GB2299648A - Rotatable wheel driven by gravity - Google Patents

Abstract

The wheel has a horizontal shaft and a numbed of symmetrical radial frames A. Each radial frame A has a sub-axis B which engages with a movable means C. Bulges D are disposed on a lateral side of the movable means C or on the radial frames A at a different distances from the sub-axis B or from the rotary shaft, so that when the movable means C drops down due to gravity force, it makes an alternate contact with the bulges D and presses against the radial frame A through the bulge thus creating an unbalanced torque on radial frame to drive the wheel in one direction. The wheel can be installed above ground or under water, or with one half above the water surface and one half below the water surface provided that the specific gravity of movable means be less than one. In such circumstances, gravity force and floating force of movable means joint together to create an unbalanced effect on radial frames to drive rotary wheel to rotate in one direction. It is alleged that the wheel rotates perpetually without consuming energy and can be used to generate electricity.

Description

Title: A Physical Energy Development Method The present invention relates to a physical energy development method and particularly to new method of developing energy and electricity that is safe, pollution-free, widely applicable, low cost and can be perpetually used, thereby to effectively resolve the energy supply problem and to enhance the welfare of humanbeing.

Energy development has been a big issue of mankind in the past few decades. Traditional fire electricity generation mainly use oil and coal as fuel. There fuels have limited supply and create environment pollution problem. To develop new form of energy sources has been a constant and critical issue worldwide. Some of the alternative energy sources have been developed and exploited, such as wind-mill electricity generation, solar energy electricity generation, or even tide electricity generation. However their applicability is restricted by geographical condition, time and temperature, and cannot be universally applied. They cannot fully meet the requirements of energy supply for the next century.

The embodiment of this invention are described by way of examples, with reference to the drawings in which: Fig. 1 is a plan view of embodiment one illustrating radial frame of a rotary wheel having a sub-axis disposed thereon, sub-axis engages with a movable means which has a groove formed therein, the opening of the groove is directed outward and in the opposition direction of sub-axis, there are bulges disposed on radial frame, the rotary wheel keeps rotating due to the system generating an unbalanced torque on radial frames.

Fig.2 is a plan view of a variation of embodiment one illustrating. radial frame of a rotary wheel having a sub-axis disposed thereon, sub-axis engages with a movable means which has a groove formed therein, the opening of the groove is directed outward and in the opposition direction of sub-axis, there are bulges disposed on the inside lateral walls of the groove, the rotary wheel keeps rotating due to the system generates unbalanced torque on radial frames.

Fig.3 illustrates a movable means for embodiment one in Fig. 1 having an extension-arm disposed on an outside wall to make force application point in rotational direction having a longer distance from rotary shaft.

Fig.4 illustrates another variation of embodiment one in Fig. 1, having an extension-arm disposed on an outside wall to make force application point in rotational direction having a longer distance from rotary shaft, having another extension arm disposed on radial frame in rotational direction and near sub-axis to make force application point in counter-rotational direction having a shorter distance from rotary shaft.

Fig.S is a plan view of embodiment two illustrating radial frame of a rotary wheel having a sub-axis disposed thereon, sub-axis engages with a movable means which has a groove formed therein, the opening of the groove is directed inward and faces rotary shaft, two bulges are disposed on radial frame in opposite direction and have different distance from sub-axis to generate unbalanced force on radial frame to make rotary wheel rotate.

Fig.6 illustrates an embodiment of a movable means of Fig.S having bulges disposed on the inside lateral walls of the groove instead of on radial frame.

Fig. 7 illustrates another embodiment of a movable means of Fig.S, having an extension arm disposed on the inside wall of the movable means to make force application point on radial frame in counter-rotational direction having a shorter distance from rotary shaft.

Fig.8 is a plan view of embodiment three illustrating radial frame of a rotary wheel having a sub-axis disposed thereon and at position in counter-rotation direction and far away from rotary shaft, sub-axis engages with a movable means, movable means has a bulge disposed in rotational direction side and near sub-axis, thereby rotational forces are applied on radial frame at the position of sub-axis and where the bulge presses against the radial frame, movable means also applies counter-rotational force on radial frame at a position where sub-axis connected with radial frame and at a position on a radial frame where the remote end of the movable means in counter-rotational direction and near rotary shaft making contact with radial frame, thus resulting in an unbalanced torque to keep rotary wheel moving.

Fig.9 illustrates a variation of embodiment three in Fig.8, having an extension arm disposed on the radial frame nearby the sub-axis and in counter-rotational direction, having another extension arm disposed on the radial frame nearby rotary shaft and in rotational direction.

Fig.lO illustrates another embodiment variation of a movable means of Fig. 8, movable means has a slot groove formed at one end near rotary shaft, a rope or rod runs across the slot groove and has its two ends engaging with a pair of radial frames.

Fig.ll is a plan view of embodiment four illustrating radial frame of a rotary wheel having a sub-axis disposed near rotary shaft and in rotational direction, sub-axis engages with a movable means, a bulge is disposed on a rotational side of movable mean and far away from sub-axis, movable means also has an extension arm disposed in counter-rotational side and near sub-axis, movable means applies rotational force on radial frame at the positions of sub-axis and where a bulge pressing against the radial frame, movable means also exerts counter-rotational force at the positions where sub-axis being connected with radial frame and where the extension arm makes contact with radial frame, thus resulting in an unbalanced torque to keep rotary wheel moving.

Fig. 12 illustrates an embodiment variation of a movable means of Fig. 11, having an extension arm disposed on a radial frame in counter rotational direction and far away from sub-axis, and having another extension arm disposed on a radial frame in rotational direction and close rotary shaft but beyond sub-axis.

Fig. 13 illustrates another embodiment variation of a movable means of Fig. 11, having a slot groove formed in the outside portion of movable means, a rope or rod runs across the groove and has its two end engaging with a pair of radial frames.

Fig. 14 is a plan view of embodiment five illustrating radial frame of a rotary wheel having a sub-axis disposed thereon and far away from rotary shaft in rotational direction, sub-axis engages with a movable means, an extension arm is disposed on a radial frame in rotational direction and beyond sub-axis relative to rotary shaft, another extension arm is disposed on a counter-rotational side of the movable means and close rotary shaft, thus resulting in an unbalanced torque to keep rotary wheel moving.

Fig. 15 is an embodiment variation of a movable means of Fig.14, having a slot groove formed in the inside portion toward rotary shaft, a rope or rod runs across the groove and has its two ends engaging with a pair of radial frames.

Fig. 16 is a plan view of embodiment six illustrating radial frame of a rotary wheel having a sub-axis disposed thereon in rotational direction and far away from rotary shaft, sub-axis engages with a movable means which has a slot groove formed across in the middle section except a small connecting section along a lateral side in rotational direction, an extension arm is disposed on radial frame in rotational direction and beyond sub-axis and far away from rotary shaft, a bulge is disposed on an inside wall of the connection section in counter-rotational direction, a rope or rod runs across the groove and has its two ends engaging with a pair of radial frames thus resulting in an unbalanced torque to keep rotary wheel moving.

Fig. 17 is an embodiment variation of a movable means of Fig. 16, having an extension arm disposed on the inside wall of the connection section to make force application point on radial frame in counter-rotational direction having a shorter distance from rotary shaft.

Fig. 18 illustrates another variation of embodiment six in Fig. 16, having extension arm disposed on radial frame in rotational direction and near rotary shaft, it makes force application point on radial frame in counter-rotational direction having a shorter distance from rotary shaft.

Fig. 19 is a plan view of embodiment seven which has a short radial frame between a pair of long radial frames, the remote end of short radial frame being set as a sub-axis and engages with a movable means, a bulge is disposed on one lateral side of the movable means in rotational direction and far away from sub-axis, an extension arm is disposed on another lateral side of the movable means in counter-rotational direction and close sub-axis thus resulting in an unbalanced torque to keep rotary wheel moving.

Fig.20 is an embodiment variation of a movable means of Fig. 19, having a slot groove formed at the outside portion, a rope or rod runs across the groove and has its two ends engaging with a pair of long radial frames.

The following is detailed description of the preferred embodiments: Referring to Fig. 1 for embodiment one of the present invention, a rotary wheel has even number of four or more of radial frames A, there is a sub-axis B disposed on a radial frame. Sub-axis B engages with a movable means C which has a triangle groove formed inside, the opening of the groove is directed outward of rotary wheel.A bulge D is disposed on radial frame within the groove in rotational direction and close sub-axis, another bulge D is disposed on radial frame within the groove in counter-rotational direction and is remoted from sub-axis, when movable means drops because of gravity force, it exerts force on the radial frame at the position of sub-axis and where locates bulge D, as the distance between rotary shaft and bulge D is longer in rotational direction than that in counter-rotational direction, there will be an unbalanced torque applied on radial frame thereby pushing rotary wheel to rotate.

Fig.2 shows a variation of embodiment shown in Fig. 1, instead of disposing bulges D on radial frame, they are disposed on the inside lateral walls of the groove.

Fig.3 shows a variation of movable means for embodiment one, an extension arm M is used to substitutive one of the bulges D.

Fig.4 shows another variation of embodiment shown in Fig.l, two extension arm substitute two bulges.

Fig.S illustrates embodiment two of the present invention. It is based on the same principle as that of embodiment one set forth above. The movable means has a groove opening directed toward rotary shaft. A bulge disposed on radial frame in rotational direction has a shorter distance to rotary shaft than a bulge disposed in counter-rotational direction, therefore an unbalanced force and torque will be applied on radial frame and drive rotary wheel to rotate.

Fig.6 shows a variation of movable means for embodiment two, with the bulges disposed on the inside lateral walls of the groove instead of on radial frame.

Fig.7 shows another variation of movable means for embodiment two, with an extension arm to substitute a bulge.

Fig.8 illustrates embodiment three of the present invention. It is based on the same principle as that of embodiment one set forth above, but having a sub-axis disposed on a radial frame in counterrotational direction and far away from rotary shaft. A bulge is disposed on a rotational side of movable means and close sub-axis.

Fig.9 shows a variation of embodiment shown in Fig.8, an extension arm is disposed on radial frame in counter-rotational direction and near sub-axis to substitute a bulge which is disposed on a rotational side of movable means and close sub-axis, another extension arm is disposed on radial frame in rotational direction and near rotary shaft.

Fig. 10 shows another variation of movable means for embodiment three, having a slot groove formed at one end close rotary shaft, and having a rope or rod runs across the groove and with two ends of the rope or rod engaging with a pair of radial frame.

Fig. 11 illustrates embodiment four of the present invention. It is based on the same principle as that of embodiment three, but having sub-axis disposed in rotational direction and close rotary shaft, an extension arm is disposed in counter-rotational direction side of movable means and close sub-axis.

Fig. 12 shows a variation of movable means for embodiment four shown in Fig.ll having two extension arms disposed on a radial frame, one is on a radial frame in counter-rotational direction and far away from sub-axis to substitute a bulge on the movable means, another one is on rotational direction and close sub-axis.

Fig. 13 shows another variation of movable means for embodiment four. It has a slot groove formed in the outside portion of movable means. A rope or rod runs across the groove and having its two end engages with a pair of radial frames. Two extension arms are disposed on movable means to generate unbalanced force on radial frame.

Fig. 14 illustrates embodiment five of the present invention. It is based on the same principle as that of embodiment four, but having a sub-axis disposed far away from rotary shaft, and having an extension arm E on a radial frame in rotational direction and beyond sub-axis, such that when movable means is moved across the downward vertical line of six o'clock position, movable means would promptly tilt toward inward side of rotary wheel.

Fig. 15 is a variation of movable means for embodiment five. It is similar to an embodiment shown in Fig. 10, except that sub-axis is disposed in rotational direction and an extension arm close to the rotary shaft is to substitute a bulge.

Fig. 16 illustrates embodiment six of the present invention. It is based on the same principle as that of embodiment five in Fig. 14, but having a slot groove formed across in the middle of a movable means and having a rope or rod F runs across the groove. The rope or rod has its two ends engaging with a pair of radial frames. A bulge is disposed on an inside wall of the groove in counterrotational direction and far away from sub-axis.

Fig. 17 shows a variation of movable means for embodiment six, with an extension arm to substitute a bulge.

Fig. 18 shows a variation of embodiment shown in Fig.17, instead of disposing extension arm M on the inside wall of the connection section, it is disposed on radial frame in rotational direction and near rotary shaft.

Fig. 19 illustrates embodiment seven of the present invention. It is based on the same principle as that of embodiment four in Fig. 11 but having a short radial frame disposed between a pair of long radial frames. The remote end of short radial frame serves as an sub-axis to engage a movable means.

Fig.20 shows a variation of a movable means for embodiment seven in Fig. 19. It essentially bases on same principle as that in Fig. 13, except that sub-axis is disposed on one end of a short radial frame rather than on a long radial frame.

Applying the present invention, a simple rotary wheel should be able to operate. However a plural number of rotary wheels disposed parallelly on a common rotary shaft would generate more steady pushing force. It can be setup by firstly set one rotary wheel on a rotary shaft, the rest rotary wheels should be mounted on the rotary shaft by shifting an angle against the first rotary wheel. The angle is determined as follow: 3600/Number of radial frames that have equal length in a rotary wheel/Number of rotary wheels on a rotary shaft.

Besides abovementioned arrangement of multiple rotary wheels mounting on a rotary shaft, another alternative is to have an inside rim and an outside rim on a rotary wheel, or have a plural number of rotary wheels each has an inside rim and an outside rim disposing on a common rotary shaft.

The specific gravity of movable means can be either homogeneous, or be greater at the inward portion close the rotary shaft, or be greater at the outward portion remote to the rotary shaft.

The rotary wheels in the embodiment set forth above can be set above ground surface. The specific gravity of movable means can be greater than one, or equals one, or be less than one.

The rotary wheel can also be disposed under water surface and becomes waterwheel, or have the rotary shaft disposed on water surface (i.e. having one half of rotary wheel above water surface, another half of rotary wheel below watersurface). In this circumstance, the specific gravity of rotary wheel should be less than one.

In summary, the present invention has the following characteristics.

1. Rotary wheel can be disposed above ground surface and have its rotary shaft at horizontal position, sub-axis on radial frame engages with a movable means which drops downward because of gravity force. Due to the interaction between the bulge or extension arm against movable means and radial frame, the net pushingforce and torque applying on radial frame in rotational direction is always greater than in counter-rotational direction, therefore resulting in an unbalanced torque to make rotary wheel rotates.

2. The specific gravity of movable means can be less than one.

In such case, the rotary wheel can be totally disposed under water surface, or has one half above water surface and another half below water surface.

3. It does not need advanced or complex technology.

Construction materials are easy to get and easy to substitute. Lost costs in construction and operation.

4. It's an energy development method that does not consume energy. It can be perpetually used and be totally controlled by humanbeing. It is highly reliable. No restriction in applicable environment. It's a much better energy alternative than solar energy or windmill.

S. It does not produce air pollution or waste and is environmentally healthy.

The present invention can achieve the following effects: 1. The generating kinetic energy can be used to generate electricity or be used directly in production.

2. It can substitute traditional fuel such as coal, oil, gas, nuclear energy, wood, etc. It produces no pollution or environment damage.

3. Lost cost. Helpful in improvement economic condition and people's quality of life.

4. Help energy importing countries to reduce dependency on imported fusel.

5. Simple and short installation lead time for electricity generation.

Can effectively resolve electricity shortage problem.

6. In the long term, it can direct the carbon-hydrogen fuel to other more valuable use, such as raw material for producing chemicals, plastics or synthetic fibers.

Claims (29)

Claims:

1. A rotary wheel comprising: a horizontal rotary shaft; four or more in even number of radial frames having one end connecting with said rotary shaft; a sub-axis disposed on a said radial frame; and a movable means having one end engages with said sub-axis and having a groove formed inside, said groove having an opening directed outward in the opposite direction relative to said rotary shaft;; wherein said radial frame further having a bulge disposed thereon in rotational direction and near said sub-axis, and having another bulge disposed in counter-rotational direction and far away from said sub-axis, both said bulges are disposed inside said groove of said movable means, thus when movable means drops because of gravity force, said movable means alternately presses against said radial frame on a said bulge which becomes one of the force application points, the distance of force application point in rotational direction from rotary shaft tO bulge is longer than the distance of force application point in counter-rotational direction from rotary shaft to bulge, thereby resulting in an unbalanced torque applying on said radial frame and driving said rotary wheel to rotate.

2. A rotary wheel of claim 1 wherein one said bulge is disposed on a lateral side of said groove in rotational direction and far away from said sub-axis while another said bulge is disposed on another lateral side of said groove in counter-rotational direction and near said sub-axis.

3. A rotary wheel of claim 1 wherein a said bulge in counter rotational direction and far away from said sub-axis is replaced by an extension arm disposed on an outside surface at counter rotational side of said movable means, said extension arm can makes contact with said radial frame.

4. A rotary wheel of claim 3 wherein a said bulge in rotational direction and near said sub-axis on radial frame is replaced by an another extension arm, said another extension arm can makes contact with the lateral side of groove in counter-rotational direction.

5. A rotary wheel comprising: a horizontal rotary shaft; four or more in even number of radial frames having one end connecting with said rotary shaft; a sub-axis disposed on a said radial frame; and a movable means having one end engages with said sub-axis and having a groove formed inside, said groove having an opening directed inward and face toward said rotary shaft; wherein said radial frame further having a bulge disposed thereon in rotational direction and far away from said sub-axis, and having another bulge disposed in counter-rotational direction and near said sub-axis, said bulge can make alternate contact with a lateral wall of said groove when said movable means drops down due to gravity force.

6. A rotary wheel of claim 5 wherein one said bulge is disposed on a lateral side of said groove in rotational direction and near subaxis, another one said bulge is disposed on another lateral side of said groove in counter-rotational direction and far away from said sub-axis.

7. A rotary wheel of claim 5 wherein one said bulge in rotational direction is replaced by an extension arm disposed on an inside surface at rotational side of said movable means, said extension arm can makes contact with said radial frame.

8. A rotary wheel comprising: a horizontal rotary shaft; eight or more in even number of radial frames having one end connecting with said rotary shaft; a sub-axis disposed on a said radial frame in counterrotational direction and far away from said rotary shaft; and a movable means having one end engages with said sub-axis and having a bulge or an extension arm disposed on a rotational side and near said sub-axis, and having a bulge or an extension arm disposed on counter-rotational side and near said rotary shaft, said bulge or extension arm can make alternate contact with a said radial frame when said movable means drops down due to gravity force.

9. A rotary wheel of claim 8 wherein a bulge or an extension arm is disposed on said radial frame in counter-rotational direction and near said sub-axis while another bulge or extension arm is disposed on said radial frame in rotational direction and near rotary shaft.

10. A rotary wheel of claim 8 wherein said movable means make contact with said radial frame at an inwardly direct end in counter-rotational direction without through a said bulge or an said extension arm.

11. A rotary wheel of claim 8 wherein said movable means having a slot groove formed at one end directed toward said rotary shaft and having a rope or rod runs across said groove, said rope or rod having its two ends engaging with a pair of said radial frames.

12. A rotary wheel comprising: a horizontal rotary shaft; eight or more in even number of radial frames having one end connecting with said rotary shaft; a sub-axis disposed on a said radial frame in rotational direction and near said rotary shaft; and a movable means having one end engages with said sub-axis and having a bulge or an extension arm disposed at rotational side and far away from said sub-axis, and having a bulge or an extension arm disposed at counter-rotational side and near sub-axis, either said bulge or extension arm can make alternate contact with said radial frame when said movable means drops down due to gravity force.

13. A rotary wheel of claim 12 wherein a bulge or an extension arm is disposed on said radial frame in rotational direction and beyond said sub-axis away from said rotary shaft while another bulge or extension arm is disposed on said radial frame in counterrotational direction and far away from said rotary shaft.

14. A rotary wheel of claim 12 wherein said movable means makes contact with said radial frame at a far away end from said sub-axis in rotational direction without through a said bulge or an said , extension arm.

15. A rotary wheel of claim 12 wherein said movable means having a slot groove formed at an outward section and having a rope or rod runs across said groove, said rope or rod having its two ends engaging with a pair of said radial frames.

16. A rotary wheel comprising: a horizontal rotary shaft; eight or more in even number of radial frames having one end connecting with said rotary shaft; a sub-axis disposed on a said radial frame in rotational direction and far away from said rotary shaft; and a movable means engages with said sub-axis at one end, wherein said radial frame further having an extension arm disposed in rotational direction and beyond said sub-axis away from said rotary shaft, and said movable means having a bulge or an extension arm disposed on one counter-rotational side and near said rotary shaft and far away from said sub-axis, either said extension arm can make alternate contact with said movable means or said radial frame when said movable means drops down due to gravity force.

17. A rotary wheel of claim 16 wherein said bulge or extension arm near said rotary shaft and far away from said sub-axis is replaced by a bulge or an extension arm disposed on said radial frame in rotational direction and near said rotary shaft and far away from said sub-axis.

18. A rotary wheel of claim 16 wherein said movable means makes contact with a said radial frame at a remote end from said sub-axis in counter-rotational direction and without through a said bulge or an extension arm.

19. A rotary wheel of claim 16 wherein said movable means having a slot groove formed at inward section toward said rotary shaft and having a rope or rod runs across said groove, said rope or rod having its two ends engages with a pair of said radial frames.

20. A rotary wheel of claim 19 wherein said slot groove formed across substantial area inside of said movable means except a side in rotational direction, a bulge is disposed on said radial frame against a connecting wall formed in said groove in rotational direction and far away from said sub-axis.

21. A rotary wheel of claim 20 wherein said bulge is disposed on said connecting wall of said movable means in counter-rotational direction and far away from said sub-axis.

22. A rotary wheel of claim 20 wherein said bulge is substituted by an extension arm which is disposed near said rotary shaft.

23. A rotary wheel of claim 22 wherein said extension arm is disposed on the inside wall of the connection section instead of on radial frame.

24. A rotary wheel comprising: a horizontal rotary shaft; four or more in even number of long radial frames having one end connecting with said rotary shaft; four or more in even number of short radial frames each being disposed between a pair of said long radial frames; a sub-axis being disposed on one end of said short radial frame; and a movable means engages with said sub-axis, wherein said movable means further having a bulge or an extension arm disposed at one lateral side in rotational direction and far away from said sub-axis, and further having a bulge or an extension arm disposed at another lateral side in counter-rotation direction and near said subaxis, either said bulge or said extension arm can make alternate contact with a said radial frame when said movable means drops down due to gravity force.

25. A rotary wheel of claim 24 wherein a bulge or an extension arm is disposed on a said long radial frame in rotational direction and near rotary shaft while another bluge or extension arm is disposed on a said long radial frame in counter-rotational direction and far away from said rotary shaft.

26. A rotary wheel of claim 24 wherein said movable means makes contact with a said long radial frame at a remote end in rotational direction without through a bulge or an extension arm.

27. A rotary wheel of claim 24 wherein said movable means has a slot groove formed inside at outward section and having a rope or rod runs across said groove, said rope or rod having its two ends engaging with a pair of said long radial frames.

28. A rotary wheels of either 1,5,8,12,16 or 24 wherein said movable means having specific gravity less than one and said rotary wheel is totally disposed under water surface.

29. A rotary wheels of either 1,5,8,12,16 or 24 wherein said movable means having specific gravity less than one and said rotary shaft is disposed on water surface.