Abstract
Monitoring of the water total dissolved solids (TDS) has remarkable importance for industrial, agricultural, and domestic purposes. The controller designed and simulated in this paper controls and displays the TDS of water. This controller assembled with industrial and domestic purifiers has better control to frequent changing TDS of input water. Controller parameters in this paper are derived based on Ziegler Nicolas tuning method. Working of the controller will be explained here by discussion of several simulation models, and advantages over other controllers will also be studied. In order to have better and fast control over frequent change in TDS, a mathematical model for domestic water purification reverse osmosis (RO) system is taken from previous published paper. Then, the system model is used for testing and comparing P, PI, and PID controller; after the comparisons, a PID controller is selected because of its capability to settle fast and is then compared with constant and random TDS inputs. Task of controlling the TDS is done through real time and continuous controlling of a mixing valve.
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Jaiswal, R., Ansari, I.A. (2021). Performance Comparison of TDS Controllers for Water Purification System with Dynamic Input. In: Sharma, T.K., Ahn, C.W., Verma, O.P., Panigrahi, B.K. (eds) Soft Computing: Theories and Applications. Advances in Intelligent Systems and Computing, vol 1381. Springer, Singapore. https://doi.org/10.1007/978-981-16-1696-9_48
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