WO2010000046A2 - Power hydraulic machine in circular movement at electric power generation - Google Patents

Description

"POWER HYDRAULIC MACHINE IN CIRCULAR MOVEMENT AT ELECTRIC POWER GENERATION"

The present patent of invention refers to a machine duly developed to produce electric energy or other movements that such power may be applied, since such energy may be generated and carried with vehicles in movement and be transferred to them like automobiles, ships and other vehicles in movement, and also generate energy in bulk in a small room of a land. As I will start its power generation with a tube or several tubes fixed to a shaft or more than a shaft, in this patent I will work with more than one shaft and with several water-filled tubes, I herein describe more than one shaft due to the fact such machine best works with more than one shaft, when the first one runs with the tubes fixed to it filled with water; there is always a buoy inside each tube, two steel cables, a groove in each side of the tube. When each tube is vertically positioned, the buoy goes up inside the water- filled tube and it is fixed to a steel cable in one side of the tubes; at going up, it makes a shaft runs where there was one of the steel cables coiled; at being uncoiled, it exerts an upper movement that duly reused, such movement transfers outside, it couples to a turning gear which transfers to a shaft through a chain or belt, in such shaft the power may move a generator or other machines that require power. When the buoy goes up with the first steel cable and finishes its up movement, it holds to the second cable inside the tube; in such movement, the first cable unfixes and coils through an electric engine towards the place it came out. There is thus the water-filled, other kinds of liquids, tubes turning behind a wheel bigger in its diameter than the length of the tubes to facilitate its rotation, since the bigger the wheel, the smaller the tube rotation effort to the machine stop, there is, thus, a new rise of the second cable that turned fixed to a buoy to the starting point, there had been, thus, the second buoy up movement, and then, successively, each time one of the tube ends is vertically placed, the machine stops and there is a movement to the buoy together with one of the cables, now the buoy goes up from one side of the tube, and then the buoy goes u on another, now it unfixes one cable and coils, then holds another cable together with the buoy and it is placed for the respective rising initiating the buoy rising and the machine movement. In such machine movement starting and power transfer it is seen the machine need of having more than one shaft separated so that it is possible to initiate the buoys rising, they go up in separated times since the tubes are hanging in more than shaft to give different times for fitting and power transfer in the buoy movement for its good operation; rising times need to be always synchronized when a buoy goes up and the other goes for the groove, for that reason the bigger the number of buoys, the number of shafts best transmits power to the shaft that will run a generator or other machines that need power in order to move, as I will show the machine with its buoy rising movements happening when the tube is found vertical and the machine stops and the buoy rising initiates. But also it may be different, by changing the external groove in a way so that the buoy movements are performed with the tubes in movement and transfer such movement to turning gear groove, since it makes possible to perform the movements immediately to buoy rising. By analyzing a bicycle movement it is better understood how it is possible transferring its movement without making the machine to stop, since there is movement only when the buoy moves or at the same time transfers the movement to the turning gear. (Figure 1) Shaft one supporting water-filled tubes where the buoys (1) move, shaft two supporting the water-filled tubes where the buoy move, it is observed that said shaft two is equals to shaft one, but they need to be separated in order to balance the buoys rising and the machine to stop to perform each rising movement in buoys different times (2) , water-filled tubes where buoys move

(3), water-filled tubes where buoys move (4), water-filled tubes where buoys move (5), water-filled tubes where buoys move (6) , water-filled tubes where buoys move (4), water- filled tubes where buoys move (8), water-filled tubes where buoys move (9) , water-filled tubes where buoys move (10) , steel cable that goes up together with the buoy in a tube end (11), steel cable that has same function as eleven (12), steel cable that has same function as eleven (13) , steel cable that has same function as eleven (14) , steel cable that in tube end waiting for the buoy to go up, when the buoy finishes its rising, cable eleven unfixes and coils and goes to the place where cable fifteen came from and couples to the buoy, in such movement the machine turns the buoy together with the tube until vertically positioning the tube and giving a new movement to the buoy, and then sequentially, now a cable on one side of the buoy and then the other cable on the other side of the buoy, and then it is possible the machine to perform its movements (15) , the same function as cable fifteen (16) , the same function as cable fifteen (17) , the same function as cable fifteen (18) , electric engine in each side of each tube end, its function is to coil cables when they unfix the buoys (19) , the same function as engine nineteen (20) , the same function as engine nineteen (21) , the same function as engine nineteen (22), the same function as engine nineteen (23), the same function as engine nineteen (24) , the same function as engine nineteen (25) , the same function as engine nineteen (26), the same function as engine nineteen (27), the same function as engine nineteen (28) , the same function as engine nineteen (29), the same function as engine nineteen (30) , the same function as engine nineteen (31) , the same function as engine nineteen (32), the same function as engine nineteen (33), the same function as engine nineteen (34) , tube end duly built in a turning gear system to transfer buoy movements to a chain or belts, and in case it is possible, to move a shaft through its coupling (35) , the same function as thirty five (36) , the same function as thirty five (37), the same function as thirty five (41), the same function as thirty five (42) , the same function as thirty five (43), the same function as thirty five (44), the same function as thirty five (45) , the same function as thirty five (46), the same function as thirty five (47), the same function as thirty five (48) , the same function as thirty five (49), the same function as thirty five (50), electric power generator (51) , shaft that transfers the power to generator or other machines that may need power

(52), wheel fixed to shaft one or gear with a diameter larger than tubes length in order to reduce the effort on tubes turning until machine stops to vertically position the buoy and initiate its rising (53), wheel two that exerts same function than fifty three, but its tubes support is separated to allow buoy rising in separated times and keeping machine rotation (54) , electric engine that moves wheel fifty three (55), electric engine that moves wheel fifty four (56) , respirator valve in each tube to allow through air opening to improve buoy rising (57), the same function that fifty seven (58) , the same function that fifty seven (59), the same function that fifty seven (60), the same function that fifty seven (61), the same function that fifty seven (62), the same function that fifty seven (63), the same function that fifty seven (64), the same function that fifty seven (65) , the same function that fifty seven (66), the same function that fifty seven (67), the same function that fifty seven (68), the same function that fifty seven (69), the same function that fifty seven (70), the same function that fifty seven (71) , the same function that fifty seven (72), shaft one support (73), shaft one support (74), shaft two support (75), shaft two support (76), shaft fifty two support (77) , shaft fifty two support (78) . Steel cables that are hanged on shaft two that perform the same buoy rising operation of cable eleven (79) , steel cable that performs the same function as cable eleven (80) , steel cable that performs the same function as cable eleven (81), steel cable that performs the same function as cable eleven (82), steel cable that performs the same function as cable fifteen

(83), steel cable that performs the same function as cable fifteen (84) , steel cable that performs the same function as cable fifteen (85) , steel cable that performs the same function as cable fifteen (86) . Belt or chain coupled to the turning gear that waits for each tube passage in buoys rising movement transference (87), belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (88) , belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (89), belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (90) , belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (91) , belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (92), belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (93), belt or chain coupled to turning gear that waits for each tube passage in buoys rising movement transference (94) , buoy that exerts function of rising power inside a liquid and its movement duly reused

(95) , buoy that exerts function of rising power inside a liquid and its movement duly reused (96) , buoy that exerts function of rising power inside a liquid and its movement duly reused (97), buoy that exerts function of rising power inside a liquid and its movement duly reused (98), buoy that exerts function of rising power inside a liquid and its movement duly reused (99), buoy that exerts function of rising power inside a liquid and its movement duly reused (100) , buoy that exerts function of rising power inside a liquid and its movement duly reused (101) , buoy that exerts function of rising power inside a liquid and its movement duly reused (102), Figure (2) best illustrates buoy movement in larger port with buoy at tube one rising point. At tube two the buoy has already finished the rising, unfixed the cable which went up fixed to said buoy and become fixed to the other cable, becoming ready for tube turning together with said buoy and initiating new rising, and then successively .

Claims

"POWER HYDRAULIC MACHINE IN

CIRCULAR MOVEMENT AT ELECTRIC POWER GENERATION", wherein comprises more than one tube supporting shaft in circular stop movements for buoy rising in different times. This machine is interesting because its consumption for its movements is very short and its production may be very big depending on machine size, this machine may be built in a small room of land or in ship ballast, since it may be built in a movement vehicle. Vehicle that said machine may feed through electric energy generated by this machine through buoys rising reuse and its respective movements that I herein describe and totally claim. Rounded tubes built in iron or other materials filled with water or other liquids, one, two, three, four, five, six, seven, and eight, such tubes are pt underneath two by two, which might be one by one, not impeding this, its function is to allow a power performance when a buoy in each tube goes up and to exert a power in its rising that is transferred in the movement of a turning gear to outside and its movement duly reused. Two by two put underneath tat exert the same function of the tubes that are supported on shaft one, but there is a shaft and tubes separation to enable the machine stop, when the tubes are vertically placed in different times and start buoys rising and machine movement, as the tubes lean in different times, the more tubes, buoys and shafts may be built is separated it is possible to keep the machine always in movement, and thus keep the machine movement more uniform, such tubes are built in iron or other materials (2) a buoy in each machine tube, which is one of the buoys that when going up give movement to a shaft outside the machine when the buoy goes up fixed the cable and finishes its route from end tube to the other end, and then fixes to another cable at the same tube. It unfixes from the cable that went up and returns to the place where it came from. The machine fixed to the cable buoy, it starts its turning from the tube or tubes, buoy or buoys, to the place where it came from. Said tubes are vertically placed again and start a new buoy rising movement, but this time with cable fifteen that when going up to the tube end, it unfixes the cable eleven and the buoy fixes to cable eleven and starts a new movement, and then successively, now goes up with cable eleven, turns the tube, goes up cable fifteen and thus the machine movements occur, a buoy in each tube. And two cables in each tube. Such buoys are built in metal or other resistant and light materials in a way they support the rising speed and the pressure among the tubes, each buoy has two groove points (3) . The steel cables fixed to buoys allow buoy movement inversion, now in one direction, then in another direction, to invert the buoy it must be fixed and when it hits up the tube, it inverts its position, leaves a cable and fixes to another one to start the buoy rising in another tube end, for this reason it is has two independent cables. Here it must be emphasized the machine, depending on its size and moving speed; the materials to be used may be others, as well as the shafts duly tamped in substitution to steel cable in buoys in fast movement and short spaces, the smaller the size of the water-filled tube, shorter is the buoys rising time, for this reason is that I claim the movements of this machine in vehicles drive train in movement, since this machine may also run with no tube stops and its fittings are performed with the machine in movement in power buoys transmission when internal sheave runs, it spins a shaft outside the turning gear that fits and transfers the movement to a gear that spins couplet! to it or a belt that will transfer the power to another shaft, where the electric energy generator is, or other means such power may need. (4) Air opening valve to allow air inlet in the tubes at buoys rising, each tube contains a valve in each end built in iron or other materials. (5) huge gear in shaft one, such gear is necessary to have its diameter bigger than the length of the water-filled tubes or other liquids to turn the tubes and position them for buoys rising, the bigger the gear diameter in relation of the tubes length, the bigger the effort will be done by an electric engine at its movement operation in each shaft one and two, there is a big gear so that it is possible to allow the buoy rising movements in separated times. (7) This machine may be built in iron or in other materials, what does not impede its movements, they are very distinct, it is possible to build a machine with just one tube, which makes it very slow, that is why I make a demonstration with several tubes and separation in times of buoys risings and its respective movements. Such gears may also be smaller and put a reducing box in the machine, depends on the components costs. (8) All such machine movements I herein claim as a whole. It may be built in a big or small size depending on its use needs. It is also possible to transfer rotation power from buoys rising with its tubes in movement by just modifying the fitting system outside the tube towards the belt or chains.

(figure 2) is a demonstration of buoys movement inside tube one and tube two to facilitate clarification of such machine movements .