NL1034252C1 - Perpetua mobilia machine, comprises weights on rotary support which cooperate with radial guide system to convert gravitational energy into kinetic energy - Google Patents

Abstract

Gravitational energy is converted into kinetic energy using a machine comprising at least one support (2) rotatable about a horizontal axis (A) and having at least one weight (3) mounted on it which can be moved in a radial direction relative to this axis; and a radial guide system (4) for the weight.

Description

Energy conversion device

The present invention relates to a device for generating a sustainable form of energy.

As is known, a large number of the energy sources currently used are in principle not inexhaustible. For example, the proven stocks of mineral fuels such as oil and natural gas are at most sufficient for a few tens or hundreds of years, while this consumption will increase rather than decrease with the increasing level of development of the world's population. Moreover, the use of these energy sources leads to a number of problems, of which the air pollution and the warming up of the earth's atmosphere are the best known.

That is why diligent efforts are being made to find alternatives that have so far been found in the form of nuclear energy and various natural or sustainable energy sources such as wind energy, solar energy and the like. However, these alternative energy sources also have a large number of disadvantages. Thus, energy generation through nuclear fission 20 leads to the release of hazardous radiation and radioactive waste for which no processing method has yet been found, while the theoretically promising technique of nuclear fusion does not yet prove useful in practice.

The renewable energy sources have various problems. For example, hydropower can only be used in areas with sufficient height differences or sufficient tidal difference, while using a dam there is a risk that insufficient sludge will be deposited downstream of the dam and therefore the fertility of the riverbed will decrease.

Wind energy is available almost everywhere, but on such a limited scale that the large-scale generation of usable energy from wind leads to an unacceptable use of space and large-scale horizon pollution, while this is also accompanied by considerable noise nuisance. Finally, solar energy is only available in sufficient quantities in certain regions of the earth, while the direct conversion of sunlight into electrical energy is still expensive and not very efficient.

There is therefore a need for an alternative way of generating energy, wherein the aforementioned drawbacks do not occur. To this end, the invention provides a device for converting gravitational energy into kinetic energy, comprising: - at least one carrier rotatable about a horizontal axis with at least one weight mounted thereon, which is substantially movable relative to the axis in radial direction and - means cooperating with the carrier for guiding the radial displacement of the at least one weight.

The operation of the conversion device according to the invention is in fact based on the control of the falling and lifting forces acting on the weights; by allowing the weights to swing radially outwards during their falling movement - under the influence of gravity - and forcing them radially inwards during the subsequent upward movement by the guide means, a moment is generated around the axis of rotation.

Because the device according to the invention makes use of the gravitational energy present everywhere on earth, that is to say the potential energy of the weights in the gravitational field of the earth, it can be used anywhere. Moreover, the device can be placed at locations concealed from view, for example under the ground or under the sea level, so that it does not cause any inconvenience. The device is furthermore silent, and does not generate harmful gases, heat or even sparks, so that it is very suitable for placement in inhabited areas, enclosed spaces or hazardous, for example, explosion-prone environments. Moreover, because the device is suitable for directly converting gravitational energy into a rotating movement, it is particularly useful for all kinds of drives, for example as a vehicle engine.

Preferably, the guide means are adapted to accelerate the at least one weight near the top of its path about the axis of rotation in radial direction away from the axis. Thus, the weight when it has reached the top of its path is again thrown out with force, whereby the carrier is also accelerated and the direction supplies a considerable amount of energy.

In order to increase the power to be generated with the conversion device, it is preferred that a number of weights are arranged distributed on the carrier 20 in circumferential direction.

A structurally simple conversion device is obtained when the or each weight is slidably mounted on or in the carrier in the radial direction.

Because the loads on the device can be considerable, the carrier preferably has the shape of a disc on which or in which a substantially radially extending guide track is formed for the or each weight. A robust construction is thus obtained.

In order to be able to swing the weight optimally outward during its falling movement, the or each guide track advantageously has a track segment curved in the direction of rotation, at least at its end furthest away from the shaft. This can be achieved in a simple manner when the or each guide track has the shape of a hockey stick. On the other hand, it is also conceivable that the or each guide track has a smooth curvature substantially over its entire length.

In order to minimize the frictional resistance encountered by the or each weight, the or each guide track preferably has at least partially interrupted edges.

In order to balance the conversion device in the plane of the rotational movement, the or each weight can be of divided design and have a connecting part extending between the weight parts through the guide path in the disc-shaped carrier. A carrier which is symmetrical with respect to its plane of rotation is thus obtained. The same effect is achieved when in each case two disc-shaped carriers with spacing are placed parallel to each other and share one or more weights arranged in the spacing, and the or each weight has connecting parts protruding on either side in the guide tracks of the disc-shaped carriers. A constructionally simple embodiment of the conversion device is obtained when the guide means comprise at least one ring placed next to the carrier and extending substantially parallel to the plane of the rotational movement thereof, along which the or each weight is movable.

For an optimum balance of the conversion device, it is preferred that the guide means comprise two rings placed on either side of the carrier.

In order to be able to force the weights towards the axis of rotation during their upward movement, the or each ring preferably extends eccentrically in the horizontal direction with respect to the axis of rotation of the carrier.

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This effect can also be obtained or enhanced if the or each ring has a substantially vertically oriented, substantially oval shape.

In order to ensure uniform rotation of the carrier, the conversion device can advantageously be provided with secondary bearing means arranged along the periphery of the carrier. A constructionally simple and robust embodiment of the conversion device is then obtained when the secondary bearing means comprise a number of spacers extending from the carrier to the guide means and a bearing ring arranged around the guide means and accommodating the spacers.

In order to minimize the internal friction in the conversion device and yet to obtain a strong and rigid construction, at least the carrier and / or the guide means are advantageously made of glass.

The invention is now elucidated on the basis of a number of examples, wherein reference is made to the appended drawing, in which corresponding parts are designated with reference numerals that are each increased by 100, and in which:

FIG. 1 shows a front view of a first embodiment of the conversion device according to the invention, FIG. 2 shows a side view of the carrier of the conversion device of FIG. 1, with eight guideways for weights therein,

FIG. 3 shows a side view of the guide ring and the bearing ring of the conversion device of FIG. 1, FIG. 4 shows a schematic view of the web that travels through a weight with a complete rotation of the carrier, 6

FIG. 5A to 5D schematically show a number of positions of an alternative embodiment of the carrier, which is provided with four weights,

FIG. 6 shows a side view of yet another embodiment of the carrier, which is provided with guide tracks with interrupted edges,

FIG. 7 is a rear view of another embodiment of the conversion device, and

FIG. 8 is a side view of one of the carriers of the conversion device of FIG. 7.

A device 1 for converting gravitational energy into kinetic energy comprises two parallel carriers 2 rotatable about a common horizontal axis line A, each having a number of weights 3 arranged therein in circumferential direction (Fig. 1). These weights 3 are displaceable in radial direction relative to the axis A. The conversion device 1 further comprises means 4 cooperating with the carriers 2 for guiding the radial displacement of the weights 3. These guide means 4, 20 which will be discussed in detail below are accommodated in side plates 5, which extend parallel to the plane of the rotational movement on either side of each carrier 2.

In the example shown, the two carriers 2 are mounted rotationally on a continuous shaft 6, which is rotatably mounted in openings 7 in the side plates 5. This shaft 6 can be connected to, for example, a generator, whereby the power of the conversion device 1 is reduced. and converted into electrical energy, for example. The carriers 2 and the side plates 5 are otherwise made of glass in the example shown, although other strong and rigid materials with low friction, such as metals, are also conceivable.

Each carrier 2 here has the shape of a disc in which a radially extending 7 guide track 8 is formed for each weight 3 (Fig. 2). In order to promote the swinging out of the weights 3, the guide tracks at least have a track segment 5 which is curved at their ends 9 which are furthest away from the shaft 6. The curvature is thereby directed in the direction of rotation of the carrier 2. In the example shown here, the guide tracks even have a smooth curvature over their entire length.

Each of the weights 3 is slidably mounted in radial direction 10 in an associated guide track 8. To that end, in the example shown, the weights 3 are each designed to be divided. Each weight 3 herein has a connecting part 10 which extends between the two weight parts 11 and protrudes through the guide track 8. These connecting parts 10 slide back and forth in the guide tracks 8 in the radial direction. In an alternative embodiment of the conversion device, the edges 212 of each guide track 208 are interrupted in order to reduce the frictional resistance experienced by the weights during the sliding movement (Fig. 6). The connecting parts 210 of the weights are thereby elongated in order to ensure a uniformly supported movement along the interrupted edges 212. Incidentally, with this embodiment it can be seen that it is also possible to distribute the guide tracks 208 unevenly around the axis 206.

In the example shown, the guide means 4 are formed by two rings 13 placed on either side next to the carrier 2, along which the weights 3 can be moved. These rings 13 are recessed here in the side plates 5. The rings 13 extend eccentrically in the horizontal direction with respect to the axis of rotation A of the carrier 2, and have a somewhat oval shape, the long axis of which is oriented vertically. In fact, the rings 13 are in the form of a circle pressed on an 8 side. Due to this shape of the rings 13, each weight 3 is accelerated very strongly in the radial direction upon reaching the highest point of its path around the axis A, or just before that. This releases a lot of energy. The long axis of each ring 13 is tilted slightly so that the weights 3 are already forced inwards in a radial direction before reaching the lowest point of their path.

In the example shown, the conversion device 1 is further provided with secondary bearing means 14, which are arranged along the circumference of the carrier 2. These secondary bearing means 14 are here formed by a number of spacers 15 extending from the carrier 2 to each of the side plates 5, and a bearing ring 16 arranged on each side plate 5 which receives the spacers 15. Each bearing ring 15 extends remotely around the guide ring 13 (Fig. 3).

The path that each of the weights 3 traverses during the rotation of the carrier 2 about the axis A is shown in Fig. 4. Starting from the position at the top right (indicated as 3 °) the weight moves downwards under the influence of gravity wherein, under the influence of the centrifugal force, it tries to move in a radial direction along its guide track 8 from the axis line A. This radial movement is prevented by the guide rings 13. When the weight has almost reached its lower position 35, the radius of the guide ring 13 starts to decrease, whereby the weight 3 is forced during its upward movement in the radial direction to the axis line 30A. . Approximately at the level of the axis line A the radius of the guide ring 13 starts to increase again, so that the weight 3 starts to move out again from position 312. The weight 3 is thus "flung", as it were.

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Due to the variation in the distance of the weight from the axis line A, a torque is generated in the carrier 2, which torque is delivered to the axle 6.

While in Fig. 4 the movement of a single weight 5 is shown, it will be clear that each of the weights traverses the same path. This is shown in Figs. 5A to 5D, which shows an embodiment of the conversion device 101 with four weights 103a-103d and guide tracks 108. In these views, we can see how the weights 103-103d 10 move towards each other and from each other.

In an embodiment of the conversion device 301 which is currently being made ready for practical tests, two carriers 302 with spacing are placed next to each other, and the weights 303 are accommodated in the space between those carriers 302 (Fig. 7). Each weight 303 herein has a connecting part 310 which extends on either side through the guide tracks 308 in the two carriers 302 and to within the rings 313 of the guide means 304. In this example, the guide tracks 308 are in the form of a hockey stick; they are substantially straight and have a curved segment only at the radially outer end 309 (FIG. 8). This causes a short but violent swinging movement of the weights 303. Incidentally, it can be seen that the straight parts of the guide tracks 308 here are not purely radially oriented, but are staggered with respect to the axis line A.

Although the invention has been explained above on the basis of a number of examples, it will be clear that it is not limited thereto. For example, more or fewer carriers and weights could be used than shown here, and the carriers and weights could also have other shapes and dimensions. For example, instead of being disc-shaped with guide tracks, the carrier could also be designed as a wheel with spokes along which the weights could be slidable.

The scope of the invention is therefore solely determined by the following claims.

1034252

Claims (18)

Device for converting gravitational energy into kinetic energy, comprising: - at least one carrier rotatable about a horizontal axis with at least one weight mounted thereon, which is movable substantially in the radial direction relative to the axis, and - means cooperating with the carrier for guiding the radial displacement of the at least one weight. 2. Conversion device as claimed in claim 1, characterized in that the guide means are adapted to accelerate the at least one weight near the top of its path around the axis of rotation in a radial direction away from the axis. 3. Conversion device as claimed in claim 1 or 2, characterized in that a number of weights are arranged distributed on the carrier in circumferential direction. 4. Conversion device as claimed in any of the foregoing claims, characterized in that the or each weight is slidably mounted on or in the carrier in radial direction. 5. Conversion device as claimed in claim 4, characterized in that the carrier has the shape of a disc on which or in which a substantially radially extending guide track is formed for the or each weight. 6. Conversion device as claimed in claim 5, characterized in that the or each guide track has a track segment curved in the direction of rotation at least at its end furthest away from the axis. 1034252 7. Conversion device as claimed in claim 6, characterized in that the or each guide track has the shape of a hockey stick. 8. Conversion device according to claim 6, characterized in that the or each guide track has a smooth curvature substantially over its entire length. Conversion device according to one of claims 5 to 8, characterized in that the or each guide track has at least partially interrupted edges. The conversion device as claimed in any one of claims 5 to 9, characterized in that the or each weight is of divided design and has a connecting part extending between the weight parts through the guide track in the disc-shaped carrier. 11. Conversion device as claimed in any of the claims 5 to 9, characterized in that in each case two disc-shaped carriers with spacing are placed parallel to each other and share one or more weights arranged in the spacing, and the or each weight on either side in the guide tracks of the disc-shaped carriers have projecting connecting parts. 12. Conversion device as claimed in any of the foregoing claims, characterized in that the guide means comprise at least one ring placed next to the carrier and extending substantially parallel to the plane of the rotational movement thereof, along which the or each weight is movable. 13. Conversion device according to claim 12, characterized in that the guide means comprise two rings placed on either side of the carrier. A conversion device as claimed in claim 12 or 13, characterized in that the or each ring extends eccentrically in the horizontal direction with respect to the axis of rotation of the carrier. 15. Conversion device as claimed in any of the claims 12 to 14, characterized in that the or each ring has a substantially vertically oriented, substantially oval shape. 16. Conversion device as claimed in any of the foregoing claims, characterized by secondary bearing means arranged along the periphery of the carrier. 17. Conversion device according to claim 16, characterized in that the secondary bearing means comprise a number of spacers extending from the carrier to the guide means and a bearing ring arranged around the guide means and receiving the spacers. 18. Conversion device as claimed in any of the foregoing claims, characterized in that at least the carrier and / or the guide means are made of glass. 1034252