Water control technology aims to provide a sufficient water supply to avoid overflow. An automatic valve sluice gate made from fiberglass is preferred for water control in tidal agriculture. The mechanical valve sluice gate model can automatically release and close water discharge at a precise angle to optimize water control in tidal agriculture. The advantage of this sluice gate design is its utilization of the difference between upstream and downstream water levels on the sluice gate. A sluice gate design with a slope angle of 15° is recommended for tidal agriculture. The upstream water level should reach a height of 1.67 m for the sluice gate to open, while the downstream side should be at 0.82 m. The sluice gate will automatically open if the water level difference is 0.85 m in height and close if there is no water level difference. It is known that the flood level from the ground is 1 m to 2 m. It is suggested to elevate the land to prevent flooding for residents.

Water Control Technology, Sluice Gate, Tidal Agricultural

Bahri, Z. (2012). Aplikasi Program Matlab Pada Perhitungan Beda Tinggi Muka Air Terhadap Berat Dan Sudut Kemiringan Pintu Air Otomatis Tipe Segiempat. Jurnal Berkala Teknik. (2) 4. 256-268.

Harnita. MTS, Johnny. Bachtiar, V. (2021) KAJIAN PERBAIKAN SISTEM IRIGASI DAERAH RAWA KAPUAS KECIL II, KECAMATAN SUNGAI KAKAP, KABUPATEN KUBURAYA. JeLAST : Jurnal PWK, Laut, Sipil, Tambang. (8) 3.

Kristina Kesi Dianti, N. MTS, Johnny. Meirany, J. (2022). Studi Irigasi Tambak Udang Di Desa Sungai Pangkalan Satu Kecamatan Sungai Raya Kabupaten Bengkayang. JeLAST : Jurnal PWK, Laut, Sipil, Tambang. (9) 1.

Rizki, M. Darmawani. (2019). Perencanaan Pintu Otomatis Pada Desa Jelapat Baru Kec. Tamban. JURNAL GRADASI TEKNIK SIPIL POLITEKNIK NEGERI BANJARMASIN. (3) 2.

Tahir, M. Musa, R. (2020). Kajian Koefisien Kekasaran Manning (N) Pasangan Batu Dan Beton Berdasarkan Kuantifikasi Kekasaran Hidrolis (Studi Kasus Daerah Irigasi Wawotobi Kab. Konawe Sultra). Jurnal Teknik Sipil MACCA Universitas Muslim Indonesia. (5) 2.

Udayakumar, R., & Thandaveswara, B. S. (2014). Effect Of Inlet Submergence On Flow Characteristics Through Sluice Gates. International Journal of Research in Engineering and Technology, 3(1), 173-177.

Vatankhah, A. R., & Ghorbani, M. A. (2015). Experimental Study On The Discharge Coefficient Of Sluice Gate. Water Science and Engineering, 8(1), 25-32.

Shahiri, H., Tabarestani, M., & Gheisari, M. (2018). Investigating The Effects Of Guide Walls On The Performance Of Sluice Gates Using Physical And Numerical Modeling. Journal of Applied Water Engineering and Research, 6(3), 189-198.

Wang, X., Yang, S., Yang, K., & Fang, H. (2019). Influence Of Flow Direction On Discharge Characteristics Of A Submerged Sluice Gate. Water Science and Engineering, 12(1), 59-65.

Shao, S., & Liu, Z. (2020). Flow Characteristics Of A Sluice Gate With Different Gate Openings: A Numerical Study. Journal of Hydroinformatics, 22(5), 1237-1248.

Hassan, Y. A., & Ismail, M. (2020). Performance Of Double Weir-Slotted Sluice Gate In Regulating Flow Under Subcritical Condition. Journal of Water Supply: Research and Technology-Aqua, 69(2), 121-133.

Fathabadi, H., & Naghibi, M. (2020). Investigation Of Gate Sill Influence On Flow Characteristics Through Sluice Gates. Water Science and Technology: Water Supply, 20(1), 144-153.

Sengul, O., Kocaman, S., & Yavuz, M. (2021). Experimental Investigation Of Flow Control Through A Sluice Gate Using Shape Memory Alloy Actuators. Journal of Irrigation and Drainage Engineering, 147(10).

Alqahtani, F. A., & Al-Salloum, Y. A. (2021). Numerical Modeling Of Flow Over Sluice Gate For Different Gate Openings Numerical Modeling Of Flow Over Sluice Gate For Different Gate Openings. Journal of Hydrology and Hydromechanics, 69(3), 264-271.

Poudel, S. R., & Vamsi, K. V. (2021). Performance Evaluation Of Sluice Gate For Flow Regulation In Irrigation Canals. International Journal of Advanced Research in Engineering and Technology, 12(2), 109-117.