Design of an IoT-Based Air Quality System with Web Integration in a Palm Oil Mill Environment

Sigid Nur Rohim; Uyock Anggoro Saputro

doi:10.30871/jaic.v9i4.9876

Authors

Sigid Nur Rohim Universitas Amikom Yogyakarta
Uyock Anggoro Saputro Universitas Amikom Yogyakarta

DOI:

https://doi.org/10.30871/jaic.v9i4.9876

Keywords:

Internet of Things, Air Quality, Gas Sensor, Web Application, Palm Oil Industry

Abstract

This research aims to design and implement an Internet of Things (IoT)-based air quality monitoring system with real-time data integration to web applications in the PT Gemareksa Mekarsari palm oil mill environment. This system utilizes NodeMCU ESP32 as the main microcontroller connected with MQ-2 and MQ-135 sensors to detect CO, CH₄, and NH₃ gases. Data is sent in real-time to the ThingSpeak platform and displayed through a responsive web dashboard. Testing was conducted over two days at three different location points (open area, fruit processing, and factory office) with a total of 45 measurements. Results showed that the system was able to transmit data with a delivery accuracy rate of 86.67%, with most data received without delay.. The detected gas concentrations were within safe limits, although mild fluctuations occurred, especially in the fruit processing area. The system also showed stable performance in displaying data on mobile and desktop devices. Thus, this system can be an effective solution for automatic and real-time industrial air monitoring, and support efforts to mitigate health risks due to air pollution.

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[1] H. Li, C. Yu, R. Chen, J. Li, en J. Li, “Novel ionic liquid-type Gemini surfactants: Synthesis, surface property and antimicrobial activity”, Colloids Surfaces A Physicochem. Eng. Asp., vol. 395, nr. tourism, pp. 116–124, feb. 2012, doi: 10.1016/j.colsurfa.2011.12.014.

[2] L. Pengabdian e.a., “Data Mining Menggunakan Metode Naive Bayes Untuk Menetapkan Standar Untuk Produk Minyak Sawit Mentah Abdul Sidik”, EJECTS E-Journal Comput. Technol. Informations Syst., vol. 3, nr. 2, pp. 52–58, 2024.

[3] M. Faisal, “Eksperimen Pembakaran dalam Boiler untuk Evaluasi Kinerja dan Emisi Menggunakan Bahan Bakar Padat Kelapa Sawit”, J. Serambi Eng., vol. IX, nr. 3, pp. 10175–10183, 2024, [Online]. https://jse.serambimekkah.id/index.php/jse/article/view/422

[4] A. D. Prakoso en T. Wellem, “Perancangan dan Implementasi Sistem Pemantauan Kualitas Udara berbasis IoT menggunakan Wemos D1 Mini dan Android”, Build. Informatics, Technol. Sci., vol. 4, nr. 3, pp. 1246–1254, 2022, doi: 10.47065/bits.v4i3.2498.

[5] M. G. Salasa, A. Rosadi, en N. Fahriani, “Perancangan Alat Monitoring Polusi Udara Berbasis Mikrokontroler Menggunakan Sensor Gas TGS-2442”, Comput. Insight J. Comput. Sci., vol. 3, nr. 1, pp. 1–8, jul. 2021, doi: 10.30651/ci:jcs.v3i1.9146.

[6] L. T. J. Turangan, H. Riogilang, en C. J. Supit, “Pengaruh Penggunaan Eco-Enzyme Terhadap Kualitas Udara Di Tempat Pembuangan Akhir Sumompo Kota Manado”, Tekno, vol. 22, nr. 88, pp. 1389–1397, 2024.

[7] R. Sih Harsanti en R. Mustika Yasi, “Implementation of Ammonia (NH3) Gas Level Detection Tool in the Shrimp Processing Industry”, J. Educ. Eng. Environ., vol. 1, nr. 2, pp. 22–25, 2023, doi: 10.36526/jeee.v1i2.2853.

[8] G. Hergika, Siswanto, en S. S, “Perancangan Internet of Things (Iot) Sebagai Kontrol Infrastuktur Dan Peralatan Toll Pada Pt. Astra Infratoll Road”, PROSISKO J. Pengemb. Ris. dan Obs. Sist. Komput., vol. 8, nr. 2, pp. 86–98, 2021, doi: 10.30656/prosisko.v8i2.3862.

[9] M. Rizal, A. Arifin, M. F. Rasyd, A. A. M. Suradi, en A. Bahtiar, “Desain dan Implementasi Sistem Pemantauan Polusi Udara Berbasis Android Real-Time di SMKS Darul Ulum Layoa Bantaeng”, MALCOM Indones. J. Mach. Learn. Comput. Sci., vol. 3, nr. 2, pp. 143–152, 2023, doi: 10.57152/malcom.v3i2.894.

[10] A. Ferrari, A. Kubilay, D. Derome, en J. Carmeliet, “The use of permeable and reflective pavements as a potential strategy for urban heat island mitigation”, Urban Clim., vol. 31, p. 100534, mrt. 2020, doi: 10.1016/j.uclim.2019.100534.

[11] A. Octaviano, S. Sofiana, D. O. Agustino, en P. Rosyani, “Pemantauan Kualitas Udara Berbasis Internet O Things”, Media Online), vol. 3, nr. 2, pp. 147–156, 2022, [Online]. Beschikbaar op: https://djournals.com/klik

[12] T. N. Hakim en M. F. Susanto, “Sistem Monitoring Kualitas Udara Berbasis Internet of Things”, Pros. 11th Ind. Res. Work. Natl. Semin., nr. 1, pp. 26–27, 2020.

[13] A. Silvia, R. . Halimatussa’diyah2, R. Rizky Aldi, en N. Latifah, “Perancangan Wireless Sensor Network Menggunakan Teknologi Multisensor Sebagai Sistem Monitoring Kualitas Udara”, J. Qua Tek., vol. 10, nr. 2, pp. 1–13, 2020, doi: 10.35457/quateknika.v10i2.1189.

[14] A. M. Rumagit e.a., “Perancangan Sistem Monitoring Kualitas Udara Dalam Ruangan Berbasis Internet of Things”, pp. 1–8, 2018.

[15] R. Muttaqin, W. S. W. Prayitno, N. E. Setyaningsih, en U. Nurbaiti, “Rancang Bangun Sistem Pemantauan Kualitas Udara Berbasis Iot (Internet Of Things) dengan Sensor DHT11 dan Sensor MQ135”, J. Pengelolaan Lab. Pendidik., vol. 6, nr. 2, pp. 102–115, 2024, doi: 10.14710/jplp.6.2.102-115.

[16] S. Sadi, S. Mulyati, en P. B. Setiawan, “Internet of Things Pada Sistem Monitoring Kualitas Udara Menggunakan Web Server”, Formosa J. Multidiscip. Res., vol. 1, nr. 4, pp. 1085–1094, 2022, doi: 10.55927/fjmr.v1i4.679.

[17] D. Margaritis, C. Keramydas, I. Papachristos, en D. Lambropoulou, “Calibration of Low-cost Gas Sensors for Air Quality Monitoring”, Aerosol Air Qual. Res., vol. 21, nr. 11, p. 210073, 2021, doi: 10.4209/aaqr.210073.

Design of an IoT-Based Air Quality System with Web Integration in a Palm Oil Mill Environment

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