DESCRIPTION AN ELECTRICITY GENERATION SYSTEM TECHNICAL FIELD The present invention relates to a system for generating electrical energy with high kW power by means of two main assemblies and auxiliary assemblies, via using hydraulics, air pressure and a weight obtained from water. BACKGROUND ART Today, electricity ranks first as the indispensable energy source in our lives. For centuries, people have been doing both practice and research on easy and simple electricity generation and use. People's interest in systems and devices that will provide electricity generation continues to increase, and they carry out research and practice with all their strength and intelligence to discover new ways. Electricity generation is the process of producing primary energy from electricity and other sources. The basic principles of electricity generation were discovered by the British scientist Michael Faraday in the 1820s and early 1830s. His basic method is still used today: Electricity is generated by moving a conductive wire, such as copper, in a magnetic field. The electric generator is a circuit in which the wound conductive wires rotating in a magnet are present and which generates electric current by rotating these wires in the magnet. In order to obtain the large amounts of electrical energy we need in our homes, workplaces and industry, we need large power plants to drive electricity generators. Most power plants generate heat to drive the generator. Fossil-fuelled power plants burn natural gas, coal and oil for heat generation. Nuclear power plants produce heat by splitting uranium fuel. However, all these different types of power plants use the heat they generate to convert water into steam. The resulting vapour is supplied to the turbine connected to the electricity generator. As the water vapour passes over the thousands of blades on the turbine shaft, it rotates the turbine shaft by using the energy it has received from the heat previously generated. This rotation is the mechanical movement required by the generator to generate electricity. The electricity generated in the generator is sent to the place where it will be used with conductive wires called transmission lines. The steam coming out of the turbine, whose energy, in other words, pressure and temperature have decreased, is cooled and converted into water in the section called condenser and then sent back to the heat generating section of the power plant to be re-used. Water from the sea, lake or rivers is used to provide cooling in the condenser. In areas far from water sources, cooling towers, which are located right next to the power plant and resemble large giant chimneys when viewed from a distance, are used. The white smoke seen above these towers is water vapour. In the abstract part of the patent application with application number 2022/007119 and titled "AN ELECTRICITY GENERATION SYSTEM AND METHOD OF GENERATING ELECTRICITY WITH THIS SYSTEM", it is summarized as follows: “The invention is a system for generating electricity that can be safely used anywhere, is environmentally friendly, and can be scaled according to the amount of electrical energy desired to be obtained, and a method of generating electricity with this system.”. The invention relates to an assembly for generating electricity by means of the pressure power created by liquid fluids. In the abstract part of the utility model application with application number 2022/003258 and titled "COMPACT HYDROELECTRIC POWER PLANT", it is summarized as follows: “The invention relates to a hydroelectric power plant which can be used instead of the traditional method of using break pressure tank types and pressure breakers in water transmission lines with elevation differences and which are used in places such as houses in towns and villages, hotels and construction sites far from settlements, fish farms, water treatment plants, where electricity is not available.”. The invention relates to a compact, portable machine for generating electricity by means of hydroelectricity. Description of the Invention: The present invention relates to a system for generating electrical energy with high kW power by means of two main assemblies and auxiliary assemblies, via using hydraulics, air pressure and a weight obtained from water. In present invention, it is aimed to generate electricity with two systems assembled side by side. While generating electricity, it is ensured that electricity generation is provided by using the power of air and water in completely natural ways. A further object of the invention is to provide an integrated electricity generation system which operates in a loop. A further object of the invention is to provide a power generation system which generates electricity despite being remote from any energy unit. List of Reference Numbers 1. Discharge Cover, 2. outer tank, 3. inner tank, 4. Intermediate cover, 5. Weight, 6. Cylinder carrier, 7. Extension and shortening part, 8. Ground-fixed part, 9. Fixed hydraulic piston, 10. Fixing hydraulic piston, 11. Fixing apparatus, 12. Intermediate cover fixing slot, 13. Intermediate cover fixing apparatus, 14. Lifting spring, 15. Fixing hydraulics, 16. Pressurized water outer apparatus, 17. Pressurized water internal apparatus, 18. Air pipes, 19. Water plug, 20. Waterway inlet, 21. Pressurized water supply part, 22. Rotating shaft with pressurized water, 23. Dynamo, 24. Bottom holder, 25. Part of the water inlet to the pressure system, 26. Waterway, 27. Ground fixer, 28. Steel wire rope, 29. Buoy, 30. Air tank, 31. Compressor, 32. Control panel, 33. Sealing gasket, 34. Sealing metal gasket, 35. Bridge. Description of the Figures: Figure 1: Front view of the discharge cover. Figure 2: Top view of the outer tank and cylinder carrier. Figure 3: Side view of the outer tank and cylinder carrier. Figure 4: Perspective view of the outer tank. Figure 5: Front view of the outer tank. Figure 6: Top view of the outer tank. Figure 7: Front view of the cylinder carrier. Figure 8: Partial front view of an electricity generation system. Figure 9: View of the outer tank and discharge cover in the closed position. Figure 10: View of the outer tank and discharge cover in the open position. Figure 11: Detailed view of the intermediate cover. Figure 12: Detailed view of the intermediate cover. Figure 13: Front view of the intermediate cover. Figure 14: Top view of the intermediate cover. Figure 15: Front view of the inner tank. Figure 16: Top view of the inner tank. Figure 17: Front view of the inner tank. Figure 18: Perspective view of the inner tank. Figure 19: Installation view of outer tank, inner tank and intermediate cover. Figure 20: Installation view of outer tank, inner tank and intermediate cover. Figure 21: Installation view of discharge cover, outer tank, inner tank and intermediate cover. Figure 22: Installation view of outer tank, inner tank, intermediate cover, weight and cylinder carrier. Figure 23: Installation view of discharge cover, outer tank, inner tank, intermediate cover, weight and cylinder carrier. Figure 24: Front view of extension and shortening part. Figure 25: Perspective view of extension and shortening part. Figure 26: View of the working sequence of the extension and shortening part. Figure 27: Upper working position of extension and shortening part. Figure 28: Top view of cylinder carrier. Figure 29: Front view of the cylinder carrier. Figure 30: Front view of shaft and dynamo. Figure 31: Front view of the pressure unit. Figure 32: Horizontal position of holder hydraulic piston. Figure 33: Horizontal position of holder hydraulic piston with weight. Figure 34: Vertical position of the holder hydraulic piston. Figure 35: Top view of vertical position of the holder hydraulic piston. Figure 36: Vertical position view of the fixing hydraulic piston. Figure 37: Horizontal position view of the fixing hydraulic piston. Figure 38: The quadruple system horizontal position view of the fixing hydraulic piston. Figure 39: View of the fixing hydraulic working system. Figure 40: Lower position view of the fixing hydraulic weight. Figure 41: Upper position view of the fixing hydraulic weight. Figure 42: Front view of the air tank. Figure 43: View of the pressure system and weights of an electricity generation system. Figure 44: View of the weights of an electricity generation system. Figure 45: Installation view of outer tank, inner tank and intermediate cover. Figure 46: Installation view of outer tank, inner tank and intermediate cover. Figure 48: Top view of an electricity generation system. Figure 48: Top view of the weight. Figure 49: Top view of the outer tank, inner tank and bridge. Figure 50: Front view of weight. Figure 51: Front and top view of the buoy. Figure 52: View of the buoy operation system. Figure 53: Position view of weight with extension and shortening part. Figure 54: Position view of weight with extension and shortening part. Figure 55: Installation view of the outer tank and intermediate cover. Figure 56: Installation view of the fixing apparatus and the parts used together. Figure 57: Detailed view of the fixing apparatus and the parts used together. Figure 58: View of waterway inlet and water plug. Figure 59: Side view of water plug. Şekil 60: View of hydraulic connections. Figure 61: View of the fixing hydraulic piston connection. Detailed Description of the Invention The present invention relates to a system for generating electrical energy with high kW power by means of two main assemblies and auxiliary assemblies, via using hydraulics, air pressure and a weight obtained from water, wherein it includes: - the discharge cover (1) placed under the outer tank (2) and allowing water to be discharged when opened, - the outer tank (2), which is placed on the ground and stores the water filled into it, - the inner tank (3), which is placed inside the outer tank (2), contains the liquid for weighting, and functions as an upward and downward movement, - the intermediate cover (4) which, when the discharge cover (1) is opened, discharges the liquid between the outer boiler and the inner boiler, enables the liquid covers to be closed, weight to be obtained, and the intermediate cover to move up and down, - the weight (5) on both sides, connected to the inner tank (3) by a steel wire rope (28), raised by the weight of the inner tank (3), - the cylinder carrier (6) on the ground, which carries the outer weight (5) and the inner tank (3) by means of steel wire ropes (28), - the extension and shortening part (7) on the weight (5), two on each side, in the centre of which the weight (5) is mounted, containing a steel rope at one end, that is hydraulically fixed for lengthening and shortening the inner tank (3), - the ground-fixed part (8) on both sides in front of the weight (5), which allows the discharge cover (1) to move up and down, which acts as a rail, which contacts and closes when the extension and shortening part (7) is lowered, - the fixed hydraulic piston (9) in the weight (5) on both sides, both opening and closing at the same time, first fixing and then opening the extension and shortening part (7), - the fixing hydraulic piston (10) located on the ground, which fixes the weight (5) in two stages, first below and then above, - the fixing apparatus (11) inside the outer tank (2) for stabilising the intermediate cover (4), - the intermediate cover fixing slot (12) in the intermediate cover (4), which ensures the arrangement of the intermediate cover (4), - the intermediate cover fixing apparatus (13) for fixing the intermediate cover (4), - the lifting spring (14) that lifts the intermediate cover (4) upwards after the pressurized lifting process is finished by attaching it to the outside of the fixing apparatus (11), - the fixing hydraulics (15) located on the ground and securing the discharge cover (1), - the pressurized water outer apparatus (16) located on the ground and fixing the discharge cover (1), - the pressurized water inner apparatus (17), which enables the displacement of air and water, - the air pipes that allow pressurized air in and out (18), - the water plug (19) prevents water from descending after the pressure has been exhausted, - the waterway inlet (20), which is closed by the lifting of water after water enters, - the pressurized water supply part (21) which provides pressurized water by lowering the weight (5) located under the weight (5), - the shaft (22) rotating with pressurized water, which transfers the movement to the dynamo (23), - the dynamo generating electricity with the rotational movement it receives (23), - two bottom holders (24) located on the ground, - the pressure system water inlet device (25) for water inlet to the pressure system, - the waterway outlet that allows water to exit the system (26), - the ground fixer (27), which is the part that contains the parts located on the ground, - the steel wire rope (28) connecting the weight (5) and the inner tank (3), - the buoy that helps to adjust the level of water in the system and mechanically directs the water level (29), - the air tank, which acts in the stage of pressurizing the water and supports the system by compressing the pressurized air into it (30), - the compressor that helps to create pressurized air by compressing the air (31), - the control panel (32), which enables the realization of switching on and off and other control directives for the operation of the system, - silicone gasket (33), which is located on the underside of the intermediate cover (4) and provides sealing, - in the alternative embodiment of the invention, the metal gasket (34) located at the upperside of the silicone gasket (33), - bridge (35), which ensures the proper settlement of the ground and adjusts the stability of the system by means of steel wires (28). An electricity generation system is a system built on two main platforms. The two main platforms work in co-ordination to balance each other. The weight system installed on each platform works in order, they pressurize the water by means of auxiliary systems located at the bottom and around the platforms, by using the weight of the water taken into the system. The rotating shaft with pressurized water (22) rotating with pressurized water at the bottom of the platforms is operated to generate electricity by means of dynamo (23). It is an efficient system to be used in areas where it is difficult to generate electricity. The amount of the electricity to be produced according to the large and small size of the system is determined as the capacity. The water gaps between the parts, the gap between the outer tank (2) and the inner tank (3), the gap (10 cm) on the sides, vary if the system is built large or small. The basis is the amount of water in the inner tank (3) and the fact that the clearance on the sides increases as the height increases (e.g. for a weight of 10 tonnes, 1 centimetre clearance on the sides is sufficient). The rule here is that the water is discharged in 3 seconds when the discharge cover (1) is opened, the clearance at the bottom is always the same (10 cm). All the parts are placed and filled with water. The first movement opens the hydraulic piston (10) that fixes the discharge cover (1). The water inside is discharged, the discharge time is 3 seconds. After 3 sec., the weight fixing hydraulics (15) are opened, The inner tank (3) descends, the weight (5) rises (3 sec.). When the weight (5) rises, the fixed hydraulic piston (9) on the ground stabilises the weight (5). The hydraulic piston (10) fixing the extension and shortening part (7) on the weight (5) and the inner tank (3) are descended by 2 cm and bocome ready for pressure. The fixed hydraulic piston (9) on the ground is opened, the weight (5) pushes the water inside the pressure system by placing a weight on it and rotates the shaft (22) rotating with pressurized water. Electricity is generated by the dynamo (23) with the shaft (22) rotating with pressurized water. Preparation time for pressure is 7 sec. In 3 sec. the water is discharged; in 2 sec. the inner tank (3) is descended, the weight (5) is raised, the extension and shortening part (7) is opened; after 2 sec. the fixing hydraulics (15) are opened, taking 7 sec. in total. Obtaining and distributing the weight; the drain cover (1) is opened, the water between the inner tank (2) and the outer tank (2) and at the bottom is discharged. A weight is thus obtained. Since the resulting weight is fifteen per cent heavier than the outer weight, it descendes. When descending, it uses one third of the fifteen per cent in excess of the outer weight to descend, one third thereof to tension the springs under the intermediate cover (4) and one third thereof to ascend the discharge cover (1). The distribution of the ascending outer weight is such that when the weight (5) is connected by steel wire ropes (28) to the inner tank (3), it uses three tenths of its own weight to pull the inner tank (3) upwards and the remaining seven tenths to pressurize it. Pressure and pressurizing preparation times; pressure time is 10 seconds. Pressurizing preparation time is 7 seconds. (e.g. platform A starts pressurizing, after 7 seconds platform B, which is ready, starts pressurizing. Platform A and B pressurize together for 1.5 seconds. When platform B is pressurizing for 7 seconds, the pressure of platform A becomes ready, thus ensuring continuity. Weight (5) can be made to the desired size. If the weight of the water in the inner tank (3) that we should take as a basis corresponds to how many kilos in the inner tank (3), the weight must correspond to the same weight (for example: water is 1000 kg, weight is 1000 kg, the weight of the inner tank (3) must be 1.5 tenths of the water inside). Compressor (31) working arrangement is such that the water coming from the waterway inlet (20) fills the compressor (31) by passing through the cover, the apparatus inside it ascendes, the waterway inlet (20) is closed. The ascending apparatus closes the air outlet and opens the air inlet. The compressed air in the compressor (31) enters the tank (30) and pushes the water out by opening the plug, wherein the important thing is that the water on the water plug should be half of the water entering the tank (for example, if 100 kilos of water enters the tank, the water on the plug should be 50 kilos). The working arrangement of the extension and shortening part (7) is located on the weight (5), connected to the inner tank (3) by a steel wire rope (28) at one end, with a hydraulic piston at the other end. A movable weight is mounted in the center. There are two at the front and two at the back. When the weight (5) ascendes and the inner tank (3) descendes, the hydraulic piston opens when the spacers (4) touch the fixed place inside the outer tank (2). Together with the steel wire rope (28), the inner tank (3) extends by 2 centimeters. The inner tank (3) is separated from the intermediate cover (4) by two centimeters. The water in the inner tank (3) fills the side and bottom. Due to the metal weight of the inner tank (3), the weight (5), rotary pressure of which is ready, starts to descend and pressurizes. At 2 cm before the end of the pressure, the lower end of the extension and shortening part (7) touches the ground-fixed part (8), which is fixed on the ground. The distance between the inner tank (3) and the intermediate cover (4) is 4 cm. The distance between the weight (5) and the ground-fixed part (8) is 2 cm. At the same time, the distance between the part of the extension and shortening (7) to which the steel wire rope (28) is attached and the ground-fixed part (8) is 4 cm. One end of the extension and shortening part (7) touches to the ground-fixed part (8) so that it is fixed. When the weight (5) descendes, it pulls the inner tank (3) up by 4 cm and joins with the intermediate cover (4) and the extension and shortening part (7) is hydraulically fixed. The travel distance of the moving parts, i.e. the discharge cover (1) pulled up by the weight (5) and pulled down by the lifting springs (14), is 8 cm. With the extension and shortening (7) on the weight (5) and the hydraulic piston (10) fixing the extension and shortening (7), the inner tank (3) is pulled up, the inner tank (3) descendes by the rotation of the metal weight, the travel distance is 10 cm. As the water at the bottom of the inner tank (3) and on the sides is discharged, the weight builds up, it descendes, the distance it descendes with the weight of the water inside is 10 cm. It descends another 2 cm by opening the extension and shortening (7). It ascendes as the weight (5) pulls it up. It ascendes 12 cm with the closure of the extension and shortening (7). The intermediate cover (4) descendes by the pressure weight. By extending the inner tank (3), the pressure inside the inner tank (3) is balanced. It descendes thanks to the lifting spring (14) located underneath, its travel distance is 11 cm. The shaft (22) rotating with the water coming from the pressure unit on the ground and rotating with the pressurized water transferring the frictional power moves forward by means of the lifting spring (14) on the hydraulics. It pushes back the part it fixes, the extension and shortening distance is 2 cm, the distance of all hydraulics is the same, 2 cm. The part inside the air tank (30) rises up as water enters it, the air outlet closes and the air inlet opens, expels the water inside and the part descendes, the air inlet closes and the water inlet starts. The pressure system is located under the weight (5), pressing on the weight (5) starts to rotate the shaft (22) rotating with the pressurized water in the pressure system. There should be two of these systems, one for preparation and one for pressurization. They both provide continuity to the shaft (22) rotating with pressurized water. Hydraulic pistons are used for fixing. When opened, the part it fixes pushes the hydraulics back, when fixed, the part is fixed by pushing it forward by means of the lifting springs (14) on it. On the ground fixer (27) are the parts located on the ground: four fixed hydraulic pistons (10), two fixed hydraulic pistons (9), two grpund-fixed parts (8) in contact with the discharge cover (1) and the extension and shortening part (7), two parts under the pressure unit and the cylinder carrier (6). The pressurized water working system in which the compressor (31) is located, includes air outlet and air inlet pipes (18) and sensors. Initially it is down, the air outlet is open, water enters by itself and raises the buoy (29). The buoy (29) is lifted up by the buoyancy of the water, closing the air outlet and opening the air inlet, then the incoming air allows the water to escape. The part descendes and closes the air inlet and the water fills up again. Five percent of the water weight obtained in the amount of water between the two tanks (3)(2) and the amount of water coming out of the discharge cover (1) is used. (for example: 10 tons of water weight varies when the water discharged from the bottom and sides is 500 kilos more or less, the average is 100/5). The water entering the compressor (31) from the waterway (26), all the water discharged by the two units, enters the pressure section of the compressor (31) in 10 seconds and enters the inner tank (3) evenly from the top with pressure in 10 seconds. It takes 20 seconds for the water entering through the waterway (26) to return to the tank. The amount of water entering varies according to the weight of water obtained. What should be taken as a basis here is that the air pressure that allows the water entering the air tank in 10 seconds to come out in 10 seconds is given according to the water entering the tank. Seven tenths of a ton of weight obtained from the weight of water is used in energy production. It pressurizes for 10 seconds, the energy obtained is 56 volts per ton on average. (for example, when a weight of ten tons is obtained, seven tons of it is used in pressure, the energy is 560 volts in ten seconds. It was obtained in the R&D study. It meets the energy consumed by the compressor (31) and sensors from the energy it produces itself, it spends two tenths of the energy it produces at pressure for recycling (for example, seven tons of ten tons of weight is used in pressure, the energy obtained in ten seconds is 560 volts, it uses two tenths of this energy for recycling. Two tenths of 560 is 112 volts, this ratio is always the same, it uses two tenths of the energy it produces, it uses two tenths of the energy desired to be produced). The energy produced by the system is 44 volts per ton on average, this data was obtained in the R&D study. In the installation of the fixing hydraulic pistons (10), in terms of opening and closing time, the piston fixing the weight (5) from the top is opened 3 seconds after the piston of the first opened discharge cover (1) is opened. The waiting time of three seconds is for the water to drain between the tanks (2)(3), during which time the inner tank (3) is lowered. Weight (5) moves up. The intermediate covers (4) touch the fixed ground. The hydraulics (15), which are fixed by extension and shortening part (7), are opened, the inner tank (3) is extended by 2 cm. Water from the waterway (26) enters the system by itself. The buoy (29) inside goes up and closes the water and air inlet. The air inlet on the other side opens. The pressurized air that comes in expels the water. Sensors automatically adjust the air inlet and outlet. The inlet compressed air is filled into the pressure tank by the compressor (31). There is a silicone gasket (33) at the bottom of the intermediate cover (4). The silicone gasket (33) is designed for sealing. In the alternative embodiment, a metal gasket is used on top of the silicone gasket (33) to ensure a more solid surface fit. In this way, the sealing function lasts longer. The bridge (35), where the steel wire ropes (28) are attached from the ground, carries the weight from the ground to the steel wire ropes (28), and when the water outside the inner tank (3) ascendes, the weight of the water inside the inner tank is transferred to the bridge, ensuring that the ground is smooth.