A Solution for Monitoring Temperature and Humidity at 31 Explosive Materials Company

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Author(s)

Chien Thang Vu 1,* Trung Hieu Nguyen 2

1. Thai Nguyen University of Information and Communication Technology, Vietnam

2. 31 Explosive Materials Company, Vietnam

* Corresponding author.

DOI: https://doi.org/10.5815/ijem.2024.03.05

Received: 2 Jan. 2024 / Revised: 23 Feb. 2024 / Accepted: 15 Mar. 2024 / Published: 8 Jun. 2024

Index Terms

Sensor Network, Temperature and Humidity Monitoring System, Explosive Materials Company, Ethernet Communication, Hardware and Software Solutions for Monitoring System

Abstract

Assuring product safety and quality in the explosives manufacturing process is critical today to protect worker and environmental safety. Temperature and humidity in the manufacturing plant are critical factors to consider because they can impact the manufacturing process and the quality of the final product. In this work, we design a temperature and humidity monitoring system for 31 explosive materials company using ethernet communication standard. In explosives factories, this communication standard is more suitable than other commonly used wireless communication technologies. We tested the system at 31 explosive materials factory. Test results show that the system operates stably and accurately. This system assists factory operators in increasing production efficiency, reducing dangers, and ensuring the quality of explosives.

Cite This Paper

Chien Thang Vu, Trung Hieu Nguyen, "A Solution for Monitoring Temperature and Humidity at 31 Explosive Materials Company", International Journal of Engineering and Manufacturing (IJEM), Vol.14, No.3, pp. 48-53, 2024. DOI:10.5815/ijem.2024.03.05

Reference

[1]L Manoj Kumar Yadav; K Dhineshkumar; R Mythili; B Arthi (2023). Optimization of Industrial Power Systems through Automated Humidity and Temperature Surveillance based on PLC and SCADA. 2023 4th International Conference on Electronics and Sustainable Communication Systems (ICESC).
[2]Alberto Coboi, Minh T.Nguyen, Kien T.La and Thang C.Vu (2023). Wireless Sensor Network Based Gas Monitoring System Utilizing ZigBeeTechnology. Journal of Electronics and Electrical Engineering. Volume 2 Issue 2.
[3]M. Park (2015). IEEE 802.11ah: sub-1-ghz license-exempt operation for the internet of things. IEEE Communications Magazine, vol. 53, no. 9, pp. 145-151.
[4]N. Sornin, M. Luis, T. Eirich, T. Kramp, and O.Hersent (2015). Lorawan specification. LoRa Alliance.
[5]J. Lee, Y. Kim, Y. Kwak, J. Zhang, A. Papasakellariou, T. Novlan, C. Sun and Y. Li (2016). LTE-advanced in 3GPP Rel -13/14: an evolution toward 5G. In IEEE Communications Magazine, vol. 54, no. 3, pp. 36-42.
[6]C. Gomez, J. Oller, and J. Paradells (2012). Overview and evaluation of Bluetooth low energy: An emerging low-power wireless technology. In Sensors, vol. 12, no. 9, pp. 11734-11753.
[7]Institute of Electrical and Electronics Engineers (2022). 802.3-2022 - IEEE Standard for Ethernet.
[8]Latha N, Usha Surendra, Malathi M (2021). Power Line Communication Parameters in Smart Grid for Different Power Transmission Lines. IEEE 8th Uttar Pradesh Section International Conference on Electrical, Electronics and Computer Engineering (UPCON).
[9]Emilio Mazzon (2000). Review: A Guide to the TCP/IP Protocol Suite.  ITNOW, Volume: 42, Issue: 6.