Please use this identifier to cite or link to this item: http://hdl.handle.net/1893/36072
Appears in Collections:Computing Science and Mathematics Journal Articles
Peer Review Status: Refereed
Title: CAD-Based Design Optimization of Four-Bar Mechanisms: An Emergency Ventilator Case Study
Author(s): Ben Yahya, Abdelmajid
Van Oosterwyck, Nick
Knaepkens, Ferre
Houwen, Simon
Herregodts, Stijn
Herregodts, Jan
Vanwalleghem, Bart
Cuyt, Annie
Derammelaere, Stijn
Contact Email: annie.cuyt@stir.ac.uk
Keywords: dimensional synthesis
four-bar linkage
optimization
mechanical systems
motion control
Issue Date: 3-Mar-2023
Date Deposited: 27-Jun-2024
Citation: Ben Yahya A, Van Oosterwyck N, Knaepkens F, Houwen S, Herregodts S, Herregodts J, Vanwalleghem B, Cuyt A & Derammelaere S (2023) CAD-Based Design Optimization of Four-Bar Mechanisms: An Emergency Ventilator Case Study. <i>Designs</i>, 7 (2), p. 38. https://doi.org/10.3390/designs7020038
Abstract: The design optimization of mechanisms is promising as it results in more energy-efficient machines without compromising performance. However, machine builders do not apply state-of-the-art methods, as these algorithms require case-specific theoretical analysis. Moreover, the design synthesis approaches in the literature predominantly utilize heuristic optimizers, leading to suboptimal local minima. This paper introduces a widely applicable workflow, guaranteeing the global optimum. The constraints describing the feasible region of the possible designs are essential to find the global optimum. Therefore, kinematic analysis of the point-to-point planar four-bar mechanism is discussed. Within the feasible design space, objective value samples were generated through the CAD multi-body software. These motion simulations determine the required torque to fulfill the movement for a combination of design parameters. This replaces the cumbersome analytic derivation of the torque. This paper introduces sparse interpolation techniques to avoid brute force sampling of the design space. The advantage of this approach is that it is easily scalable to more design parameters, as the interpolation method minimizes the number of necessary samples. This paper explains the mathematical background of our developed interpolation approach. However, a step-by-step procedure is introduced to allow the employment of the interpolation technique by machine designers without the necessity to understand the underlying mathematics. Finally, the mathematical expression, obtained from the interpolation, enables applying global optimizers. In a case study of an emergency ventilator mechanism with three design parameters, 1870 CAD motion simulations allowed reducing the RMS torque of the mechanism by 67%
DOI Link: 10.3390/designs7020038
Rights: Copyright: © 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/)
Licence URL(s): http://creativecommons.org/licenses/by/4.0/

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