| WO2019098997A1 | 2019-05-23 |
| US20130019971A1 | 2013-01-24 | |||
| EP2381089A1 | 2011-10-26 | |||
| US20200208615A1 | 2020-07-02 |
| CLAIMS 1. The three tanks: (upper tank (11), middle tank (12), and lower tank (13)) in terms of shape, design, movement, and their location in the machine, and its related parts which are manifested in the following: - The funnel that on both: (the funnel of the upper tank (49) and the funnel of the upper tank (50)) where it is made of reinforced plastic; In order to reduce the total weight of the tank and reduce the cost of its manufacture, - Automatic closing drain stopper where it's existing at each of: (the bottom of the upper (5) and middle water tank funnels (6), which open and close depending to the movement of the tanks in the machine cycle as previously shown in the machine cycle phases, - The wires and cables (40) (27) attached to the automatic closing of the drain stopper, where these wires are fixed on the water tanks and passing to the automatic brake pedal box on the structure of the machine (1), - The fixed pistons (7) (51) under the middle tank which it's work to pressure on each of: (the water syringes (15.1) and the large gas springs (8)), in addition to the pistons (52) fixed in the base of the machine (42) that presses the water syringes (15.2), also the pistons (53) fixed in the machine's structure (1) which compress the water syringes (15.3), - The watercourse (54) inside the upper tank (11) of the water descending from the water turbine (2) casing, (the purpose of the watercourse (54) is to reduce the sound of water coming down and streamline flow it in the tank), - The longitudinal canal track (48) of the manual brake system on both sides of the middle tank (12). 2. The automatic brake system that manifested in: - The boxes of automatic brake pedals (30), (36) to stop the movement of the middle water tank (12), and the large gas springs (8), - The boxes for releasing the pedals of automatic brake (31), (31) after it brake the movement of the middle tank (12), and the large gas springs (8), - The double box (33) that contains a cable (41) to release the automatic brakes (36), and another cable (40) to open the drain stopper under the funnel of the upper tank (5), - The Box (34) of opening the drain stopper under the funnel of the middle tank (6), - All the parts included in item 2 of the automatic brake box parts (Fig. 8A), and the similar parts in brake pedal release boxes which are manifested by; - The box arm (21), coil spring (22), and the coil spring (55), brake pedal (23), key of release the brake pedal lock (25), key of the brake pedal (26) return after pressed its, and the associated oil pressure tubes (57), cables and wires (56), and small pulleys (58), head of the arm (24), the brake oil pressure piston rod (39), and the brake oil pressure cylinder (59), and finally the structure of the box (60) itself. 3. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; middle tank brake and hand brake (Fig. 13), where it works to brake the middle tank (12) in order to stop the machine when needed, also to resuming the work of the machine when the manual brakes are lowered that, and it's manifested by; - The middle tank's rail track (37), - The brake's jaws (38), - The common oil pressure tube (47) between the middle tank brake and the hand brake, - longitudinal canal track (48), - The system includes 4 brakes (35), distributed on four sides, on each side of the middle tank (12) there is a longitudinal canal (48) intended for the brake's jaws (38). 4. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the water syringes (15.1), (15.2), (15.3), which includes; - Four of the water syringes 1 (15.1), water syringes 2 (15.2) and water syringes 3 (15.3). So: the total is: 12 of the water syringes, - The coil spring (14.1), (14.2), (14.3) at the top of each piston arm base on the syringe (51), (52), (53), its task to completing the pressure on the remaining water at the end of each pressuring process on the water syringe, and thus keep the continuity of the flow of water on the water turbine (2), also giving enough time for the water to move between the water tanks (11), (12), (13) and reverse their movement, - The two holes in the head of each syringe (16.1.1), (16.1.2), (16.2.1), (16.2.2), (16.3.1), (16.3.2), and they're of one-way valve (Fig. 14), and the valves are automatic opening when there is water pressure on them from the direction intended for them, as each valve has a cylindrical iron tube (62) and inside it is a triangular (internal) coil spring (64) wrapped with insulation plastic material and rubber in order not to rust, and there is a solid plastic ball covered with strong rubber (63) wrapped with strong rubber inside the cylindrical tube (62) over the coil spring (64), and the ball (63) it's pressed against the hole of the valve (66) reverse the direction of water movement (65). 5. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the spiral spring water tubes (4.1), (4.2), that connected between the lower tank (13) and the water syringes (15.1), (15.2), (15.3), the total of it is: (8 tubes), and it includes four layers in terms of design, arrangement and quantity as follows; - The first layer 45% of reinforced and high-pressure rubber (68), - The second layer 7% of a carbon fiber fabric (69), - The third layer 29% of a supple plastic cover to protect the fibers in the second layer (70), - The fourth layer 19% it's a metal lattice coil spring (71) that is attached on the spiral spring water tube over the third layer in order to help supporting and carry the weight of the tube when tightened. 6. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the design and general shape of the machine structure, and what is related to it, which it's manifested in: - The steel beams (61) that carrying pistons rods of the water syringes (14.3), the water pipes (4.1), the water turbine (2) casing, the upper tank (11), the automatic brake boxes (33) and its accessories, the pulleys of the steel wire ropes (17), - The external structure (1), which it's fixes the internal parts such as fixing the water syringes (15.1), and the rail tracks and slide cylinder that fix the middle tank (12), and lower tank (13), and the movement of their rise and descent. 7. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the large gas springs (8) and the small springs (9), and it's in total: (8 gas springs), and it includes the following: - The large gas springs (8) it's 4 in total, they are distributed evenly and in parallel in the four directions of the base of the machine (42) under the lower tank (13), also 4 small gas springs (9), as shown in: (Fig. 16), - What is included in the large gas springs (8) of automatic brake pedal boxes (30), boxes (31) pedals of releasing the brakes, and the brakes themselves (28) where it's on both sides of the rail tracks (29) which are part of the inner cylinder piston head. 8. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the automatic system for lifting the middle tank (Fig. 11), which includes the following: - The steel wire ropes (18) that work to raise the middle tank (12) after its descent, and they are: 4 in total, it distributed in the four corners at the top of the middle tank (12), - The pulleys (17) for steel wires ropes (18), they're (8 Pulleys) in total, for each rope two pulleys, and they are fixed in the inner ceiling up the machine structure (1), - The coil spring (19) which ability to tighten, fixed in the base of the machine (42) and with the steel wire rope (18), - The solid cylinder (20) fixed in the steel wire rope (18) inside a tube (45) in the lower tank (13). 21 9. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; a concrete base (42) at the bottom of the machine, to secure the parts and the machine structure (1). 10. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the main shaft of the water turbine (10), which is out from the axis of the water turbine (2), where this main shaft (10) is able to install an electric generators on it, and it may reach to four electric generators, two on each side of the water turbine (2) casing, or one electric generator on one of sides, or two electric generators on each side one, and all of that is inside or outside the machine structure, depending on the size of the machine, or the size and type of the electric generator. 11. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the movement and interaction of the machine parts together in the entire machine cycle and in its five phases to generate kinetic energy in the water turbine main shaft (10). 12. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the idea and the work principle of the machine movement 'as a whole', which is manifested in machine working steps on its five phases that are mentioned above (in the detailed description) and the general distribution of all parts of the machine in its place within the machine structure, and on its. 13. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; all of the above mentioned was for the machine in its original state, that is, which it's produces kinetic energy only from its movement, without using an electronic parts or additional electrical installations to help operate the machine, and of course without using any type of energy consumed and known as fossil fuel and electricity from any source, Or nuclear energy, or gas, etc. 14. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; replacing the automatic braking system based on the dynamic movement of 22 the machine with a magnetic braking system (electromagnetic lock) that relies on electricity in the braking process, where the time to give orders to the brake to the braking boxes by the laser sensors that are directed to a specific point on the middle tank (12) and the lower tank (13) or to the large and small gas springs (8), and when these signs reach the direction of the laser beam, an a wireless signal is send to the main control board and read it, then given order of connect the electricity to the magnetic brakes, thus the braking process occurs, and the process of releasing the brakes it's as the same method. 15. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; with this we can dispose with the extensions of the previous system, as like the oil pressure tubes (57), the cables (56), (40), (41), (27), and the brake pedal release boxes (Fig. 9A + Fig. 9B) that contain mechanical parts, as for the brakes of the electromagnetic lock it do not need all that stuffs troubles, where the signals are transmitted by wireless, whether it is from the laser box to the main control panel Or, from the main control panel of the electromagnetic brake box. 16. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; it's indicated here that the electricity using in this system it's negligible, as it's very little less than 1%, and the electricity is taken from a battery that is inside the machine, where it's constantly charged. 17. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; Adding a box with an automatic system to control the manual brake system of the middle tank (12), (Fig. 13), which stops the movement of the machine and resumes it to work again at any time where the middle tank (12) (Fig. 4) moving... where it stops the machine moving and let it to working again by pressing a key on the main control board in (the first item). 18. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; when the machine contains a battery with a large storage capacity and the purpose of it's to store the excess from the electric generator, and when the battery is 23 filled, an electrical signal is sent to the control panel to give a signal order to the automatic control box to brake the machine and stop its movement. 19. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; when the battery is drained and reaches 19%, the operation of the machine is resuming by the same technique mentioned above. There is another version of the second version where just aforementioned, in addition to replacing the automatic braking systems based on the dynamic movement of the machine, with an electromagnetic braking system, and adding a battery that can be charged quickly, here, in this version, the large gas springs (8) and the small gas springs (9) are replaced with hydraulic lifting cylinders to raise the lower tank (13), it takes the electricity from the pre-charged battery before starting the machine. 20. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; the battery will charge continuously, and the battery will never drain; because the hydraulic lifting cylinders lift the lower tank (13) in only one phase of the five phases of the machine cycle, which is the fourth phase, and these hydraulic lifting cylinders it only consumes a small amount of electricity from the battery, and because the battery is charging quickly and continuously it becomes impossible to drain. 21. As mentioned in Claim 1, the invention is perpetual motion machine, the feature of which is; if the battery malfunctions, the electric generator in the machine will supply the hydraulic lifting cylinders with electric in ease, and it will not adversely affect the machine operation and production the kinetic energy to operate the electric generator. 24 |
Technical Field:
This invention relates to a perpetual motion machine.
State of the Art:
The present invention relates to the perpetual motion machine, there's no current real art and invention that complements the conditions of permanent and subjective movement without losing kinetic energy in the entire machine cycle each time, Whereas most physicists and those interested in this field have said that it's impossible to achieve the design and manufacture of a perpetual motion machine; (Because the machines that exist today are stop after a relatively short period, and don't meet the requirements of the name of the invention, also they're not practical, so that most of them were made for decoration, such as those in the offices, and they also need external strength every time they stop).
Returning to the first attempt that might be real in the beginning of the eighteenth century 1712 A.D., at the hands of the European-English inventor: (Orpheus), where he claimed that he invented a permanent machine that managed to work for two months without stopping, and was raised a few kilograms... However, the secret of his invention was buried with him, and no one can determine that his invention wasn't a trick in it.
As for the first failed attempt in history, it was a proposal for an eternal machine\ in Latin: (Perpetuum mobile) designed by inventor Villard de Honico, since 1230 A.D., but it didn't succeed Because of the great friction and uselessness of it.
So, this invention is like a mystery yet to be discovered. Therefore: In my invention, (I sincerely claim) that I invented a permanent and selfmotion machine that satisfies the aforementioned conditions.
Description of the Invention:
A mechanical machine with a closed and isolated dynamic system, the machine derives its moving energy and much more than that (to the point of operating a large electric generator), through its permanent and closed motion system, where the machine cycle begins with a specific force, then the cycle ends and begins with the same force and activity in every time.
The system of the machine it contains three water tanks, the upper one is stationary, the middle and the lower are moving up and down, also they move the water and take benefit of their weight to pressure the gas springs and the water syringe in the machine system.
The function of the gas springs is to storing the force of the (lifting, propulsion) of the machine cycle.
The water syringes have two valves in two different directions, its function is to suction water from the middle and lower tank through the first valve and transfer it to the upper tank through the second valve in each cycle, but before the pressurized water arrives from the injections, it's head it to the (water turbine), which is producing Enough kinetic energy to power a large electric generator.
Returning to the upper tank, its task is to receive the descending water from the water turbine casing and store it to start the new cycle, the water where collects in the upper tank is passed to the middle tank at the beginning of each cycle and so forth ...
The structural and characteristic features and all advantages of the product subject to the invention will be understood more clearly thanks to the figures given below and the detailed explanation written by referring to these figures, and therefore the evaluation should be made by considering these figures and detailed explanation.
Description of the Figures:
The invention will be described with reference to the accompanying figures, so that the features of the invention will be more clearly understood and appreciated, but the purpose of this is not to limit the invention to these certain regulations. On the contrary, it is intended to cover all alternatives, changes and equivalences that can be included in the area of the invention defined by the accompanying claims. The details shown should be understood that they are shown only for the purpose of describing the preferred embodiments of the present invention and are presented in order to provide the most convenient and easily understandable description of both the shaping of methods and the rules and conceptual features of the invention. In these drawings.
Figure 1 (A) Longitudinal section of the prototype design figure according to the invention.
Figure 1 (B) Longitudinal section of the less-simplified prototype design figure.
Figure 2 Longitudinal section illustrating the parts of a machine in a simplified prototype.
Figure 3 The first phase of the machine cycle, which is the beginning of the cycle.
Figure 4 The second phase of the machine cycle.
Figure 5 The third phase of the machine cycle.
Figure 6 The fourth phase of the machine cycle.
Figure 7 The fifth phase of the machine cycle, which is the end of the cycle.
Figure 8A Brake system box
Figure 8B Brake system box
Figure 8C Brake system box
Figure 8D Brake system box
Figure 8E Brake system box
Figure 9A Brake pedal release box
Figure 9B Brake pedal release box Figure 10 Self-braking system for the large gas springs.
Figure 11 The middle tank automatic lifting system.
Figure 12 Map distribution of the brakes boxes, brake pedal removal, and tank covers opening and closing.
Figure 13 Middle tank brake + hand brake.
Figure 14 One-way valve.
Figure 15 Spiral water pipe layers.
Figure 16 Small and large gas spring distribution base.
The figures to help understand the present invention are numbered as indicated in the attached image and are given below along with their names.
Description of References:
1. Machine structure
2. Water turbine
3. Water pipe
4. Spiral spring water tube
5. Drain stopper of the upper tank
6. Drain stopper of the lower tank
7. Pistons of the large gas springs
8. The large gas springs
9. The small gas springs
10. The main shaft of the water turbine
11. The upper tank
12. The middle tank
13. The lower tank
14.1 Coil springs 1
14.2 Coil springs 2
14.3 Coil springs 3
15.1 Water syringe 1
15.2 W ater syringe 2 15.3 W ater syringe 3
16.1.1 Suction V alve 1
16.2.1 Suction V alve 2
16.3.1 Suction V alve 3
16.1.2 Outlet Valve 1
16.2.2 Outlet Valve 2
16.3.2 Outlet Valve 3
17. Pulley
18. The steel wire ropes
19. Coil springs for steel wires ropes
20. The solid cylinder
21. The box arm
22. Coil spring 1
23. Brake pedal
24. Head of the arm
25. Key of release the brake pedal lock
26. Key of the brake pedal return after pressed its
27. Brake pedal release cable
28. Brake's jaws
29. Rail track 1
30. The boxes of automatic brake pedals 1
31. Brake pedal release box 1
32. Brake pedal release box 2
33. Brake pedal release box 3
34. Brake pedal release box 4
35. Manual Brake
36. The boxes of automatic brake pedals 2
37. Rail track 2
38. Braking jaws
39. The oil pressure brakes piston rod
40. Cable of opening the upper tank drain stopper
41. Middle tank brake release cable 42. The base of the machine
43. A pipe inside the upper tank
44. A pipe inside the middle tank
45. A pipe inside the lower tank
46. Carrying area of the Middle tank
47. The common oil pressure tube
48. Longitudinal canal track
49. The funnel of the upper tank
50. The funnel of the upper tank
51. The fixed pistons under the middle tank
52. The pistons fixed in the base of the machine
53. The pistons fixed in the machine's structure
54. The watercourse inside the upper tank
55. Coil spring 2
56. Cables and wires of automatic brake box
57. Oil pressure tubes
58. Small pulleys
59. The brake oil pressure cylinder
60. The structure of the automatic brake box
61. Steel beams
62. Cylindrical iron tube
63. Solid plastic ball covered with strong rubber
64. Triangular (internal) coil spring
65. Direction of water movement
66. Hole of the one-way valve
67. Wide slots of cylinder
68. Layer of reinforced and high-pressure rubber
69. Layer of a carbon fiber fabric
70. Layer of a supple plastic cover
71. Layer of a metal lattice coil spring Detailed Description of The Invention:
Part One
This machine depends in its permanent movement on a self-renewing cycle, as it consists of five phases as follows: -
1) The first phase: As shown in (Fig. 3), the middle water tank (12) (Fig. 3) is already stop and close fitting to the upper fixed water tank (11) (Fig 3), the upper tank (11) is open to the middle tank (12) through the drain stopper (5) (Fig. 3) from down of the upper tank funnel (11), where the water is passed through and transferred from it, that is, the weight of the water is carried by the middle tank (12) in this state, and this is the position in which the machine cycle is in the fifth (last) phase, and from here the manual brakes of the machine (35) (Fig. 12), (Fig. 13) are lowered by hand only once to start the first phase of the machine cycle as follows: -
The middle tank (12) begins to go down compressing with it the large gas springs (8) (Fig. 3), through the pistons installed on it and designated for that (7) (Fig. 3), Also, the water syringe (15.1) (Fig. 3) is compressing at the same time, as these water syringe (15.1) (Fig. 3) push the water to flow up through the valve which designed to extract and pushing water from the syringe (16.1.2) (Fig. 3), then rise through the water pipe (3) (Fig. 3) to the water turbine (2) (Fig. 3) and make it spin, Thus the main shaft of the water turbine (10) (Fig. 3) rotates to produce kinetic energy, whereas the drain stopper of the funnel head under the upper water tank (5) (Fig. 3) still open.
2) The second phase: As shown in (Fig. 4), after the arrival of the middle tank (12) (Fig. 4) and attach with the lower water tank (13) (Fig. 4), then the middle tank (12) stops moving, and the large gas springs (8) (Fig. 2) are braked Automatically, which was compressed in the first phase, and from here the second phase begins as follows: -
The drain stopper (6) (Fig. 4) down the funnel opens below the middle water tank automatically so that water flows down into the lower tank (13), and in the same time the water syringe (15.1) (Fig. 4) continues to push the water onto the turbine (2) (Fig. 4) at the top through the output valve (16.1.2) (Fig. 4) the reason for this is: that the water syringes (15.1) is left a small amount of water remaining as shown in (Fig 4), and therefore the coil springs (14.1) (Fig 4) on it pushing the remaining of the water in the water syringes (15.1), where the drain stopper (5) (Fig. 4) in the funnel of the upper tank is still open.
! Note: The coil springs (14.1) (Fig. 4) are compressed at the beginning of the second phase due to the descent of the middle water tank (12) (Fig. 4) during the first phase.
3) The third phase: As shown in (Fig. 5), after the water is transferred from the middle tank (12) (Fig. 5) to the lower tank (13) (Fig. 5), the lower tank (13) begins to descend and the middle tank (12) goes up, where the weight of the lower tank (13) raise the middle tank (12) due to the weight difference, by the steel cables and pulleys (17) (Fig. 5) installed in the machine frame at the top as shown in, at the same time, the drain stopper of the upper tank (5) (Fig. 5) closes automatically, and the drain stopper of the middle tank (6) (Fig. 5) remains open , the result from each: descend of the lower tank (13), and the rising of the middle tank (12) as follows: -
- Suction water from the lower tank (13) by water syringes (15.1) (Fig. 5) by the suction valve (16.1.1) (Fig. 5) by the action of the ascending of the middle water tank (12).
- Suction water from the lower tank (13) by water syringes (15.3) (Fig. 5) by the suction valve (16.3.1) (Fig. 5) by the movement of the descending of the lower tank (13), and at the same time the syringes (15.2) (Fig. 5) is pushing the water by the output valve (16.2.2) (Fig. 5) to the water turbine at the top of the machine, by the movement of the lower tank (13) downward, where the outer cylinders of the syringes (15.2), (15.3) (Fig. 5) are always fixed around the lower tank (13), also at the same time the lower tank (13) and in its descending movement are working to press the small gas springs (9) (Fig. 5).
! Note: The large gas springs (8) (Fig. 5) are remaining brake throughout the third phase, and the pistons (7) (Fig. 5) rise with the rise of the middle water tank (12); because it is fixed on it. 4) The fourth phase: As shown in (Fig. 6), the middle tank (12) (Fig. 6) is already arrived to the upper tank(l l) (Fig. 6) and close fitting on it and automatically braked into the machine structure (1) (Fig. 6), the drain stopper of the middle tank funnel (6) (Fig. 6) is closed automatically at the moment of its arrival to up and, the lower tank (13) (Fig. 6) has reached the bottom and compressed the small gas springs (9) (Fig. 6) without to brake its, and at the beginning of the fourth phase the following occurs:
When the lower tank (13) (Fig. 6) reaches down and touches the large gas springs (8) (Fig. 6), the brakes (30) (Fig. 8), (Fig. 10), (Fig. 12) are removed from the large gas springs (8) (Fig. 6) via the brake pedal release box (31), (Fig. 9B), (Fig. 10), (Fig. 12) of the lower tank movement to begins the lower tank (13) (Fig. 6) rise up through the propulsion energy that has been compressed and stored in the large (8) and small gas springs (9) (Fig. 6), thus the lower tank (13) (Fig. 6) is easily raised, and in the meantime, i.e. (the rise of the lower tank (13) (Fig. 6)), this tank works to reverse the fixed water syringes movement on it, i.e. (the water syringes (15,3) (Fig. 6)) compresses the water and pushes it into the water turbine (2) (Fig. 6) at the top, through the output valve on the water syringes (16.3.2) (Fig. 6), also reverse the water syringes (15.2) (Fig. 6) movement, where it suction water from the lower tank (13) (Fig. 6) through a suction valve located on the water syringes (16.2.1) (Fig. 6), while the middle tank (12) (Fig. 6) is attached and fixed in the upper tank (11) (Fig. 6), so the water syringes (15.1) (Fig. 6) is still inactive and its valves (16.1), (16.2) (Fig. 6) are closed.
5) The fifth phase: As shown in (Fig. 7), when the lower tank (13) (Fig. 7) returns and reaches its place at the top, (without braking its) and the water is transferred to the upper tank (11) (Fig. 7) where the drain stopper of funnel in the upper tank (5) (Fig. 7) it still closed, and at this moment the following occurs: -
The drain stopper of the upper tank (5) (Fig. 7) funnel opens via the brake pedal release box (33) (Fig. 9A, upper tank's (Fig. 11) cable), (Fig. 12), and in the same time release down the brakes (36) (Fig. 8) (Fig. 12) of the middle tank (12) (Fig. 7), via the brake pedal release box (33) (Fig. 9A, middle tank's (Fig. 12) cable), (Fig. 12), so that the water moves from the upper tank (11) (Fig. 7) to the middle tank (12) (Fig. 7), and this also means that The weight of the water will be carried by the middle tank (12) (Fig. 7) as in the first phase, Meanwhile, exactly how long it takes for the water to descend and move to the middle tank (12) (Fig. 7), the remaining water in the syringes (15.3) (Fig. 7) are compressing by the output valve (16.3.2) (Fig. 7) to the water turbine (2) (Fig. 7) on top; This is done by the coil springs on water syringe (14.3) (Fig. 7).
After the fifth phase of the machine cycle ends, the first phase begins automatically and so on ...
Part Two
Detailed description of the automatic systems in the machine:-
1) Automatic brake system for the middle tank (12) and large gas springs (8), by oil pressure: -
First: The middle tank (12) (Fig. 3) brake mechanism, where this system relies on the brake pedal box (36) (Fig. 8), (Fig. 12) and its fixed in the machine structure (1) (Fig. 2), where the box (Fig. 8) contains a special arm (21) (Fig. 8) that is outside of the box as shown in and once the arm (21) (fig. 8) starts touching the specified place to it on the structure of the middle tank (Fig. 12) (as a result of the rising of the middle tank (Fig. 12)) the arm (21) (fig. 8) is pressed into the box (Fig. 8) pressing with it the coil spring (22) (Fig. 8), where the coil spring (22) (Fig. 8) is always touched on the pedal (23) (Fig. 8), and the pedal (23) (Fig. 8) is locked before the arm (21) (Fig. 8) reaches its release switch (25) (Fig. 8), and once the arm head (24) (Fig. 8) reaches of the key (25) (Fig. 8) on the pedal (23) (Fig. 8) and this key (25) (Fig. 8) is pressed, the coil spring (22) (Fig. 8) has been pressed to the maximum, and in this moment the brake pedal lock (25) (Fig. 8) is removed due to the pressure of the arm head (24) (Fig. 8) on the brake release key (25) (Fig. 8), thus the coil spring (22) (Fig. 8) presses the pedal (23) (Fig. 8) quickly and completely, so it's brake the movement of the middle tank (12) by pressing the brake's jaws (38) (Fig. 13) on the middle tank's rail track (37) (Fig. 13) through the common oil pressure tube between the middle tank brake and the hand brake (47) (Fig. 13). As for the release the brake pedal of the middle tank (23) (Fig. 8) through the releasing key of the brake pedal (26) (Fig. 8) it's by the movement of the lower tank (13) (Fig. 7) up at the end of the fourth phase, where there is a box to release the brakes (Fig. 9A, the middle tank's (Pt.12)) cable, where that box (33) (Fig. 12) fixed on the machine structure as shown in, and in this same box and at the same time that releasing the pedal of the middle tank brake (23) (Fig. 8), the drain stopper of the upper tank funnel (5) (Fig. 7) opens via the brake pedal release box (Fig. 9A, the upper tank's (11)) cable.
Second: The system of brake the large gas springs:
This system relies on two boxes for the braking process, in the first box (30) (Fig. 8), (Fig. 10), the oil pressure tubes are used in the braking process, and in the second box (31) (Fig. 9B) the cable (27) (Fig. 10) is used in the process of release the brake pedal (23) (Fig. 8) in the first box (30) (Fig. 10).
On both sides of the upper part of the outer cylinder of the large gas springs as in, the brake's jaws (28) (Fig. 10) are used on each side to brake the rail track (29) (Fig. 10) that pass between them, where this rail track (29) (Fig. 10) is part of the head of the inner cylinder press as it shown in, this is when the large gas springs (8) (Fig. 4) are compressed when the middle tank (12) (Fig. 4) descends at the end of the first phase, as the brake pedal box (30) (Fig. 8), (Fig. 10) is fixed on the outer cylinder of the large gas springs as shown in, also as shown in (Fig. 12), and when the middle tank (12) (Fig. 4) at the end of the first phase descends, and pressure on the arm (21) (Fig. 8B) of the brake box, and braking the large gas springs (8) (Fig. 4), the arm (21) (Fig. 8C) remains and hold in its place; because of the braking, and this process is called: (self-braking).
As for when the time becomes to release the large gas springs (8) (Fig. 6) from the brake exactly at the end of the third phase and the beginning of the fourth phase, here the second box (31) (Fig. 10), (Fig. 12) is used as in, as the cable (27) (Fig. 9B), (Fig. 10) it releases the oil pressure brakes piston rod (39) (Fig. 8E) through the brake pedal (23) (Fig. 8E), therefore, letting the brake's jaws (28) (Fig. 10) off the rail track (29) (Fig. 10) and allow the large gas springs (8) (Fig. 6) to raise the lower tank (12) (Fig. 6). ! Note: After releasing the brake pedal (23) (Fig. 8E), (Fig. 8A), it returns to its place as in by tightening it with the coil spring (55) (Fig. 8E).
2) The automatic system for opening and closing the drain stopper of the funnel under the upper tank (5) (Fig. 2) and the drain stopper of the funnel under the middle tank (6) (Fig. 2) as follows: -
First: the process of opening and closing the upper tank drain stopper (5) (Fig. 2), this system relies to open the drain stopper of the tank on the brake pedal releasing box (33) (Fig. 12) fixed on the machine structure, shown in (Fig. 9A, upper tank cable (40)) and that through the movement of the rise of the lower tank (13) (Fig. 7) at the end of the fourth phase.
As for the closing of the drain stopper of funnel (5) (Fig. 2) for this tank, this is done by the movement of the descent of the middle tank (12) (Fig. 4) at the end of the second phase, where the automatic closure system is used through box (32) (Fig. 9B, Brake pedal release cable (27)) which it fixed on the machine structure (Fig. 12).
! Note: The upper tank drain stopper (5) (Fig. 4) closes at a slow speed fit to speed of the water emptying from the middle tank (12) (Fig. 4).
Second: The process of opening and closing the drain stopper of the middle tank funnel (6) (Fig. 2), the drain stopper of this tank funnel is opening when the middle tank (12) (Fig. 4) descends and reaches the bottom, through the automatic opening box (Fig. 9B, Brake pedal release cable (27)), fixed in the middle tank structure (34) (Fig. 12).
As for the closing drain stopper of this tank funnel (6) (Fig. 6), this is done through the outer ring of the upper tank funnel (5) (Fig. 6), exactly when the middle tank (12) (Fig. 6) returns to the top in its place at the end of the fourth phase. 3) The Automatic system for lifting the middle tank (12) (Fig. 11):
As shown in (Fig. 11) the diagram of the automatic system, where this system depends on the steel wire rope (18) (Fig. 11), and the pulleys (17) (Fig. 11) fixed in the machine structure (1) (Fig. 11) at the top.
The steel wire rope (18) (Fig. 11) is always fixed in the middle tank (12) (Fig. 11), and it passes through the pulleys (17) (Fig. 11) fixed to the top of the machine structure (1) (Fig. 11), and it's directed down towards the base of the machine (42) (Fig. 11) through its passage in a pipe inside the tank of: {upper (43) (Fig. 11), middle (44) (Fig. 11), lower (45) (Fig. 11)}, the steel wire rope (18) (Fig. 11) is fixed to an extendable coil spring (19) (Fig. 11), and this coil spring is always fixed at the base of the machine (42) (Fig. 11) in order to keep the steel wire rope (18) (Fig. 11) tight throughout the time from the scattering and friction with the machine parts.
The process of lifting the middle tank (12) (Fig. 11) occurs automatically by the weighing of the lower tank (13) (Fig. 11) when it comes down, specifically where the steel wire rope (18) (Fig. 11) is tighten from the top of the pipe intended for the steel wire rope in the lower tank (45) (Fig. 11), in the area shown in (Fig. 11), where this steel wire (18) (Fig. 11) in this area (46) (Fig. 11) has a solid steel cylinder (20) (Fig. 11) attached and knotted to the steel wire rope (20) (Fig. 11) to let a lifting occurs between the ends of the steel wire rope (18) (Fig. 11), thus the middle tank (12) (Fig. 11) is raise.
When the lower tank reaches down, the coil spring returns with its original status position (shrunken), and when the lower tank rises again in the fourth phase it does not affect to the steel wire rope, as the coil spring stays in its status position (shrunken).
As for when the middle tank (12) (Fig. 4) comes down at the end of the first phase, here the steel wire rope (18) (Fig. 5) is tugging from the end at the base of the machine, and extension the coil spring (19) (Fig. 5), and thus the solid steel cylinder (20) (Fig. 11) returns to its position as in, and this movement of the steel wire rope (18) (Fig. 11) continues to this way. 4) In addition to the automatic systems, there is a manual braking system (35) (Fig. 13), (Fig. 12) whose task is to stop the machine, and its main task is as the first spark to operate the machine; Once the brakes (35) (Fig. 12) are manually lowered into this system, the machine begins to be running and operate.
The machine can be stop by the manual brakes system (35) (Fig. 12) at any time while the middle tank (12) (Fig. 5) is in moving; Because the brakes are on both sides of the middle tank (35) (Fig. 12), as the brakes (Fig. 13) are brakes by the oil pressure system in the tubes, and the brakes (Fig. 13) are fixed in the machine structure (1) (Fig. 13), (Fig. 2) and included in a longitudinal canal track (48) (Fig. 13) on both sides of the middle tank (12) (Fig. 13) structure as shown in (Fig. 13).
! Note: the brake system (35) (Fig. 13), (Fig. 12) does not adversely affect on the machine, and the operation of the machine can be resumed at any time once the brake is lowered again.
Part Three: Important physical calculations in the principle of machine operation as follows: -
1) The momentum losing by the gas springs on average is = ( 20%) from the weight that compressed them, for example: (the gas spring that is compressed by 1000 kg, it can raise 800 kg), and because of the gas springs compression in two phases in the machine's cycle, The (large springs (89 (Fig. 2) in the first phase, and the small springs (9) (Fig. 2) which are 75% of the power of the large springs (89) (Fig. 2) in the third phase), thus the resultant of the thrust energy in the gas springs (the large (8) (Fig. 2) 800 kg and the small (9) (Fig. 2) 600 kg) = 1400 kg, and this force inherent in the total of the large (8) (Fig. 2) and small (9) (Fig. 2) gas springs is able to raise the lower tank (13) (Fig. 6) with ease in the fourth phase, and also work by big force to push the water from the water syringes (15.3) (Fig. 6) to the water turbine (2) (Fig. 6) at the top by the amount of the remaining increase of the force of pushing and lifting the weight of the lower tank (13) (Fig. 6) as will be explaining in the next paragraph. 2) Explain the equation of the distribution of weights in the phases of the machine cycle, which the middle tank (12) (Fig. 3) and lower tanks (13) (Fig. 5) moving in the first, third and fourth phases as follows: -
The first phase.
If the weight of the water in the middle tank (12) (Fig. 3) is = 4000 kg, and the weight of the tank itself = 800 kg, so the total is = (4800 kg), and since the machine has four sides, then there are four water syringes (15.1) (Fig. 3) (on each side a syringe), therefore each water syringe (15.1) (Fig. 3) needs (200 kg) of weight in order to be sufficient to reach the water turbine (Fig. 3, Pt. 2) and flow on its with enough strength, so: (200 kg x 4 syringes (15.1) (Fig. 3)) = 800 kg.
So: we subtract from the weight 4800 kg, the weight that water syringes (15.1) (Fig. 3) require, mean: (4800 - 800) = 4000 kg.
The (weight 4000 kg), is the weight that must compress the large gas springs (8) (Fig. 3), but as mentioned earlier: “The momentum of gas springs losing an average by (20%) from the weight that compressed them”, thus the weight that obtained from the momentum of the large gas springs (8) (Fig. 3) = (4000 kg - 20%) = 3200 kg.
The third phase.
At the beginning of this phase, the water has been transported from the middle tank (12) (Fig. 5) to the lower tank (13) (Fig. 5) through the first and second phase, thus the weight of the water in the lower tank (13) (Fig. 5) becomes = (4000 kg), in addition to the weight of the lower tank (13) (Fig. 5) = (800 kg), so the total summation = (4800 kg), here we subtract the weight designated for the water syringes (15.2) (Fig. 5) and since there are 4 syringes, then 200 kg x 4 syringes (15.2) (Fig. 5) = 800 kg, i.e. (4800 — 800) = 4000 kg.
But here the small gas springs (9) (Fig. 5) can contain a weight: (75% from what can the large gas springs (Fig. 5, Pt. 8) contain), that's mean the small gas springs (9) (Fig. 5) need only 3000 kg, thus the aggregate amount of the weight from the obtained of the momentum gained by the small gas springs (9) (Fig. 5) is = (3000 — 20%) = 2400 kg.
So: the total of the weight from the momentum gained by the (large (8) (Fig. 5)) and small (9) (Fig. 5)) gas springs is = 3200 kg + 2400 kg = 5600 kg.
That's mean: these gas springs ((8) (Fig. 5) + (9) (Fig. 5)) can carry a weight of (5600 kg).
As for the rise of the middle water tank (12) (Fig. 5) (empty of water) in the same phase, it will be through the weight that has been relinquished from the small gas springs (9) (Fig. 5), and its quantity is (1000 kg), therefore this weight (1000 kg) can lift the empty middle water tank (12) (Fig. 5), where its empty weight is (800 kg); Because the weight difference here is (200 kg), and this lifting process happening as shown in the second part of the detailed description of the invention, item No. (3).
Finally, the fourth phase.
At the beginning of this phase, the weight that all gas springs ((8) (Fig. 6) + (9) (Fig. 6)) must carry is: (4000 kg, water weight in the lower tank (13) (Fig. 6) + 800 kg, the weight of the lower tank (13) (Fig. 6) itself) = 4800 kg, so we subtract this weight from the weight that the large and small gas springs ((8) (Fig. 6) + (9) (Fig. 6)) collected to push and lifting, that’s mean: (5600 kg — 4800 kg) = 800 kg.
And this result (800 kg) will be distributed to the water syringes (15.3) (Fig. 6) and it's 4, that's mean: each one has (200 kg) of weight from the pressure of the gas springs ((8) (Fig. 6) + (9) (Fig. 6)).
! Notice: Always the small quantity of water at the bottom of the lower tank (13) (Fig. 3) is calculated before the water is transferred to it from the middle tank (12) (Fig. 3) from the total of the lower tank (13) (Fig. 3) itself = 800 kg), as if it empty. ! Note: In this version, the brakes boxes of the large hydraulic lift cylinders aren't needed, because hydraulic lifting cylinders do not need to be braking.
! Important notice: In addition to the simplified first model (Fig. 2), there are two other models for distributing machine parts and arranging them to fit the desired purpose by the size of it, as shown in (Fig. 1 A) and (Fig. IB).