Recent Papers

Fiber winding has arisen as the principal cycle for carbon fiber supported plastic (CFRP) creation, and pressure control assumes a key part in upgrading the nature of the winding items. With the consistent improvement of prod uct quality and proficiency, the accuracy of the pressure control framework is continually getting to the next level. In this paper, an original strain control strategy is proposed, which can manage the fiber pressure and transport speed of the twisting system by overseeing the results of three different driven rollers (the force of the loosen up roll, the force of the attractive powder brake roller, and the speed of the expert speed roller) in three levels. The mechanical designs and dynamic models of the determined rollers and inactive rollers are laid out by considering the timevarying highlights of the roller range and dormancy. Besides, the impact of boundaries and speed minor departure from fiber pressure is researched utilizing the addition model. In this way, the control technique is proposed by applying fiber pressure in three levels accord ing to the elements of the three driven rollers. A versatile fluffy regulator is intended for tuning the PID boundaries online to control the speed of the expert speed roller. Recreation is led for checking the presentation and sta bility of the proposed strain control strategy by contrasting and those of the regular PID control technique. The outcome uncovers that the proposed strategy beats the ordinary technique. At last, an exploratory stage is developed, and the proposed framework is applied to a winding machine. The exhibition and dependability of the strain control framework are shown through a progression of examinations utilizing carbon fiber under various reference velocities and pressures. This paper proposes an original pressure control technique to manage the fiber strain and transport speed.

Copyright © 2023 keshav kumar. This is an open access article distributed under the Creative Commons Attribution License.