Abstract — In this project, a design for an automated mechanism is presented for implementation in textile manufacturing processes, where an integrated system for textile fiber recognition based on artificial intelligence (AI) was added. The mechanical design of the machine was studied in terms of force, providing a robust and efficient structure that supports the integration of sensors and cameras for real - time image capture of the processed fibers. Additionally, this design included a precise feeding system and a transport mechanism that ensured the stability and correct positioning of the fibers during analysis. In parallel, an AI model was implemented to identify and classify textile fibers based on their color characteristics. A simulated dataset was generated , where each type of fiber was represented by a specific color (red, green, blue, yellow), and a simple neural network w...

This research presents the design of an automatic machine for post-harvest garlic processing, integrating 3 fundamental processes: garlic stalk cutting, garlic shelling and finally garlic peeling, in order to optimize production, improve quality and reduce costs. The development of the research is confined to farmers in the regions of Peru, contemplating the optimization and automation of 3 garlic processes, in order to allow a faster processing and relieve the farmer's workload. The initial part of the design is the cutting of garlic stalks, followed by the shelling of garlic cloves and then the peeling process, the processes have a system of vacuuming of waste and residues to obtain better product quality. The design is validated through previous research and with mechanical and electronic design software, concluding a significant improvement of 9.15% and 96% in the efficiency and qual...

This research presents the design of a system for heart rate monitoring in people suffering from hypertension. The project was developed by creating a device that includes heart rate sensors, a position sensor, a temperature sensor, and a controller. The system consists of three stages: data reception and storage, data validation and comparison, and finally visualization through a control panel that will be monitored by a physician specialized in the field. The main objective is to provide an accurate and effective tool for the constant monitoring of heart rate, which will allow a better understanding of the hypertension condition and a more personalized treatment.