A. Sugiharto, F. Ferryanto, Harridhi Dzar Tazakka, A. Mahyuddin, A. Wibowo, S. Mihradi
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In the initial design, the maximum stress that occurs during the static loading is 353.96 MPa, exceeding the yield strength of aluminum 6061 of 276 MPa. Hence, to alleviate the exceedingly high maximum stress, three alternative structural reinforcement types are considered for a design modification. The version of reinforcement yielding the smallest maximum stress was selected in the design modification of ESAR prosthetic foot to be used in the robotic prosthetics ankle. The equivalent stiffness of the final ESAR prosthetic foot design has been calculated to be used in the control system scheme.In this study, structural analysis of energy storage and return (ESAR) prosthetic foot was carried out by using the finite element method. The basic design of the ESAR prosthetic foot consists of four main components: main plate, S-plate, base plate, and auxiliary body. SOLIDWORKS was used for modeling of ESAR prosthetic foot during the design stage. Furthermore, an ANSYS Workbench 16.2 was used to perform a finite element analysis of ESAR prosthetics foot structure. Static simulation is carried out with a loading force of 750 N representing the amount of force that is supported by the edge of the base-plate component during the push-off phase. In the initial design, the maximum stress that occurs during the static loading is 353.96 MPa, exceeding the yield strength of aluminum 6061 of 276 MPa. Hence, to alleviate the exceedingly high maximum stress, three alternative structural reinforcement types are considered for a design modification. 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引用次数: 2
摘要
本研究采用有限元法对ESAR (energy storage and return)假肢足进行结构分析。ESAR假肢足的基本设计由四个主要部件组成:主板、s板、底板和辅助体。ESAR假肢足在设计阶段采用SOLIDWORKS进行建模。利用ANSYS Workbench 16.2对ESAR义肢足部结构进行有限元分析。静态模拟以750 N的加载力进行,该加载力表示在推离阶段由底板组件边缘所支持的力的大小。在初始设计中,静加载时产生的最大应力为353.96 MPa,超过了6061铝的屈服强度276 MPa。因此,为了减轻极高的最大应力,三种可供选择的结构加固类型被考虑用于设计修改。在ESAR假肢足的设计修改中,选择最大应力最小的加固版本用于机器人假肢踝关节。计算了ESAR假肢足最终设计的等效刚度,用于控制系统方案。本研究采用有限元法对ESAR (energy storage and return)假肢足进行结构分析。ESAR假肢足的基本设计由四个主要部件组成:主板、s板、底板和辅助体。ESAR假肢足在设计阶段采用SOLIDWORKS进行建模。利用ANSYS Workbench 16.2对ESAR义肢足部结构进行有限元分析。静态模拟以750 N的加载力进行,该加载力表示在推离阶段由底板组件边缘所支持的力的大小。在初始设计中,静加载时产生的最大应力为353.96 MPa,超过了6061铝的屈服强度276 MPa。因此,为了减轻极高的最大应力,三种可供选择的结构加固类型被考虑用于设计修改。产生最小最大应力的钢筋版本…
Static analysis of an energy storage and return (ESAR) prosthetic foot
In this study, structural analysis of energy storage and return (ESAR) prosthetic foot was carried out by using the finite element method. The basic design of the ESAR prosthetic foot consists of four main components: main plate, S-plate, base plate, and auxiliary body. SOLIDWORKS was used for modeling of ESAR prosthetic foot during the design stage. Furthermore, an ANSYS Workbench 16.2 was used to perform a finite element analysis of ESAR prosthetics foot structure. Static simulation is carried out with a loading force of 750 N representing the amount of force that is supported by the edge of the base-plate component during the push-off phase. In the initial design, the maximum stress that occurs during the static loading is 353.96 MPa, exceeding the yield strength of aluminum 6061 of 276 MPa. Hence, to alleviate the exceedingly high maximum stress, three alternative structural reinforcement types are considered for a design modification. The version of reinforcement yielding the smallest maximum stress was selected in the design modification of ESAR prosthetic foot to be used in the robotic prosthetics ankle. The equivalent stiffness of the final ESAR prosthetic foot design has been calculated to be used in the control system scheme.In this study, structural analysis of energy storage and return (ESAR) prosthetic foot was carried out by using the finite element method. The basic design of the ESAR prosthetic foot consists of four main components: main plate, S-plate, base plate, and auxiliary body. SOLIDWORKS was used for modeling of ESAR prosthetic foot during the design stage. Furthermore, an ANSYS Workbench 16.2 was used to perform a finite element analysis of ESAR prosthetics foot structure. Static simulation is carried out with a loading force of 750 N representing the amount of force that is supported by the edge of the base-plate component during the push-off phase. In the initial design, the maximum stress that occurs during the static loading is 353.96 MPa, exceeding the yield strength of aluminum 6061 of 276 MPa. Hence, to alleviate the exceedingly high maximum stress, three alternative structural reinforcement types are considered for a design modification. The version of reinforcement yielding the smallest maximum stress ...
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