Seawater which contains salt, metal components and mycobacteria is part of Indonesia's natural resources. Behind its abundance, not many benefits can be used, such as clean water to drinking water. Therefore, various technologies are needed to reduce the salt content and other components. In this study, a portable seawater purifier based on the adsorption function was used. The purification apparatus is in the form of a column, and has a series of plates that are placed as a support for the filling material in order to increase residence time and complete the purification process. Materials used as adsorbents in this study include ceramic biological balls, ammonite, volcanic rock, activated carbon and zeolite. Each material is organized in a filter bag for easy installation and cleaning. The equipment construction is arranged where in addition to the column there is also a circulation flow system for seawater to ensure the purification process can run optimally. The circulation process uses a buffer tank and a booster pump back to the column input line. The variable in this study, namely the location of the water sample at Ngobaran Beach, Gunungkidul. Another variable is the filtration rate. Based on the pH value of the TDS analysis and the adsorption results of seawater samples, it can be seen that the 2-stage adsorption process is the most optimal process configuration compared to other levels. This is because the 2-stage adsorption process obtained the smallest TDS value and the most suitable pH value for clean water. The results of this study can be an alternative for an easy and portable seawater purification method. This research can continue to be developed with innovations from the type of filling material and the configuration of the adsorption column used.

Abdelgaied, M. (2017). PERFORMANCE OF A PYRAMID SOLAR STILL WITH V-CORRUGATED ABSORBERS PLATE: EXPERIMENTAL STUDY. Twentieth International Water Technology Conference-IWTC20.

Bimantio, M. P. (2017). Effect of Grain Size and Activation Time of Zeolite to Adsorption and Desorption of NH4OH and KCL As Model of Fertilizer-Zeolite Mix. Jurnal Konversi, 6(2), 20–27.

Bimantio, M. P. (2021). Patent No. IDD0000059215. Indonesia: Kementerian Hukum dan Hak Asasi Manusia.

Bimantio, M. P., Oktavianty, H., & Widyasaputra, R. (2020). Perancangan Desain Portable Fixed-Bed Composite Adsorber Column sebagai Media Pemurnian Biodiesel dengan Sistem Packing Bed. TEKNIK, 41(3), 253–260. https://doi.org/10.14710/teknik.v41n3.32661

Iswadi, I. (2016). Rancang bangun alat pemurni air laut menjadi air minum menggunakan sistem piramida air (green house effect) bagi masyarakat pulau dan pesisir di kota Makassar. Jurnal Sains dan Pendidikan Fisika, 12(3), 300–310.

Krisdiarto, A. W., Ferhat, A., & Bimantio, M. P. (2020). Penyediaan Air Bagi Masyarakat Pesisir Terdampak Kekeringan dengan Teknologi Desalinasi Air Laut Sederhana. DIKEMAS (Jurnal Pengabdian Kepada Masyarakat), 4(2), 25–31. https://doi.org/10.32486/jd.v4i2.532

Prastuti, O. P. (2017). Pengaruh Komposisi Air Laut dan Pasir Laut Sebagai Sumber Energi Listrik. Jurnal Teknik Kimia dan Lingkungan, 1(1), 35–41.

Pratama, A., Rahmadianto, J. P. M. F., Pohan, G. A., & Susanto, E. E. (2021). Analisa Perancangan Desalinasi Air Laut Dengan Variasi Filter Tempurung Kelapa Dan Variasi Temperatur Pemanasan. Jurnal Flywheel, 12(1), 1–5.

Rosari, T., Hadi, W., & Masduqi, A. (2014). Desalinasi Air Payau Menggunakan Energi Solar Dengan Parabolic Trough. Jurnal Purifikasi, 14(1), 55–64.

Safitri, D. I. (2019). PEMANFAATAN SEKAM PADI SEBAGAI ADSORBEN PADA AIR LAUT DAN ZAT WARNA. Pharmacoscript, 2(1), 45–54.

Wibowo, E., Rokhmat, M., Sutisna, Khairurrijal, & Abdullah, M. (2017). Reduction of seawater salinity by natural zeolite (Clinoptilolite): Adsorption isotherms, thermodynamics and kinetics. Desalination, 409, 146–156. https://doi.org/https://doi.org/10.1016/j.desal.2017.01.026