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  3. Volume 85, no.3, 2024
  4. RESEARCH AND DEVELOPMENT OF THE DRYING TECHNOLOGY

RESEARCH AND DEVELOPMENT OF THE DRYING TECHNOLOGY

ISTCMTM.
2024;
Volume 85(3), Number 3
: pp.17-24
https://doi.org/10.23939/istcmtm2024.03.017
Authors:
  1. Olha Lysa
  2. Andrii-Volodymyr Midyk
  3. Tomasz Więcek
1
Lviv National Agrarian University
2
Lviv Polytechnic National University, Ukraine
3
Rzeszów University of Technology, Polska

Static and dynamic characteristics of the drying process as an object of automation are experimentally determined in the work. It was established that the drying object can be represented as two linked "air" – "drying object" and has interconnected input and output parameters. A mathematical description of the static and dynamic characteristics of the drying process as an object of automatic regulation has been researched and carried out. With the help of mathematical processing of experimental data, mathematical dependences on the studied regulation channels were obtained as the transfer functions, differential equations, and acceleration curve equations. The obtained experimental time characteristics of the drying object on different control channels are approximated with an error of less than 3% by differential equations of the 1st order with a delay. The object is characterized by variable constant time and delay time values for different drying phases.

Automatic regulation
temperature
humidity
drying
regulation channel
differential equation.
  1. Automation of production processes: a study guide/ V.O.Fedynets, I.S.Vasylkivskyi, G.A. Nikolin. – Lviv:  SPOLOM, 2022.- 192 р. URL:http://www.lvivpolitechnic.com.ua/
  2. Executive devices of automation systems: educa- tional. guide/I.S. Vasylkivskyi, V.O. Fedynets, J.P. Yusyk.-Lviv: Publishing House of Lviv Poly- technic, 2020. – 220 р. URL: http://www. lvivpolitechnic.com.ua/, https://vlp.com.ua/node/ 20204.
  3. Katsuhiko Ogata, Modern Control Engineering,Pearson Education, Inc., Prentice Hall, 2010, 905р.URL: http://surl.li/sxpsm
  4. Vasyl Fedynets, Ihor Vasylkivskyi. Theory and practice of temperature measurement by thermoelectric transducers // Energy and control systems. – 2023. – Vol. 9, № 2. – P. 82–92. URL:https://science.lpnu.ua/sites/default/files/journal- paper/2023/dec/32755/jeecs-09-02-2023-paper-04-pdf            DOI:       10.23939/jeecs    ISSN:     2415-7287(Online) 2411-8028 (Print)
  5. T. A. Kinney, Proximity sensors compared: Inductive, capacitive, photoelectric and ultrasonic, Online: http://machinedesign.com/sensors/proximity-sensors- compared-inductive-capacitive-photoelectric-and- ultrasonic (accessed on 2024-03-31)
  6. T. Agarwal, Temperature sensors – Types, Working & Operation, white paper, Online: http://www.elprocus.com/temperature-sensors-types-working-operation/ (accessed on 2024-03-31)
  7. Common Actuator Types, Online: http://www. vma.org/?ActuatorTypes (accessed on 2024-03-31)
  8. 50 Sensors Applications for Smarter World, Libelium, Online: http://www.libelium.com/ top_50_iot_sensor_applications_ranking/ (accessed on 2024-03-31)
  9. Rayes, A., Salam, S. (2022). The Things in IoT: Sensors and Actuators. In: Internet of Things from Hype to Reality. Springer, Cham. https://doi.org/ 10.1007/978-3-030-90158-5_3