Robot-based automation system for the flexible preforming of single-layer cut-outs in composite industry

Due to the outstanding material properties the use of carbon fiber reinforced plastics in aerospace applications has grown rapidly during the last years. However, the manual process of creating a preform out of dry cut-outs is still very time-consuming and error-prone and thus limits an efficient use of this technology. Especially the high diversity of variants, the material properties and the complexity of the process limited an automation of the preforming process so far. In this paper an automation system is presented, which consists of a robot-based preforming end-effector and its offline path-planning. The end-effector has a highly modular and flexible design and integrates the three essential functions of the preforming process: gripping, draping and heating. Based on a detailed analysis of the geometric parameters of the preforms and its layers the task-specific layout of the end-effector is conducted. To achieve a preform in high-quality a solution for controlling the end-effector and planning the robot-path is necessary. Hence, a semi-automatic approach is developed, which incorporates the know-how of experts and automatically generates layup-curves with path-synchronous trigger signals for the end-effector. In an experimental set up the feasibility and flexibility of the automation solution could be successfully tested. The evaluation on three industrial moulds showed that the challenging requirements and the high quality standards could be met.

[1]  Gunther Reinhart,et al.  Design of an automation system for preforming processes in aerospace industries , 2011, 2011 IEEE International Conference on Automation Science and Engineering.

[2]  Gunther Reinhart,et al.  Flexible gripping technology for the automated handling of limp technical textiles in composites industry , 2011, Prod. Eng..

[3]  Oliver Meyer,et al.  Kurzfaser-Preform-Technologie zur kraftflussgerechten Herstellung von Faserverbundbauteilen , 2008 .

[4]  B. Corves,et al.  Development of a multifunctional robot end- effector system for automated manufacture of textile preforms , 2007, 2007 IEEE/ASME international conference on advanced intelligent mechatronics.

[5]  Günther Schuh,et al.  Future trends in production engineering : proceedings of the first conference of the German Academic Society for Production Engineering (WGP), Berlin, Germany, 8th-9th June 2011 , 2013 .

[6]  G. Reinhart,et al.  Novel Robot-Based End-Effector Design for an Automated Preforming of Limb Carbon Fiber Textiles , 2013 .

[7]  G. Seliger,et al.  Process Planning and Robotic Assembly System Design for Technical Textile Fabrics , 1992 .

[8]  Franco Failli,et al.  An Innovative Approach to the Automated Stacking and Grasping of Leather Plies , 2004 .

[9]  Mozafar Saadat,et al.  Industrial applications of automatic manipulation of flexible materials , 2002 .

[10]  Chokri Cherif,et al.  New solutions for the manufacturing of spacer preforms for thermoplastic textile-reinforced lightweight structures , 2010, Prod. Eng..

[11]  Christoph Greb,et al.  Development of New Preforming Processes for High Performance Fibre-Reinforced Plastic (FRP) Components , 2010 .

[12]  G. Seliger,et al.  Automated Handling of Non-Rigid Parts , 2003 .

[13]  Terje Kristoffer Lien,et al.  A novel gripper for limp materials based on lateral Coanda ejectors , 2008 .

[14]  Günther Schuh,et al.  Technology roadmapping for the production in high-wage countries , 2011, Prod. Eng..

[15]  A. Mills,et al.  Automation of carbon fibre preform manufacture for affordable aerospace applications , 2001 .

[16]  Robert Götz Strukturierte Planung flexibel automatisierter Montagesysteme für flächige Bauteile , 1991 .