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Abstract Power plants take fresh water from waterways for cooling purposes then discharge it back to the waterways in almost the same quantity but with temperature rise about 10 QC above ambient. Egypt needs annually about 7 milliards rrr’ from Nile River and 3.7 milliards m3 from the seas for cooling purposes of thirty five power plants. Thermal water has ecological and hydraulic impacts. The ecological impacts include a reduction in the ability of water to hold dissolved oxygen that is necessary for fish life also thermal water change the quality of water. The hydraulic impacts include recirculation/transport of thermal water from the outlet of the plant to the inlet of the same/different plant. The objective of this research is to find a scheme to minimize the impacts of the plants effluent by using multi port diffusers to discharge ambient water at the plants outlet channel to be mixed with thermal discharge in order to achieve effective reduction of the outlet water temperature before discharge thermal water to the river to comply with law 48/1982 which specified that the maximum allowable temperature rise above ambient water is 5 QC and a maximum discharge temperature is 35 QC. The laboratory study using a physical model investigates the sensitivity of the temperature reduction and wave height due to the change in seven dimensionless parameters and a formula developed to predict the temperature reduction and the formed wave height in accep accuracy. The new technique of using diffusers applied at Nubaria power plant physical model which has narrow channel and thermal discharge reaches to other side bank. The new technique reduced the water temperature by amount of 20 % to 30 % than using the ordinary outlet which comply with law 48/1982. The new technique used at numerical model of Kureimat power plant and succeeded in reducing the thermal spreading in the Nile River. |