Protrotection of a PWR nuclear power station against corrosion using hydrogen molecules to capture oxygen molecules

A protection Method for the primary loops metals of nuclear power plant from corrosion was investigated. Hydrogen molecules were added to the primary circuit to eliminate oxygen molecules produced by radiolysis of coolant at the reactor core. The hydrogen molecules were produced by electrolyses of water and then added when the coolant water was passing through the primary coolant circuit. Thermodynamical process and the protection methods from corrosion were discussed, the discussion emphasized on the removal of oxygen molecules as one of the protection methods, and compared with other methods .The amount of hydrogen molecules needed for complete removal of oxygen was estimated in two cases: in the case without passing the water through the oxygen removal system, and in the case of passing water through the system. A pressurized water reactor VVER was chosen to be investigated in this study. The amount of hydrogen molecules was estimated so as to eliminate completely the oxygen molecules from coolant water. The estimated value was found to be less than the permissible range for coolant water for such type of reactors.

Hydrogen Production Using Photovoltaic– Electrolyser System Based on Polymeric Exchange Membrane

Hydrogen production, vector of energy, by water electrolysis can be economically viable by using electrical energy from renewable sources such as photovoltaic solar energy. In this research was the study of solar hydrogen production using electrolyser based on polymeric exchange membrane electrolysis technology manufactured locally at the Faculty of Technical Engineering in Tartous. The experimental studies were achieved in two different methods: the first, direct coupling to the hydrogen electrolyser with PV module. The second method, designed PV-electrolyzer system consists of the following components: PV module, a maximum power point tracker (MPPT), A DC-DC converter, which is used to operate the system at the maximum power of the PV system at all times and to supply the necessary DC current to the electrolyzer, and tank hydrogen. The results showed that the second method more effective and highly efficient when compared with the first method because of the change in the intensity of solar radiation during the day. Also, results show that some additives such as (KOH) play an important role in enhancing the ionization process of the electrolyte liquid and improve process flow.