HANDRYER OTOMATIS DENGAN SENSOR TINGKAT KELEMBAPAN UNTUK MENGOPTIMALKAN PENGERINGAN TANGAN

Joerda Falanta; Sulaiman Sulaiman; Muhammad Ariandi; Muhammad Novrianda Dasmen

doi:10.31869/rtj.v8i1.6336

HANDRYER OTOMATIS DENGAN SENSOR TINGKAT KELEMBAPAN UNTUK MENGOPTIMALKAN PENGERINGAN TANGAN

Joerda Falanta, Sulaiman Sulaiman, Muhammad Ariandi, Muhammad Novrianda Dasmen

Sari

Conventional hand dryers often rely on manual buttons or simple infrared sensors, which can pose risks of germ transmission and limitations in responsiveness and detection accuracy. This paper proposes an innovative solution by integrating Internet of Things (IoT) technology to develop an automated hand dryer connected online using an ESP32 microcontroller. IoT technology enables remote control and real-time monitoring, enhancing cleanliness and health by reducing direct contact with the device's surface. The study includes testing proximity sensors, thermocouples, and moisture sensors to ensure optimal performance. Proximity sensors demonstrate good responsiveness within 0-5 cm, thermocouples effectively manage temperature, and moisture sensors provide appropriate audio feedback based on hand moisture conditions. The findings indicate that the IoT-integrated automated hand dryer not only improves usage efficiency but also significantly contributes to public hygiene and health, offering potential innovation in sanitation technology.
Keywords: Automated Hand Dryer, Internet of Things (IoT), ESP32 Microcontroller, Proximity Sensor, Thermocouple Sensor, Moisture Sensor

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Referensi

Anandya, G. R. “Rancang Bangµn Lengan Robot Penjepit Pcb 3 Dof Berbasis Ardµino µntµk Proses Etching PCB Otomatis”. Sµrabaya: ITS. 2019.

Andi publisher Rafiuddin Syam., 2019, Dasar Dasar Teknik Sensor, Makassar: Universitas Hasanuddin.

Andrianto Heri, 2019, Belajar cepat dan Pemograman Arduino: IF

Buntarto, M.Pd, 2020, Dasar – Dasar sistem kontrol pada kendaraan: PB

Immersa Lab. “Pengertian Proxy Sensor, jenis-jenis, dan prinsip kerja”. 2021.

Jaya, Hendra. “Desain dan Implementasi Sistem Robotika Berbasis Mikrokontroler”. Makassar: Edµkasi Mitra Grafika.2019.

J. Billingsley and J. Billingsley. “Inverse Kinematics. Essentials Dyn”. Vib. pp. 95–98. 2019.

Kadir Abdul, 2022, Simulasi Arduino: Flex Media komputindo

Kadir Abdul., 2023, Panduan praktis mempelajari aplikasi mikrokontroller dan programnya menggunakan arduino: Andi publisher

M. Khorasani.”Design and Kinematics Modeling of a Novel Haptic Device”. 5th RSI Int. Conf. Robot. Mechatronics, no. IcRoM, pp. 421–425. 2019.

M. Mµstafa, R. Misµari, and H. Daniyal. Forward Kinematics of 3 Degree of Freedom Delta Robot. no. December, pp.3–6, 2020.

PB Kadir Abdul, 2021, Simulasi Arduino: Flex Media komputindo Kadir Abdul., 2019, Panduan praktis mempelajari aplikasi mikrokontroller dan programnya menggunakan arduino

Prabowo & Mahardika. D. “Analisis Pengarµh Kecepatan dan Massa Beban pada Conveyor Belt terhadap Kµalitas Pengemasan Dan Kebµtµhan Daya dan Arµs Listrik di Bagian Prodµksi PT Indopintan Sµkses Mandiri Semarang”. µndergradµate Thesis. Semarang: µniversitas Mµhammadiyah Semarang 2019.

Rafiuddin Syam., 2023, Dasar Dasar Teknik Sensor, Makassar: Universitas Hasanuddin

Rusmad Dedy. 2019, Seri Elektronika Digital Dan Rangkaian, Bandung; CV .Pioner Jaya.

Rusmad Dedy. 2021, Seri Elektronika Digital dan Rangkaian, Bandung; CV .Pioner Jaya

Setiawan, Iwan. Bµkµ Ajar Sensor Dan Transdµser. Yogyakarta. 2019.

Sumanto.Motor Arus Bolak Balik (Motor AC), Yogyakarta: Andi Offset.

DOI: https://doi.org/10.31869/rtj.v8i1.6336