Abstract
This paper introduces a procedure in the field of computational contact mechanics to analyze contact dynamics of beams undergoing large overall motion with large deformations and in self-contact situations. The presented contact procedure consists of a contact search algorithm which is employed with two approaches to impose contact constraint. The contact search task aims to detect the contact events and to identify the contact point candidates that is accomplished using an algorithm based on intersection of the oriented bounding boxes (OBBs). To impose the contact constraint, an approach based on the complementarity problem (CP) is introduced in the context of beam-to-beam contact. The other approach to enforce the contact constraint in this work is the penalty method, which is often used in the finite element and multibody literature. The latter contact force model is compared against the frictionless variant of the complementarity problem approach, linear complementarity problem approach (LCP). In the considered approaches, the absolute nodal coordinate formulation (ANCF) is used as an underlying finite element method for modeling beam-like structures in multibody applications, in particular. The employed penalty method makes use of an internal iteration scheme based on the Newton solver to fulfill the criteria for minimal penetration. Numerical examples in the case of flexible beams demonstrate the applicability of the introduced approach in a situation where a variety of contact types occur. It was found that the employed contact detection method is sufficiently accurate when paired with the studied contact constraint imposition models in simulation of the contact dynamics problems. It is further shown that the optimization-based complementarity problem approach is computationally more economical than the classical penalty method in the case of studied 2D-problems.
Highlights
Contact between highly flexible bodies or self-contact situation in a flexible body is an important subject matter in many applications such as in wire ropes, belts, drapes and biomechanical implementations
absolute nodal coordinate formulation (ANCF) is regarded as a suitable underlying formulation to incorporate the isogeometric analysis (IGA), and in particular to be combined with the isogeometric collocation method [5] due to the feasibility of enforcing Neumann boundary conditions [14] on the higher-order degrees-of-freedom of the ANCF nodes
In the point-to-segment contact model, since the collision point between two oriented bounding boxes (OBBs) is determined according to the Cyrus–Beck algorithm, the exact contact point is identified by solving a number of closest point projection problems (CPP), see Fig. 5
Summary
Contact between highly flexible bodies or self-contact situation in a flexible body is an important subject matter in many applications such as in wire ropes, belts, drapes and biomechanical implementations. Tasora et al [66] introduced a rigid-to-flexible contact model using secondorder CCP in the frame work of geometrically exact beam with the isogeometric analysis (IGA) discretization They concluded that the employed CCP method can be regarded as an acceptable alternative to the conventional penalty method. The procedure introduced was designed for use with the mortar finite element method, and it was employed to solve problems featuring large deformations and significant sliding Their algorithm searches for potential contacting elements pairs and from which all the contributing points to the mortar integral are identified. – Proposal of a contact constraint enforcement model according to the complementarity problem method for beam-to-beam contact and in particular in the case of line-to-line contact i.e., Gauss-point-tosegment (GPTS). In order to compare against the frictionless penalty formulation, the linear complementarity problem (LCP) is selected with the Lemke’s optimizing algorithm
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