journal article
Open Access
Jan 22, 2025
The Implementation of Simulation in Designing Production Expansion
Abstract
This paper addresses the design of production expansion by using simulation to optimize production and storage capacities. The primary objective is to apply the Siemens Tecnomatix Plant Simulation software version 2404 to analyze the current production process, identify potential bottlenecks, and propose improvements. The methodology involves the use of simulation to create digital models of the production process, allowing for the detection of issues and evaluation of alternative solutions without interfering with ongoing production. The novelty of this approach lies in its ability to test and optimize the production flow digitally, ensuring a smoother transition to expanded capacities. Several alternative scenarios for production expansion were developed using Siemens Tecnomatix Plant Simulation, with a focus on verifying production volumes, identifying bottlenecks, and proposing the necessary machines and technological equipment. The results of the simulations are used to assess the proposed improvements, while the layout of the process is optimized for efficient material flow. The paper also presents 3D models as part of the solution proposal. The findings demonstrate the effectiveness of simulation-based design for expanding production systems, offering a methodology that can be applied to similar manufacturing processes.
Topics
No keywords indexed for this article. Browse by subject →
References
27
[1]
Gola, A., Plinta, D., and Grznar, P. (2021, January 26–28). Modelling and simulation of reconfigurable manufacturing system for machining of casing-class parts. Proceedings of the 20th International Scientific Conference Engineering for Rural Development, Jelgava, Latvia.
10.22616/erdev.2021.20.tf333
[2]
Wicher "A Computer Simulation-Based Analysis of Supply Chains Resilience in Industrial Environment" Metalurgija (2015)
[3]
Tsai "Competence Set Expansion for Production Process Planning" NTU Manag. Rev. (2018)
[4]
Holtewert, P., and Bauernhansl, T. (2016, January 15–17). Interchangeable Product Designs for the Increase of Capacity Flexibility in Production Systems. Proceedings of the 26th Cirp Design Conference, Stockholm, Sweden.
10.1016/j.procir.2016.04.129
[5]
Sarjono "Mulyono, Planning Production Capacity Optimisation with Rough Cut Capacity Planning" Pertanika J. Soc. Sci. Humanit. (2016)
[6]
Huang "Optimal production planning with capacity reservation and convex capacity costs" Adv. Prod. Eng. Manag. (2018)
[7]
Schwarz "Optimal sales and production rollover strategies under capacity constraints" Eur. J. Oper. Res. (2021) 10.1016/j.ejor.2021.01.040
[8]
Creutznacher, T., Berger, U., Lepratti, R., and Lamparter, S. (2015, January 24–26). The transformable factory: Adapting automotive production capacities Research and Innovation in Manufacturing: Key Enabling Technologies for the Factories of the Future. Proceedings of the 48th Cirp Conference on Manufacturing Systems, Ischia, Italy.
[9]
Ojstersek "The impact of the collaborative workplace on the production system capacity: Simulation modelling vs. real-world application approach" Adv. Prod. Eng. Manag. (2021)
[10]
Glova "Business Models for the Internet of Things Environment: Emerging Markets Queries in Finance and Business (Emq 2013)" Procedia Econ. Financ. (2014) 10.1016/s2212-5671(14)00566-8
[11]
Krajcovic, M., Gabajová, G., Matys, M., Grznár, P., Dulina, L., and Kohár, R. (2021). 3D Interactive Learning Environment as a Tool for Knowledge Transfer and Retention. Sustainability, 13.
10.3390/su13147916
[12]
Marschall, M., Gregor, M., Durica, L., Vavrík, V., Bielik, T., Grznár, P., and Mozol, Š. (2022). Defining the Number of Mobile Robotic Systems Needed for Reconfiguration of Modular Manufacturing Systems via Simulation. Machines, 10.
10.3390/machines10050316
[13]
Trebuna "Transformation the Logistics to Digital Logistics: Theoretical Approach" Acta Logist. (2020) 10.22306/al.v7i4.174
[14]
Kábele, P., and Edl, M. (2019). Increasing the Efficiency of the Production Process Due to Using Methods of Industrial Engineering. Advances in Design, Simulation and Manufacturing II: Proceedings of the 2nd International Conference on Design, Simulation, Manufacturing: The Innovation Exchange, DSMIE-2019, Lutsk, Ukraine, 11–14 June 2019, Springer.
10.1007/978-3-030-22365-6_13
[15]
Sasiadek, M., Kielec, R., and Wozniak, W. (2019, January 13–14). The Application of the Dependency Structure Matrix in the Planning of Production Processes, Vision 2025: Education Excellence and Management of Innovations Through Sustainable Economic Competitive Advantage. Proceedings of the 36th IBIMA Conference, Madrid, Spain.
[16]
Manlig "Innovation of business processes by means of computer-aided simulation: Novel Trends in Production Devices and Systems" Appl. Mech. Mater. (2014) 10.4028/www.scientific.net/amm.474.67
[17]
Saderova "Layout Design Options for Warehouse Management" Pol. J. Manag. Stud. (2020)
[18]
Paska, M., Malkus, T., Rosova, A., Trebuna, P., Kacmary, P., and Behun, M. (2018, January 3–5). International commercial terms and their necessity for the logistics. Proceedings of the 8th Carpathian Logistics Congress (CLC 2018), Pregue, Czech Republic.
[19]
Balzer "Managing Growth Opportunities in The Digital Era—An Empiric Perspective of Value Creation" Pol. J. Manag. Stud. (2020)
[20]
Saniuk, S., Grabowska, S., and Straka, M. (2022). Identification of Social and Economic Expectations: Contextual Reasons for the Transformation Process of Industry 4.0 into the Industry 5.0 Concept. Sustainability, 14.
10.3390/su14031391
[21]
Balog "Criteria for the Optimization of Production Processes in Machining of Metallic Materials" Manag. Syst. Prod. Eng. (2018)
[22]
Sujova, A., Marcinekova, K., and Hittmar, S. (2017). Sustainable Optimization of Manufacturing Process Effectiveness in Furniture Production. Sustainability, 9.
10.3390/su9060923
[23]
Laciak, M., Raskayova, D., Flegner, P., Kacur, J., and Durdan, M. (2019, January 26–29). Automated system for optimizing input parameters of the UCG process. Proceedings of the 20th International Carpathian Control Conference (ICCC), Krakow-Wieliczka, Poland.
10.1109/carpathiancc.2019.8765962
[24]
Chu "Production scale expansion and congestion in two-stage network systems" Comput. Ind. Eng. (2024) 10.1016/j.cie.2024.110317
[25]
Lin "A coordinated production planning model with capacity expansion for supply chain networks" Eur. J. Ind. Eng. (2019) 10.1504/ejie.2019.10022248
[26]
Min, Z., Nie, G.H., Ming, Z., and Lihm, H. (2006, January 2). Capacity improvement of an LCM production line. Proceedings of the 3rd International Conference on Innovation & Management, Wuhan, China.
[27]
Radatz "Comparison of capacity expansion strategies for chemical production plants" Chem. Eng. Res. Des. (2019) 10.1016/j.cherd.2018.12.018
Metrics
6
Citations
27
References
Details
- Published
- Jan 22, 2025
- Vol/Issue
- 13(2)
- Pages
- 299
- License
- View
Authors
Cite This Article
Marek Kliment, Jana Kronova, Miriam Pekarcikova, et al. (2025). The Implementation of Simulation in Designing Production Expansion. Processes, 13(2), 299. https://doi.org/10.3390/pr13020299
Related
You May Also Like
Alkaline Water Electrolysis Powered by Renewable Energy: A Review
Jörn Brauns, Thomas Turek · 2020
696 citations
Various Approaches for the Detoxification of Toxic Dyes in Wastewater
Abdulmohsen K. D. Alsukaibi · 2022
357 citations
Metal Ions, Metal Chelators and Metal Chelating Assay as Antioxidant Method
İlhami Gulçin, Saleh H. Alwasel · 2022
343 citations