Mechanical pressure converter for water desalination

The invention claimed is: 1. A pressure converter system for sustainably forcing saline water through a semi-permeable membrane, the pressure converter system comprising: a hydraulic oil pump; a hydraulic oil cylinder comprising pressurized oil generated from the hydraulic oil pump; a sustainable energy source for powering the hydraulic oil pump; a saline water cylinder containing saline water; wherein the hydraulic oil cylinder and the saline water cylinder are connected using a piston; and an electrical circuit for determining a direction of movement of the piston, wherein the electrical circuit comprises: a voltage regulator; an RS flip-flop; and a relay. 2. The pressure converter system of claim 1 , wherein the electrical circuit comprises: a first limit switch; a second limit switch; and a solenoid valve; wherein the solenoid valve is triggered to switch a direction of movement of the piston, when the piston comes in contact with the first or second limit switch. 3. The pressure converter system of claim 2 , wherein the first and second limit switches are positioned at a first end of the hydraulic oil cylinder and a second end of the saline water cylinder. 4. The pressure converter of claim 1 , wherein the voltage regulator controls a power provided to the first and second limit switches ensuring that the first and second limit switches do not overheat. 5. The pressure converter system of claim 1 , wherein pressure from the pressurized oil is transmitted to the saline water contained within the saline water cylinder, resulting in pressurized saline water. 6. The pressure converter system in accordance of claim 1 , wherein the system is used for transforming saline water into fresh water sustainably. 7. The pressure converter system of claim 1 , wherein the sustainable energy source is a ducted windmill. 8. The pressure converter system of claim 1 , wherein the system further comprises a plurality of relief valves to control an increase or decrease in pressure within the hydraulic oil cylinder and the saline water cylinder. 9. The pressure converter system of claim 1 , wherein the hydraulic oil cylinder is a double acting cylinder. 10. The pressure converter system of claim 2 , wherein the solenoid valve is a four-way valve. 11. The pressure converter system of claim 1 , wherein the saline water cylinder is made of stainless steel for resisting salinity of the saline water being stored. 12. The pressure converter system of claim 1 , wherein a plurality of hydraulic O-rings are positioned within the hydraulic oil cylinder and saline water cylinder. 13. The pressure converter system of claim 1 , wherein a plurality of hydraulic seals are positioned within the saline water cylinder to separate fluids from the hydraulic oil cylinder and saline water cylinder. 14. The pressure converter system of claim 1 , wherein the saline water cylinder is connected with a saline water reservoir. 15. The pressure converter system of claim 1 , wherein the piston is extendable and retractable. 16. A method of sustainably pressurizing seawater for penetrating through a semi-permeable membrane for desalination, the method comprising the steps of: retracting a piston from a first position to a second position owing to which oil flows through a hydraulic oil cylinder; wherein retraction of the piston creates a suction force within a seawater cylinder, thereby filling the seawater cylinder with seawater; switching a direction of movement of the piston when the piston comes in contact with a limit switch; pushing the seawater contained within the seawater cylinder towards the semi-permeable membrane; and determining a direction of movement of the piston using an electrical circuit, the electrical circuit further comprising a voltage regulator, an RS flip-flop and a relay; wherein the seawater being pushed out of the seawater cylinder is pressurized and capable of penetrating through the semi-permeable membrane. 17. The method of claim 16 , wherein a solenoid valve is used for switching the direction of movement of the piston when in contact with the limit switch. 18. The method of claim 16 , wherein movement of the piston is automatic. 19. The method of claim 16 , wherein the piston is extendable and retractable.