Abstract
During composite manufacturing, minimizing the residual void content is a key issue to ensure optimal mechanical performance of final products. For injection processes such as Resin Transfer Molding (RTM), the impregnation velocity has a direct impact on void creation at the flow front by mechanical entrapment of air bubbles. Previous work proposed to study capillary imbibition in fibrous reinforcement to determine optimal filling conditions during practical manufacturing. The objective of this study is to investigate further this possibility. For that purpose, an improved experimental procedure is proposed to estimate the optimal impregnation velocity from capillary rise tests and understand its effect in parts of varying geometry. Capillary rise experiments were carried out with an enhanced experimental protocol, and a new post processing technique was evaluated to analyze the results. The position of the capillary flow front was then used to deduce the optimal impregnation velocity range based on the Lucas-Washburn flow model. A series of injections were also carried out with a laboratory scale RTM mold to study the influence of flow velocity on the residual void content. Results show that the prediction from capillary characterization is close to the optimal velocity value deduced from manufacturing experiments. The study also highlights the importance of void transport during processing and suggests that the injection strategy (i.e., flow rate history) and the mold configuration (i.e., divergent versus convergent flow) are important process parameters that may influence void content and cycle time.
Highlights
Liquid Composite Molding (LCM) processes such as Resin Transfer Molding (RTM) are increasingly used to manufacture high performance composites structures in a large number of industrial applications [1,2,3]
The analyses presented in this investigation focus on void creation by mechanical entrapment during the injection stage
The principle of capillary rise measurements consists of dipping a fabric sample in a probe liquid in order to study the wicking behavior of the porous medium
Summary
Liquid Composite Molding (LCM) processes such as Resin Transfer Molding (RTM) are increasingly used to manufacture high performance composites structures in a large number of industrial applications (aerospace, ground transport, etc.) [1,2,3]. This strategy has been successfully applied in numerical studies [17], but it has not yet been tested by manufacturing complex parts with the recommended flow rate profile This approach requires adequate characterization of the fiber/resin system to quantify the optimal injection speed that minimizes the residual void content. The capillary rise method has already been used to characterize the permeability, the architecture, and the capillary pressure at equilibrium in different types of granular porous materials This approach has been implemented to study the microscopic and macroscopic properties of fibrous reinforcements used in high performance composites [19,20,21,22]. The influence of the mold configuration (i.e., divergent versus convergent flows) is evaluated
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