Analysis on The Influence of Sollar Irradiation And Rotational Speed of Centrifugal Submersible Pumps Efficiency in Solar Water Pump Systems Technology
Viewed = 0 time(s)
Abstract
This study aims to analyze the effect of solar irradiation and rotational speed on the efficiency of centrifugal submersible pumps in solar water pump systems. The research was conducted using measuring instruments such as the PS2-4000 Controller on a PATS system with a capacity of 5940 Wp, Autodesk Inventor 2022, Microsoft excel, and Rstudio. The independent variables used were the level of solar irradiation and rotational speed obtained every day for two weeks from 07.00 – 17.00. The dependent variable is obtained from a literature study and the PATS system used. The PATS system uses a LORENTZ PS2-4000 C-SJ17-4 centrifugal submersible pump and a PLTS with a capacity of 5940 Wp with a static head design of 20 m. Data collection was carried out based on actual data taken at the installation location of the PATS system and the velocity triangle analysis approach based on pump geometry. Data collection at the location was carried out using the pump controller PS2-4000 and COMPASS software. Data processing is done using Excel and Rstudio software. The results of data processing will be presented in the form of a curve that explains the relationship between the two or three variables studied. Based on this curve, results and conclusions can be obtained regarding the effect of solar irradiation and rotational speed on the efficiency of centrifugal submersible pumps in solar water pump systems. Data processing is done using Excel and Rstudio software. The results of data processing will be presented in the form of a curve that explains the relationship between the two or three variables studied. Based on this curve, results and conclusions can be obtained regarding the effect of solar irradiation and rotational speed on the efficiency of submersible centrifugal pumps in solar water pump systems. Data processing is done using Excel and Rstudio software. The results of data processing will be presented in the form of a curve that explains the relationship between the two or three variables studied. Based on this curve, results and conclusions can be obtained regarding the effect of solar irradiation and rotational speed on the efficiency of submersible centrifugal pumps in solar water pump systems.
Downloads
References
Aliyu, M., Hassan, G., Said, S. A., Siddiqui, M. U., Alawami, A. T., & Elamin, I. M. (2018). A review of solar-powered water pumping systems. Renewable and Sustainable Energy Reviews, 87, 61–76. https://doi.org/10.1016/j.rser.2018.02.010
Alkarrami, F., Iqbal, T., Pope, K., & Rideout, G. (2020). Dynamic Modelling of Submersible Pump Based Solar Water-Pumping System with Three-Phase Induction Motor Using MATLAB. Journal of Power and Energy Engineering, 08(02), 20–64. https://doi.org/10.4236/jpee.2020.82002
Arifin, Zaenal, Aries Jehan Tamamy, N. I. (2020). Designing a Solar Water Pump Machine to Reduce Electricity Consumption on a Home Scale. National Journal of Electrical Engineering, 9(2).
Chahartaghi, M., & Nikzad, A. (2021). Exergy, environmental, and performance evaluations of a solar water pump system. Sustainable Energy Technologies and Assessments, 43. https://doi.org/10.1016/j.seta.2020.100933
Desy Harianti. (2022). Evaluation of the Selection System for Submersible Pump Specifications Owned by PDAM Tirtauli in South Siantar District, Pematangsiantar City in 2018. ULIL ALBAB: Multidisciplinary Scientific Journal, 1(5), 984–991. https://journal-nusantara.com/index.php/JIM/article/view/221
Handoyo, Tri Wahyu, Arif Rahman Hakim, P. W. (2019). Performance Test of a DC Refrigerator as an ES making machine using Solar Power. Ministry of Maritime Affairs and Fisheries (Online), 18(2), 51–60.
Haque, A., Fernando, M., & Caputi, P. (2019). Responsible leadership, affective commitment and intention to quit: an individual level analysis. Leadership and Organization Development Journal, 40(1), 45–64. https://doi.org/10.1108/LODJ-12-2017-0397
Iqtimal, Zian, Ira Devi Sara, and S. (2018). Application of Solar Power Systems as a source of Electric Power for Water Pumps. Online Journal of Electrical Engineering (Online), 3(1), 1–8.
Journals, I. R. E. (2019). Performance Prediction of Centrifugal Pump 1, 2, 3. 3(2), 12–19.
Kadek Bayu Kusuma, Cok Gede Indra Partha, I. W. S. (2020). Design of a DC Water Pump System with a 20 kWp Tianyar Tengah PLTs as a Power Supply to Meet the Water Needs of the Banjar Bukit Lambuh Community. SPEKTRUM Journal, 7(2), 1–8.
Salilih, E. M., Birhane, Y. T., & Arshi, S. H. (2020). Performance analysis of DC type variable speed solar pumping system under various pumping heads. Solar Energy, 208, 1039–1047. https://doi.org/10.1016/j.solener.2020.08.071
Sevira Rambanisa Hamzah, Chairul G. Irianto, I. K. (2019). PLTS Systems for Agricultural Irrigation Water Pumps in the City of Depok. Scientific Journal of Electrical Engineering, 17(1), 73–86.
Silambarasan, R., & Belgacem, F. B. M. (2012). Theory of natural transform. Mathematics in Engineering. Science and Aerospace (MESA), 3, 99–124.
Suryana, A., & Sari, R. (2018). Design of a Solar Power Generation System (PLTS) as a Submersible Water Pump Power Supply. Journal of Electrical Engineering, 11(2), 1–10.
Syukron, Imam, R. (2021). Use of the Blynk Application for Remote Monitoring and Control. 15(1), 2–11.
Copyright (c) 2023 Naura Shafa, Damora Rhakasywi, Fahrudin Fahrudin (Author)
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.