Desain dan Simulasi Kontrol Elektropneumatik Berdasarkan Displacement Step pada Alat Panen dan Tanam Wortel
Kata Kunci:
Carrot, Displacement diagram, Electropneumatic, Fluidsim, GreenhouseAbstrak
The current manual process of planting and harvesting carrots in greenhouses is considered inefficient. Therefore, automation using electropneumatic technology presents a promising solution to enhance efficiency and agricultural yield. This research aims to design an electropneumatic installation for an automatic carrot planting and harvesting tool. The method used is design and simulation control based on a displacement diagram to determine the sequence of actuator motion. From this diagram, logical equations were formulated using Boolean algebra to form the basis of the control circuit. The entire circuit was then designed and tested through simulation using Fluidsim software. The design results show that the system requires 3 cylinders groups, three 5/2-way valves, 2 proximity sensors, and 2 gripper groups operating in six sequential stages. The simulation in Fluidsim successfully proved that the designed electropneumatic circuit can function according to the predetermined logic and working sequence. Thus, this design contributes a simulation-validated automated system design with the potential to be implemented to replace the manual harvesting and transplanting of carrotsReferensi
Ilham, O. F. (2021). Hasil tanaman wortel (Daucus carota L.) di dataran rendah pada berbagai ketebalan mulsa jerami padi. Jurnal Sains Teknologi &
Lingkungan. https://www.neliti.com/publications/486698/hasil
-tanaman-wortel-daucus-carota-l-di-dataran- rendah-pada-berbagai-ketebalan-m
Iman, A. N. (2024). Perancangan aplikasi smart greenhouse berbasis IoT untuk optimalisasi pertumbuhan sayuran. JIRE (Jurnal Informatika
& Rekayasa Elektronika). https://e- journal.stmiklombok.ac.id/index.php/jire/article/ view/1322
Hangga, N. (2024). Implementasi cascade control proses bahan cair pada mini-plant multi-produk multi- jalur. Jurnal Multidisiplin Saintek. https://ejournal.warunayama.org/index.php/kohe si/article/download/4483/4148/13669
Abdurahman, S. (2022). Pembudidayaan tanaman hortikultura dengan metode greenhouse. Prosiding Seminar Nasional Lahan Suboptimal. https://conference.unsri.ac.id/index.php/lahansub optimal/article/viewFile/2573/1509
Siagian, R. G. (2021). Rancang bangun mesin pencuci wortel tipe drum horizontal kapasitas 50 kg/jam menggunakan motor bensin sebagai penggerak. Jurnal Teknologi Mesin UDA. https://ejurnal.darmaagung.ac.id/index.php/tekno logimesin/article/view/5070/4329
Jones, V. T. (2022). Perencanaan Sistem Pneumatik sebagai Penggerak Pada Pintu Gerbong Kereta. STRING (Satuan Tulisan Riset dan Inovasi Teknologi). https://journal.lppmunindra.ac.id/index.php/STRI NG/article/view/10536/4662
Andiko, P. (2020). Aplikasi Aljabar Boolean Dalam Pengaturan Palang . Makalah IF2120 Matematika Diskrit. https://informatika.stei.itb.ac.id/~rinaldi.munir/M atdis/2020-2021/Makalah/Makalah-Matdis-
%20(109).pdf
Sofnivagi, M. (2020). Rancang Bangun Sistem Elektro Pneumatik untuk Mesin Pencetak Biobriket. Jurnal Mesin Sains Terapan, 4(1), 45. https://e- jurnal.pnl.ac.id/mesinsainsterapan/article/view/1
/1525
Fajar, M. N. (2021). Modifikasi sistem kontrol elektropneumatik advance level percobaan genap
-20 berbasis PLC dengan Menggunakan Festo
PLC FES-FC34. ITS Repository. http://repository.its.ac.id/id/eprint/85771
Mubarokah, A. M. (2021). Uji Coba Rangkaian Pneumatik Dasar Pada Silinder Single Dan Double Acting Serta Pada Percobaan Workbook Festo A1 - A6
Guna Untuk Pembuatan Modul Praktikum Pneumatik Sebagai Panduan Praktikum Mahasiswa Departemen Teknik Mesin Industri. Repository ITS. http://repository.its.ac.id/id/eprint/85558
Hadimi. (2024). Sistem Kontrol Pneumatik. PT Mafy
Media Literasi Indonesia, Solok. ISBN 978-623-
-88-5
I Gede, S. W. (2020). Otomatisasi Dalam Pandemi Dengan
Sensor Proximity. Jurnal Pengabdian Masyarakat.
https://www.researchgate.net/publication/346629
_Otomatisasi_Dalam_Pandemi_Dengan_Sen sor_Proximity
Hamzah, K. (2023). Perancangan Sistem Pneumatik PLC Trainer Berbasis Pemrograman Software Festo Fluidsim 3.6. Scientific Journal of Mechanical Engineering Kinematika. https://digilib.jgu.ac.id/131/1/Kamal%20Hamzah
Nadaval, H. (2024). Implementasi Cascade Control Proses Bahan Cair pada Mini-Plant Multi-Produk Multi- Jalur. Jurnal Multidisiplin Saintek. https://doi.org/10.3785/kohesi.v3i12.4483
Aji, N. I. (2024). Perancangan Aplikasi Smart Greenhouse Berbasis IoT untuk Optimalisasi Pertumbuhan Sayuran. JIRE (Jurnal Informatika & Rekayasa Elektronika). https://doi.org/10.36595/jire.v7i2.1322
Zakaria, H. (2020). Desain dan Simulasi Rangkaian Elektropneumatik dengan Festo Fluidsim. Syiah Kuala University Press.
Remus, C. (2021). Analysis of Pneumatic Circuits with FluidSim. Magazine of Hydraulics, Pneumatics, Tribology, Ecology, Sensorics, Mechatronics. https://hidraulica.fluidas.ro/2021/nr2/70-75.pdf
Gaadhe, S. K. (2022). Carrot Harvesting Methods: A Review. International Journal of Plant & Soil Science. https://www.researchgate.net/profile/Sarman- Gaadhe/publication/359459976_Carrot_Harvesti ng_Methods_A_Review/links/63ad3181a031003
a37adf5/Carrot-Harvesting-Methods-A- Review.pdf
Wang, F. (2022). Design and Test of Electric Driving Pneumatic Carrot Planter in Greenhouse. Nongye Jixie Xuebao Transactions of the Chinese Society of Agricultural Machinery. https://www.nyjxxb.net/index.php/journal/article
/view/1411/1405.
Feng, D. (2023). Optimized design of the pneumatic precision seed-metering device for carrots. International Journal of Agricultural and Biological Engineering. http://www.ijabe.net/article/doi/10.25165/j.ijabe.
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