TY - GEN
T1 - Reduction of Defects in Flexographic Material Production
T2 - 10th International Conference on Industrial and Business Engineering, ICIBE 2024
AU - Valverde Torres, Miguel Arturo
AU - Miranda Lozano, Luz Mishelle
AU - Maradiegue Tuesta, Fernando
N1 - Publisher Copyright:
© 2024 Copyright held by the owner/author(s).
PY - 2025/4/28
Y1 - 2025/4/28
N2 - The graphic industry faces an ongoing problem: printing defects, which, despite their impact, have not been widely studied. Globally, the demand for commercial printing is expected to grow by 24%. In Peru, this sector plays a significant role in the economy. According to INEI, it is part of the manufacturing industry, contributing 12.5% to the national GDP and employing 8.5% of the Economically Active Population (EAP). Additionally, in 2021, it saw a 7.3% increase in sales. This study proposes an innovative model to tackle this issue by combining AI-driven digital technologies with industrial engineering tools. Defects affect more than just finances; they also lead to customer loss and damage to a company’s reputation. Key causes include poor design procedures, printer malfunctions, failure to follow proper storage practices, and prolonged storage, all of which contribute to defective prints and the use of degraded raw materials. In response, various improvements have been implemented, including method studies, work standardization, planned maintenance, adherence to good storage practices, and the use of Economic Order Quantity (EOQ) and Demand Driven Material Requirements Planning (DDMRP). The main contribution of this study is the identification and validation of a model that helps graphic companies overcome challenges in quality and order fulfillment. The model was tested using Arena simulation software and implemented in a Peruvian company specializing in commercial printing. The results showed a 12.03% decrease in defect rates (from 17.59% to 5.56%), an increase in the meantime between failures by 400.7 hours (from 46.35 to 447.05 hours), and a reduction in defective raw materials from 23.81% to 11.11%. Additionally, the capacity of the printing and storage processes has been optimized. According to the Process Capability Analysis, the capability of the printing process increased from 0.73 to 3.22 and that of the storage process from 0.54 to 2.09, making them capable processes that ensure a high level of quality. In conclusion, the improvement model narrowed the technical gap, boosting quality in the graphic sector, and leading to greater customer satisfaction and higher profits.
AB - The graphic industry faces an ongoing problem: printing defects, which, despite their impact, have not been widely studied. Globally, the demand for commercial printing is expected to grow by 24%. In Peru, this sector plays a significant role in the economy. According to INEI, it is part of the manufacturing industry, contributing 12.5% to the national GDP and employing 8.5% of the Economically Active Population (EAP). Additionally, in 2021, it saw a 7.3% increase in sales. This study proposes an innovative model to tackle this issue by combining AI-driven digital technologies with industrial engineering tools. Defects affect more than just finances; they also lead to customer loss and damage to a company’s reputation. Key causes include poor design procedures, printer malfunctions, failure to follow proper storage practices, and prolonged storage, all of which contribute to defective prints and the use of degraded raw materials. In response, various improvements have been implemented, including method studies, work standardization, planned maintenance, adherence to good storage practices, and the use of Economic Order Quantity (EOQ) and Demand Driven Material Requirements Planning (DDMRP). The main contribution of this study is the identification and validation of a model that helps graphic companies overcome challenges in quality and order fulfillment. The model was tested using Arena simulation software and implemented in a Peruvian company specializing in commercial printing. The results showed a 12.03% decrease in defect rates (from 17.59% to 5.56%), an increase in the meantime between failures by 400.7 hours (from 46.35 to 447.05 hours), and a reduction in defective raw materials from 23.81% to 11.11%. Additionally, the capacity of the printing and storage processes has been optimized. According to the Process Capability Analysis, the capability of the printing process increased from 0.73 to 3.22 and that of the storage process from 0.54 to 2.09, making them capable processes that ensure a high level of quality. In conclusion, the improvement model narrowed the technical gap, boosting quality in the graphic sector, and leading to greater customer satisfaction and higher profits.
KW - Artificial Intelligence
KW - DDMRP
KW - Defects
KW - Graphic Industry
UR - https://www.scopus.com/pages/publications/105008284503
U2 - 10.1145/3716097.3716121
DO - 10.1145/3716097.3716121
M3 - Contribución a la conferencia
AN - SCOPUS:105008284503
T3 - ICIBE 2024 - 10th International Conference on Industrial and Business Engineering
SP - 46
EP - 57
BT - ICIBE 2024 - 10th International Conference on Industrial and Business Engineering
PB - Association for Computing Machinery, Inc
Y2 - 20 December 2024 through 22 December 2024
ER -