Nonlinear dynamics of a cable–pulley system using the absolute nodal coordinate formulation

“…Thus, 20 elements were used for subsequent simulations. Figure 3a also indicates that the model implementation is able to capture a large dynamic variation of the wrap angle (122 degrees peak-to-peak) something which previous studies have not explicitly shown [7].…”

“…The normal force vector F n acting at a single point on the element is defined using the Hunt-Crossley model [8], which represents the surface as a non-linear spring-damper (21) where ȓ is the unit vector normal to the pulley surface at the point of contact, K n is the contact stiffness, δ is the relative "penetration" of the node into the surface, D is a damping coefficient and b is a positive constant with a value between 1 and 1.5 from the Hertz contact theory [14]. Selecting the origin at the center of the pulley with radius R and noting that a negative value of the penetration has no physical meaning, the penetration and penetration velocity are defined [7]:…”

“…It is thus well suited for cable contact problems, wherein the cable undergoes large deformations along the contact arc and mainly rigid body displacements elsewhere. While research extending the ANCF method to contact problems is limited, it has been applied to systems such as belt-drives [6], caternary-pantograph systems [4], as well as cable-pulley interactions [7,8,9].…”

“…Bulin et al [7] use the ANCF approach to model both a statically loaded cable-pulley system and an actuated system with a mass on a slope attached to one cable end and a motor on the other. While their investigation focused mainly on the frictional aspects of the contact, the researchers also examined the normal contact force distribution as a function of the wrap angle.…”

“…Experimental validation of cable models with surface contact is uncommon in the literature. The systems examined in the literature mostly consist of purely reciprocating cable motion [8,9] or systems with only small variations in the wrap angle [7]; however, there are scenarios where a dynamic cable model which can accurately depict variations in wrap angle is useful [1,10]. One such scenario is the cable and pulley systems for marine towed bodies where the cable is unconstrained on the submerged end and experiences highly dynamic loads and excitations.…”

Cable-Pulley Interaction with Dynamic Wrap Angle Using the Absolute Nodal Coordinate Formulation

“…Thus, 20 elements were used for subsequent simulations. Figure 3a also indicates that the model implementation is able to capture a large dynamic variation of the wrap angle (122 degrees peak-to-peak) something which previous studies have not explicitly shown [7].…”

“…The normal force vector F n acting at a single point on the element is defined using the Hunt-Crossley model [8], which represents the surface as a non-linear spring-damper (21) where ȓ is the unit vector normal to the pulley surface at the point of contact, K n is the contact stiffness, δ is the relative "penetration" of the node into the surface, D is a damping coefficient and b is a positive constant with a value between 1 and 1.5 from the Hertz contact theory [14]. Selecting the origin at the center of the pulley with radius R and noting that a negative value of the penetration has no physical meaning, the penetration and penetration velocity are defined [7]:…”

“…It is thus well suited for cable contact problems, wherein the cable undergoes large deformations along the contact arc and mainly rigid body displacements elsewhere. While research extending the ANCF method to contact problems is limited, it has been applied to systems such as belt-drives [6], caternary-pantograph systems [4], as well as cable-pulley interactions [7,8,9].…”

“…Bulin et al [7] use the ANCF approach to model both a statically loaded cable-pulley system and an actuated system with a mass on a slope attached to one cable end and a motor on the other. While their investigation focused mainly on the frictional aspects of the contact, the researchers also examined the normal contact force distribution as a function of the wrap angle.…”

“…Experimental validation of cable models with surface contact is uncommon in the literature. The systems examined in the literature mostly consist of purely reciprocating cable motion [8,9] or systems with only small variations in the wrap angle [7]; however, there are scenarios where a dynamic cable model which can accurately depict variations in wrap angle is useful [1,10]. One such scenario is the cable and pulley systems for marine towed bodies where the cable is unconstrained on the submerged end and experiences highly dynamic loads and excitations.…”

Cable-Pulley Interaction with Dynamic Wrap Angle Using the Absolute Nodal Coordinate Formulation

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