CH720042A2 - Device for producing energy by using gravitational force applied to moving masses within a mechanical assembly. - Google Patents

Abstract

Device for producing energy by using gravitational force applied to moving masses within a mechanical assembly, comprising a chassis (2) supporting pulleys (16) on which a cable (15) slides at the ends from which are hung tanks (6, 29) at the center of which are fixed the ends of a cable (9) supported by pulleys (11, 21) of a fork (5) which allows a cable (12) to be pull on the axis (10) of one (11) of the pulleys of the fork (5) while maintaining the assembly in perfect balance thanks to symmetrical traction of the cable (9) on the tanks (6, 29) during loading working masses (27) onto the plate (26) and alternately raising a control mass (7) and the working masses (27) to produce, by gravity, the self-powering energy of the invention , increased by a delta usable for the benefit of human activity.

Description

[0001] The production of energy is traditionally ensured by machines which use fuels, such as coal, gas, oil, uranium, then more randomly, the wind, the sun or the gravity of the 'water. Energy requirements to ensure and spread the benefits of progress continue to increase. In the current state of knowledge, it is accepted that certain energy sources are neither renewable nor inexhaustible and that the use of these energies generates pollution in different forms.

[0002] The device of the invention makes it possible to minimize these drawbacks by producing energy without pollution.

[0003] The description of the invention is based on 4 figures. Figure 1/4 shows the device of the invention schematically, seen from the front. It is made up of a chassis 2, placed on the ground 1. The fork 5 is articulated on the axis 19 by ball bearings, not shown so as not to overload the figure. The fork 5 carries, on its left side, a pulley 11 mounted freely on the axis 10 by ball bearings, not shown so as not to overload the figure and on its right side, a pulley 21 mounted freely on the axis 22 The pulleys 11 and 21 support the cable 9 anchored to its left on the tank 6, via a spring 8 and to its right on the tank 29 via the anchor 28. The spring 8 n has no other function than to illustrate in the different figures, by its elongation, the variations in tension undergone by the cable 9. The tension and the length of the cable 9 can vary thanks to a simple hydraulic circuit which connects the cylinder 18 to the cylinder 24 via the flexible 20. The pivot axis 19 of the fork 5 is not located in its center, but slightly offset so that the left part of the fork 5 is longer than the right part , as illustrated by arrows 3 and 4. Location 7 is intended to support the control mass of the device. The cable 12 supports the nose of the fork 5 on the left side, by the axis 10 and on the right side the plate 26. The plate 26 is fixed to the cable 12 by the attachment 23 of the cylinder 24 and by the integral attachment 25 of the piston rod of the cylinder 24. Location 27 is intended to carry the working masses. The axis 13, secured to the chassis 2, carries on the left side of the chassis a pulley 14 mounted freely on bearings, not shown so as not to overload the figures. A pulley, mounted in the same way on the right side, supports the cable 12. The cable 15 connects and supports the tanks 6 and 29, placed in opposition. The cable 15 is supported on the upper part, to the right of the chassis 2, by the pulley 16 mounted freely on the axis 17, by means of ball bearings not shown so as not to overload the figure. Cable 15 is supported on the left side of chassis 2 by a similar mounting. Marks 30, 31 and 32 indicate the different heights at which the plate 26 can be located, depending on the operating cycles. Figure 2/4 presents the invention in a slightly different position. The plate 26 has been loaded with four masses 27 and it is aligned with the mark 31. Figure 3/4 presents the invention in a similar position with the exception of the loading of the control mass 7, on the tank 6 Figure 4/4 presents the invention in a different position, following the arrival of the control mass 7 on the tank 6, which causes the tilting of the tanks 6 and 29 and the rise of the working masses 27 until 'at marker 32.

[0004] The device of the invention is presented schematically. It is made up of a set of elements supported by a chassis 2, placed on the ground 1, figure 1/4. By construction, when the plate 26 is not loaded, the tank 29 is slightly dominant in weight over the tank 6. This slight imbalance brings the assembly into the position shown in Figure 1/4, with the plate 26 at the level of mark 30. At rest, pulley 11 and tank 6 are in the high position. When the working masses 27 are on the plate 26, figure 2/4, they cause a tension in the cable 9. The tension of the cable 9 is generated by two different factors. The first factor is consecutive to the traction of the cable 12 on the axis 10 of the fork 5, which causes a slight tilting of the latter in the clockwise direction. The distance between axes 4, figure 1/4, between the axis 10 of the pulley 11 and the axis 19, being greater than the distance between axes 3, between the axis 22 of the pulley 21 and the axis 19, the clockwise tilting of the fork 5 takes more cable than it returns. This assembly causes an increase in tension in the cable 9 caused by the tension of the cable 12. The second factor of tension of the cable 9 and elongation of the spring 8, figure 2/4, comes from the action of the hydraulic cylinder 24 on the hydraulic cylinder 18, via the flexible 20. When the plate 26 is loaded with the working masses 27, the pressure in the cylinder 24 increases, which causes tension in the cable 9 via the cylinder 18. By construction, the cylinders 18 and 24 are sized in section so that the tension generated in the cable 9 is equal to or slightly greater than the tension generated by the arrival of the working masses 27, on the plate 26, when the hydraulic circuit n is not active. Thanks to this device, the tilting of the fork 5 in the anti-clockwise direction, figure 4/4, can be done, without the tension in the cable 9 dropping, until the working masses 27 are unloaded at the level of the mark 32. When loading the working masses 27 onto the plate 26, figure 2/4, the extension of the jack 24 causes a slight descent of the plate 26 to the mark 31. The body of the jack 24 is hooked to the cable 12 by the attachment 23 and the piston rod is attached to the plate 26 by the attachment 25. By the principle of the device of the invention, when the working masses 27 are loaded on the plate 26, under the action of the cable 12, the cable 9 tenses and exerts symmetrical traction on the tanks 6 and 29 which maintain a perfect state of equilibrium. The cable 12 is supported by a system of two pulleys mounted freely on ball bearings, not shown to simplify the figures. On the left side of the chassis 2, the pulley 14 pivots on the axis 13 and on the right side another pulley is mounted in the same way, to support the cable 12. The traction exerted by the cable 9, figure 2/4 , is transmitted to the tank 6 by the spring 8 and on the other side, to the tank 29 by the attachment 28. The tanks 6 and 29 are supported by the cable 15 which circulates freely on two pulleys. To the right of chassis 2, on pulley 16, itself supported by axis 17 and to the left of chassis 2, cable 15 is supported by a pulley symmetrical to pulley 16. Other tank support systems could be used without this constituting an innovation compared to what is presented here. Other cable tensioning systems 9 could be used, instead of hydraulics, without this constituting an innovation compared to what is presented here. By the principle of the invention, the tanks 6 and 29 always remain perfectly balanced. The arrival of the control mass 7 on the tank 6, figure 3/4, breaks the balance of the assembly and drives the tanks 6 and 29. The fork 5 pivots in the counterclockwise direction. The energy produced by the descent of the control mass 7 allows, thanks to the balance of the tanks 6 and 29, the lifting of the working masses 27, from their low point 31 to their high point of arrival 32, figure 4 /4. The working masses 27 are used to illustrate the work provided by the invention. Other control systems of the invention and other energy production systems could be used on the basis of the principle of the invention, without this constituting an innovation compared to what is presented here. When the working masses 27 arrive on the plate 26, figure 2/4, at the level of mark 30, the assembly automatically balances thanks to the traction they exert on the cable 12. The traction of the cable 12, on the axis 10 of the fork 5, causes by reaction the tension of the cable 9 and the symmetrical reduction of the apparent weight of the tanks 6 and 29. By this assembly, the entire device remains in a perfect state of equilibrium, which allows the control mass 7 to overcome the overall entropy of the system and the slight mass dominance of the tank 29. The control mass 7 causes by gravity the descent of the tank 6 and the rise of the working masses 27 until the mark 32, figure 4/4. The energy produced by the fall of the working masses 27, from mark 32 to mark 30, can be used to serve human activity and to raise the control mass 7, from its low point to its point of d entry onto tank 6, when it is in the high position. To simplify the figures, the mechanism necessary for lifting the control mass 7 by using the energy produced during the descent of the working masses 27 is not shown here. The operating cycle of the device explained above is renewed in a continuous movement which allows the self-powering of the invention, the delta of energy produced by the fall of the working masses 27 being available to serve human activity . This energy delta can be captured by means of a mechanical, hydraulic or electrical system, not shown so as not to overload the figures.

[0005] The present invention is particularly suitable for the production of energy by the use of extremely simple mechanical assemblies, the maintenance of which will be elementary, while preserving the environment from additional pollution. It will be able to supply energy-consuming industries and individuals in their daily uses.

References

[0006] 1 Ground or support floor of the chassis 2. Figures 1/4, 2/4, 3/4 and 4/4. 2 Chassis supporting the elements constituting the invention. Figures 1/4, 2/4, 3/4 and 4/4. 3 Arrow indicating the distance between the pivot axis 19 of the fork 5 and the axis 22 supporting the pulley 21. The distance between axes 3 is smaller than the distance between axes 4. Figures 1/ 4. 4 Arrow indicating the distance between the pivot axis 19 of the fork 5 and the axis 10 supporting the pulley 11. The distance between axes 4 is larger than the distance between axes 3. Figures 1/ 4. 5 Fork intended to transform the traction of the cable 12 on the axis 10 into a symmetrical traction on the tanks 6 and 29 in order to maintain the entire device in balance whatever the load on the plate 26, while respecting the performance of the device of the invention. Figures 1/4, 2/4, 3/4 and 4/4. 6 Tanks of a weight equivalent to the weight of tank 29, to the nearest value of the entropy of the system, allowing tank 29 to be slightly dominant in weight compared to tank 6, so that tank 29 is in the low position when the invention is at rest. Tanks 6 and 29 must have a weight greater than the maximum traction of cable 9. Figures 1/4, 2/4, 3/4 and 4/4. 7 Reference having a dual function. It indicates in Figures 1/4 and 2/4 the location of the control mass and designates this control mass in Figures 3/4 and 4/4. Figures 1/4, 2/4, 3/4 and 4/4. 8 Spring intended to illustrate in the figures the variations in tension experienced by the cable 9. In Figure 1/4 the spring 8 is not very constrained whereas it is in tension in Figures 2/4, 3/4 and 4/ 4. Figures 1/4, 2/4, 3/4 and 4/4. 9 Connecting cable between tanks 6 and 29. Cable 9 is supported by pulleys 11 and 21 of fork 5. It is equipped with a cylinder 18 intended to regulate its tension according to the operating cycles of the invention . Figures 1/4, 2/4, 3/4 and 4/4. 10 Axis supporting pulley 11 on fork 5. Axis 10 is also used as anchoring cable 12 on fork 5. Figures 1/4, 2/4, 3/4 and 4/4. 11 Pulley supported by axis 10 on fork 5. This pulley is intended to support cable 9. Figures 1/4, 2/4, 3/4 and 4/4. 12 Connection cable between fork 5 and plate 26. Figures 1/4, 2/4, 3/4 and 4/4. 13 Support pin for pulley 14 on frame 2. Figures 1/4, 2/4, 3/4 and 4/4. 14 Cable support pulley 12. On the other side of frame 2, a second symmetrical pulley is mounted in the same way. Figures 1/4, 2/4, 3/4 and 4/4. 15 Support and connection cable for tanks 6 and 29. Figures 1/4, 2/4, 3/4 and 4/4. 16 Cable support pulley 15 on the right of the chassis. The same symmetrical pulley is mounted on the left side of chassis 2. Figures 1/4, 2/4, 3/4 and 4/4. 17 Pulley support axle 16. Figures 1/4, 2/4, 3/4 and 4/4. 18 Cylinder used to regulate the tension of the cable 9. Figures 1/4, 2/4, 3/4 and 4/4. 19 Pivot axis of fork 5 on chassis 2. Figures 1/4, 2/4, 3/4 and 4/4. 20 Hydraulic hose located between cylinder 18 and cylinder 24. Figures 1/4, 2/4, 3/4 and 4/4. 21 Pulley located to the right of fork 5 and intended to support cable 9. Figures 1/4, 2/4, 3/4 and 4/4. 22 Pulley support axle 21. Figures 1/4, 2/4, 3/4 and 4/4. 23 Attachment point of cylinder 24 on cable 12. Figures 1/4, 2/4, 3/4 and 4/4. 24 Cylinder intended to control the cylinder 18 according to the load carried by the plate 26. Figures 1/4, 2/4, 3/4 and 4/4. 25 Point of attachment of plate 26 to the piston rod of cylinder 24. Figures 1/4, 2/4, 3/4 and 4/4. 26 Plate intended to support the working masses 27. Figures 1/4, 2/4, 3/4 and 4/4. 27 Reference having a dual function. It indicates in Figure 1/4 the location of the working masses and designates these working masses in Figures 2/4, 3/4 and 4/4. Figures 1/4, 2/4, 3/4 and 4/4. 28 Anchor point for cable 9 on tank 29. Figures 1/4, 2/4, 3/4 and 4/4. 29 Tanks of a weight equivalent to the weight of tank 6, to the nearest value of the entropy of the system, allowing tank 29 to be slightly dominant in weight compared to tank 6, so that tank 29 is in the low position when the invention is at rest. Tanks 6 and 29 must have a weight greater than the maximum traction of cable 9. Figures 1/4, 2/4, 3/4 and 4/4. 30 Reference point for the height of the plate 26 when the invention is at rest. Figures 1/4, 2/4, 3/4 and 4/4. 31 Reference point for the height of the plate 26 as a function of the operating cycles of the invention. Figures 1/4, 2/4, 3/4 and 4/4. 32 Reference point for the height of the plate 26 as a function of the operating cycles of the invention. Figures 1/4, 2/4, 3/4 and 4/4.

Claims (3)

1. Device for producing energy by using gravitational force applied to moving masses within a mechanical assembly, consisting of a chassis (2) placed on the ground (1), supporting pulleys on which slides the cable (15) at the ends of which are attached the tanks (6) and (29) placed in opposition and at the center of which are attached the ends of the cable (9) which circulates freely on the pulleys (11) and (21) mounted on the fork (5), cable (9) equipped with a tension regulator consisting of a cylinder (18) controlled by a cylinder (24) whose pressure changes depending on the load constituted by the working masses (27 ), placed on the plate (26), characterized in that the appearance of the masses (27), on the plate (26), exerts traction on the fork (5) via the cable (12) pulling on the axis (10) of the fork (5), which causes a symmetrical lightening of the tanks (6) and (29) and offers a perfect balance between the traction exerted by the axis (10) on the cable ( 12) and the traction exerted by the plate (26) on this same cable. 2. Device according to claim 1, characterized in that the fork (5) is constructed with a larger center distance (4) between the pulley (11) and the pivot axis (19) than the distance between the pulley (11) and the pivot axis (19). -axis (3) between the axis (19) and the pulley (21), which causes tension in the cable (9) when the cable (12) pulls on the axis (10) of the fork (5 ) under the influence of the loading of the working masses (27) on the plate (26) and maintains a perfect state of balance between the tanks (6) and (29). 3. Device according to claims 1 and 2, characterized in that the cable (9) is equipped with a tension regulator constituted by a cylinder (18), controlled by a cylinder (24) which makes it possible to maintain a tension constant in the cable (9) as long as the working masses (27) are loaded on the plate (26), when the fork (5) pivots counterclockwise to follow the tank (6) in its descent caused by the control mass (7), resting on the tank (6), while the tank (29) and the plate (26) rise to the mark (32), where the working masses (27) can be ejected to produce, by gravity, the energy necessary to raise the control mass (7), from its low point to its high point, while delivering a surplus of usable energy for the benefit of human activity.