,电磁线网通过线路与控制器9连接,控制器还与驱动器和编码器连接。
装置管腔为圆筒状,垂直固定在磁流变液箱圆形端面的中心处,驱动器通过驱动器支架10固定在装置管腔内壁上,驱动器的一端安装有编码器,另一端与变速器连接,驱动器、变速器和编码器同轴,驱动器的驱动轴穿过变速器、伸入磁流变液箱与转动惯量轮的中心通过法兰联轴盘垂直固定连接。
本实施例中,除了设置于驱动器尾端用于采集转动惯量转动数据的编码器,吊点处也设置有一个传感器,用来采集被控结构的转动数据,此处的传感器可以采用但不限于光电轴角编码器、角加速度传感器或者陀螺仪。
本发明的作用原理如下:
被控结构吊点处设置的传感器采集被控结构的摆振运动状态即摆角以及摆角加速度数据,并把被控结构状态数据传送给控制器,控制器判断是否需要进行主动控制,当被控结构发生回转摆振运动数据超出之前所设定的阈值的时候,控制器控制驱动器动作;驱动器末端同轴安装的编码器实时采集驱动器的转动情况,反馈给控制器,实现控制器与被控结构以及驱动器的闭环控制;驱动器可以根据实时测量的结构运动状态,控制转动惯量轮发生回转转动,同时通过控制电磁线网电流的大小,调节合适的磁场强度,匹配转动惯量轮转动的阻尼。转动惯量轮转动产生的反作用力作用在装置管腔上,进而传递给与装置管腔连接的被控结构上,抑制被控结构的摆动。
本发明利用了电流的磁效应和磁流变液的基本原理,通过实时采集被控结构的摆动幅度以及频率,实时更改驱动器控制的转动惯量轮的转动和转动阻尼,调节作用在被控结构上的控制力矩,调节驱动能源输出大小,控制结构的振动,保证较高的控制效率。
该装置可以应用到以下但不限于以下的力学问题基本原型运动模型中:单摆结构的自由摆动;受约束倒立摆结构的振动;刚体绕空间任意轴的定轴转动等,在实际工程中如:悬吊结构(吊钩、吊车等)的摆动;不规则建筑在风荷载作用下的扭转摆振;海洋平台在海浪、风、冰等耦合作用下的扭转摇摆振动等;宇宙飞船、空间结构在运行过程中,由于自身姿势调整以及太阳能帆板打开引起的扭转摆振运动;高速铁路机车,在高速运行过程中,由于微小激励引起的车身的扭转摇摆振动运动等。
以上所述仅为本发明的优选实施例而已,并不用于限制本发明,对于本领域的技术人员来说,本发明可以有各种更改和变化。凡在本发明的精神和原则之内,所作的任何修改、等同替换、改进等,均应包含在本发明的保护范围之内。
Claims (7)
1.一种主动复合变阻尼转动控制装置,其特征在于,
包括变阻尼模块和动力模块;
变阻尼模块包括磁流变液箱(1)和转动惯量轮(2),磁流变液箱(1)为圆管状,内部填充满磁流变液,转动惯量轮(2)设置于磁流变液箱(1)内,被磁流变液包围,磁流变液箱(1)的两个圆形端面内设置有电磁线网(8);
动力模块包括装置管腔(3)和固定在装置管腔(3)内的驱动器(4)、编码器(5)和变速器(6),装置管腔(3)为圆筒状,垂直固定在磁流变液箱(1)圆形端面的中心处,驱动器(4)固定在装置管腔(3)内壁上,驱动器(4)的一端安装有编码器(5),另一端与变速器(6)连接,驱动器(4)的驱动轴穿过变速器(6)、伸入磁流变液箱(1)与转动惯量轮(2)的中心垂直固定;
还包括控制器(9),控制器(9)通过线路与电磁线网(8)、驱动器(4)和编码器(5)连接;
被控结构(7)安装于装置管腔(3)上,转动惯量轮(2)平行于被控结构(7)的发生扭转摆振的面,被控结构(7)的吊点处设有一个传感器,传感器用于采集被控结构(7)的状态数据。
2.根据权利要求1所述的主动复合变阻尼转动控制装置,其特征在于,还包括驱动器支架(10),驱动器(4)通过驱动器支架(10)固定在装置管腔(3)内。
3.根据权利要求1所述的主动复合变阻尼转动控制装置,其特征在于,转动惯量轮(2)为中间向内凹陷的圆饼状,外表面设置有条形凹槽或凸起,以增大与磁流变液的摩擦和接触面积。
4.根据权利要求1所述的主动复合变阻尼转动控制装置,其特征在于,驱动器(4)的驱动轴通过法兰联轴盘与转动惯量轮(2)连接。
5.根据权利要求1所述的主动复合变阻尼转动控制装置,其特征在于,驱动器(4)、变速器(6)和编码器(5)同轴。
6.根据权利要求1所述的主动复合变阻尼转动控制装置,其特征在于,变速器(6)为减速器。
7.根据权利要求1所述的主动复合变阻尼转动控制装置,其特征在于,驱动器(4)为伺服电机或步进电机。
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