Detail publikačního výsledku

Testbed 4.0: The cooling system design

BLAŽÍK, M.; KANTOR, M.; MICHALKOVÁ, S.; WOJNAROWSKÝ, K.; JANOUŠEK, T.; ARM, J.

Originální název

Testbed 4.0: The cooling system design

Anglický název

Testbed 4.0: The cooling system design

Druh

Stať ve sborníku v databázi WoS či Scopus

Originální abstrakt

The Testbed 4.0 project serves as a physical demonstrator of industrial production designed for testing advanced control strategies and algorithms. This paper focuses on the architecture of a cooling cell, one of the production units within the demonstrator. The cooling cell generates and distributes cold via a closed-loop liquid circuit to other units requiring thermal regulation. A mathematical model of the thermal system was developed in MATLAB/Simulink using measured and estimated parameters, including thermal capacities, flow rate, and heat transfer resistances. Several configurations were simulated to assess the impact of pipe insulation and geometry on temperature profiles. Results confirm that proper thermal design significantly improves cooling efficiency and the cooling aggregate is capable to meet thermal requirements of selected cells. The model will be further refined using measured data once the physical system is completed. In future work, the validated model will be integrated into a predictive control framework (MPC) and used to coordinate multiple cooling requests in a decentralized manner via Asset Administration Shell (AAS) interfaces, aligning with Industry 4.0 principles.

Anglický abstrakt

The Testbed 4.0 project serves as a physical demonstrator of industrial production designed for testing advanced control strategies and algorithms. This paper focuses on the architecture of a cooling cell, one of the production units within the demonstrator. The cooling cell generates and distributes cold via a closed-loop liquid circuit to other units requiring thermal regulation. A mathematical model of the thermal system was developed in MATLAB/Simulink using measured and estimated parameters, including thermal capacities, flow rate, and heat transfer resistances. Several configurations were simulated to assess the impact of pipe insulation and geometry on temperature profiles. Results confirm that proper thermal design significantly improves cooling efficiency and the cooling aggregate is capable to meet thermal requirements of selected cells. The model will be further refined using measured data once the physical system is completed. In future work, the validated model will be integrated into a predictive control framework (MPC) and used to coordinate multiple cooling requests in a decentralized manner via Asset Administration Shell (AAS) interfaces, aligning with Industry 4.0 principles.

Klíčová slova

Cooling system, testbed, industrial control, mod eling, simulation

Klíčová slova v angličtině

Cooling system, testbed, industrial control, mod eling, simulation

Autoři

BLAŽÍK, M.; KANTOR, M.; MICHALKOVÁ, S.; WOJNAROWSKÝ, K.; JANOUŠEK, T.; ARM, J.

Rok RIV

2026

Vydáno

29.04.2025

Nakladatel

Brno University of Technology, Faculty of Electrical Engineering and Communication

Místo

Brno

ISBN

978-80-214-6320-2

Kniha

Proceedings II of the 31st Conference STUDENT EEICT 2025

Periodikum

Proceedings II of the Conference STUDENT EEICT

Stát

Česká republika

Strany od

52

Strany počet

4

BibTex

@inproceedings{BUT201231,
  author="Michal {Blažík} and Matěj {Kantor} and Soňa {Michalková} and Kryštof {Wojnarowský} and Tomáš {Janoušek} and Jakub {Arm}",
  title="Testbed 4.0: The cooling system design",
  booktitle="Proceedings II of the 31st Conference STUDENT EEICT 2025",
  year="2025",
  journal="Proceedings II of the Conference STUDENT EEICT",
  pages="4",
  publisher="Brno University of Technology, Faculty of Electrical Engineering and Communication",
  address="Brno",
  isbn="978-80-214-6320-2"
}