WO2008097402A2 - Dispositif générant de l'énergie par la force gravitationnelle - Google Patents

Dispositif générant de l'énergie par la force gravitationnelle Download PDF

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Publication number
WO2008097402A2
WO2008097402A2 PCT/US2007/085642 US2007085642W WO2008097402A2 WO 2008097402 A2 WO2008097402 A2 WO 2008097402A2 US 2007085642 W US2007085642 W US 2007085642W WO 2008097402 A2 WO2008097402 A2 WO 2008097402A2
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WO
WIPO (PCT)
Prior art keywords
rotational
rotational member
coupled
gear
members
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Application number
PCT/US2007/085642
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English (en)
Other versions
WO2008097402A8 (fr
Inventor
Morrie Munir K. Agaid
Original Assignee
Agaid Morrie Munir K
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Filing date
Publication date
Application filed by Agaid Morrie Munir K filed Critical Agaid Morrie Munir K
Publication of WO2008097402A2 publication Critical patent/WO2008097402A2/fr
Publication of WO2008097402A8 publication Critical patent/WO2008097402A8/fr

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F03MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
    • F03GSPRING, WEIGHT, INERTIA OR LIKE MOTORS; MECHANICAL-POWER PRODUCING DEVICES OR MECHANISMS, NOT OTHERWISE PROVIDED FOR OR USING ENERGY SOURCES NOT OTHERWISE PROVIDED FOR
    • F03G7/00Mechanical-power-producing mechanisms, not otherwise provided for or using energy sources not otherwise provided for
    • F03G7/10Alleged perpetua mobilia
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K53/00Alleged dynamo-electric perpetua mobilia

Definitions

  • This invention relates generally to an energy generating device and more particularly to a gravitational force energy generating device.
  • Energy has become a virtually necessary aspect of life and is required to perform many tasks and duties daily. Energy may be used to provide heat, light and power for human activities. Centralized power generation became common in order to transport electricity through alternating current electric power lines across great distances and then transforming the voltage using power transformers.
  • Electricity has been generated from various sources of energy.
  • Conventional energy generation is performed by use of power plants that run on petroleum, natural gas, coal, hydroelectric and nuclear power. Other conventional energy generation is from hydrogen, solar energy, tidal harnesses, wind generators, and seothermal sources.
  • Common forms of generating energy include rotating turbines and reciprocating engines. Rotating turbines are attached to electrical generators and are driven by a fluid which acts as an intermediate energy carrier. The fluids typically used include steam, water, wind, and hot gases.
  • there are combined cycle gas turbine plants which are driven by both steam and gas. They generate power by burning natural gas in a gas turbine and use residual heat to generate additional electricity from steam.
  • Conventional reciprocating engines include small electricity generators that are powered by reciprocating engines burning a form of fuel.
  • the conventional energy generating devices are often used for back up energy generation.
  • the present invention relates to a gravitational force energy generating device having rotational members that are rotated due to gravitational force being exerted on the rotational members and/or gravitational force being mechanically transferred to the rotational members thereby providing movement of the rotational members.
  • the movement of the rotational members produces energy.
  • An aspect of the present invention includes a gravitational force energy generating device comprising a first rotational member having an axis of rotation and a second rotational member having an axis of rotation coupled to the first rotational member.
  • the first and second rotational members each have an equivalent force being exerted in opposite directions such that each of the first and the second rotational members are balanced.
  • the present invention further comprises an external force generated by gravitational force, the external force being applied to one of the first and second rotational members, wherein the external force causes rotation of the first and second rotational members.
  • the axis of rotation for each the first and second rotational members are the same axis. Additionally, in other embodiments, the axes of rotation of each of the first and second rotational members are independent axes.
  • the external force may be applied directly to one of the first and second rotational members. Further, in other particular embodiments, the external force may be mechanically transferred to one of the first and second rotational members.
  • FIG. IA is a side view of a gravitational force energy generating device and external force mechanism, in accordance with the present invention.
  • FIG. IB is a side view of a gear of a gravitational force energy generating device
  • FIG. 2A is a front view of a car of an external force mechanism, in accordance with the present invention.
  • FIG. 2B is a front view of a car of an external force mechanism, in accordance with the present invention.
  • FIG. 3 is a front view of a portion of an external force mechanism, in accordance with the present invention.
  • FIG. 4 is a side view of a gear of an external force mechanism, in accordance with the present invention.
  • FIG. 5 is a side view of a gear mechanism optionally usable with a gravitational force energy generating device, in accordance with the present invention
  • FIG. 6 is a side view of another gear mechanism optionally usable with a gravitational force energy generating device in accordance with the present invention.
  • FIGs.7A and 7B are a side views of an optional gravitational force energy generating device, in accordance with the present invention.
  • FIG. 8A is a side view of another gravitational force energy generating device, in accordance with the present invention.
  • FIG. 8B is a side view of a portion of the gravitational force energy generating device of FIG. 8A;
  • FIG. 8C is an end view of a portion of the gravitational force energy generating device of FIG. 8A;
  • FIG. 9A is a side view of another configuration of the gravitational force energy generating device of FIG. 8A;
  • FIG. 9B is a side view of a portion of the gravitational force energy generating device of FIG. 9A;
  • FIG. 10 is a side view of further still another embodiment of a gravitational force energy generating device
  • FIG. 11 is a front view partial view of the gravitational force energy generating device of FIG. 10;
  • FIG. 12 is an end view of a rotational member of the gravitational force energy generating device of FIG. 10;
  • FIG. 13 is a side view of a telescoping portion of the gravitational force energy generating device of FIG. 10;
  • FIG. 14 is a side view of another configuration of a gravitational force energy generating device
  • FIG. 15 is a side view of hinged legs of the gravitational force energy generating device of FIG. 14;
  • FIG. 16A is a side view of a gravitational force energy generating device with a slidable rotational member
  • FIG. 16B is an end view of a slideable rotational member of FIG. 16B.
  • embodiments of the present invention relate to a gravitational force energy generating device having rotational members that are rotated due to gravitational force being exerted on the rotational members and/or gravitational force being mechanically transferred to the rotational members thereby providing movement of the rotational members.
  • the movement of the rotational members produces energy.
  • Figs. IA, IB and 3 depicts a side view of a gravitational force energy generating device 10 with an external force mechanism 30.
  • the energy device 10 may include a scale type device having base members G supporting the various components of the energy device 10.
  • the energy device 10 further comprises a first rotational member 12 and a second rotational member 14.
  • the rotational members 12, 14 have an axis of rotation D.
  • Force is applied at point C of the first rotational member 12 and at point B of the second rotational member 14.
  • the force applied at points C and B are substantially equal, and in particular embodiments, may be in the amount of 20 tons at each point. It will be understood that various amount of force may be applied at points B and C depending in part upon the amount of energy output desired from the energy device 10.
  • an external force may be applied down at point A to cause the first and second rotational members 12 and 14 to rotate in a first direction and may then be applied upward at point A to rotate the first and second rotational members in an opposite second direction.
  • the external force may be applied to A by a gravitational force and/or from a gravitational force mechanism that transfers the force at point A, which will be discussed with reference to Figs. 2-7.
  • the amount of force required at point A is minimal and in particular embodiments may be 5% or less than the force at points B and C.
  • the rotation of the second rotational member 14 translates movement to linkage mechanism 20.
  • the linkage mechanism 20 has connection arm E, transfer arm S, rotation arm T and cam connector arms H. Arm E is coupled to the second rotational member 14 at point B such that a coupling at point B is fixed on arm E and connects with slot 16 of the second rotational arm 14.
  • the linkage mechanism 20 is used to drive a portion of an external force mechanism, the movement and force being transferred to cam I through connections 22 to cam connector arms H. As the second rotational arm 14 rotates, it moves the linkage system 20, which in turn rotates cam I.
  • the external force mechanism 30 includes a first roll chain 32 and a second roll chain 34.
  • the first and second roll chains 32 and 34 each include two gears and/or pulleys L.
  • the gear L includes a shaft that connects the gear L with another gear L as shown in Fig. 4.
  • the external force mechanism 30 further includes a rail section N having a plurality of cars R moveably coupled to the rail section N. In particular embodiments, there are twenty cars R each car having a weight of approximately one ton. It will be understood that the cars may be of any weight sufficient to accomplish the desired amount of energy output.
  • the cars R on a first side 36 of rail section N are allowed to freely drop by the pulling of the gravitational force on the cars R.
  • the cars R are lifted on a second side 38 of the rail section N.
  • the falling of the cars R engages the first roll chain 32 and cause the bottom gear L to rotate.
  • the bottom gear L of the first roll chain 32 is coupled to a cam M having a linkage U that is couple to cam M at one end and to point A of the energy device 10 at the other end.
  • cam M rotates, it applies force at point A of the energy device 10 and causes the energy device 10 to operate.
  • the energy device in turn rotates cam I which transfers movement to the second roll chain 34 and thereby lifts the roll chain. Timing between the roll chains 32 and 34 is critical.
  • cam M is a single stroke that results in two strokes of the linkage system 20, the result being rotation of gear L of the first roll chain 32 rotating at substantially the same rotational speed as gear L of the second roll chain 34.
  • the timing of the chains 32 and 34 may be adjusted by adjusting the length of arm E from the center at point B to the connection of arm E with arm S. When such an adjustment of arm E is made, an adjustment to the force applied at point C may be necessary to ensure that substantially equal force is being applied at points B and C.
  • the rail section N may be formed such that the distance between the first side and the second side allow for the car R to engage with opposite direction of teeth on each the first roll chain 32 and the second roll chain 34.
  • other ways of releasing the car R and transferring sides may include using a pushing arm and/or using pulleys on the top and bottom turns of the rail section that will turn at the same speed in the same direction to move the cars R along the rail section N and between engagements of the first roll chain 32 and the second roll chain 34.
  • the turning of the gears L of each of the first roll chain 32 and the second roll chain 34 can translate the rotational force through output shaft 60.
  • the output shaft 60 is coupled to a type of power generator or power plant.
  • the output shaft 60 may be coupled to a turbine that turns at the rate and force of the output shaft 60.
  • each gear L with shaft J may have an output shaft 60.
  • These output shafts 60 may be used concurrently in order to produce greater power.
  • the gravitational force energy generating device 10 may be used in accordance with various power scales.
  • the device may by used to produce large amounts of power and be sized to do so or may be used with a plurality of energy generating devices to generate greater power.
  • the gravitational force generating device may be used on a small scale to power a single family home having a smaller generator and smaller power consumption.
  • the cars R may have a plurality of rollers that engage the rail section N.
  • the cars may also have two sections 50 and 52 that are hingedly coupled together at hinge point 54. This allows each section of 50 and 52 to bend to a maximum angle 56 in order to move properly around any turns in the rail section N.
  • rollers 51 and opposing rollers 53 are coupled to the car R.
  • Track space 58 is defined between the rollers 51 and 53, the space 58 configured to receive a track therein and retain the car R on the track.
  • the car R further includes a shaft S on each side of the car R. The shafts S engage the first roll chain 32 when the car R is on the first side 36 of the rail section N.
  • the shafts S engage the second roll chain 34 when on the second side 38 of the rail section N.
  • the engagement of the first roll chain 32 by the car R allows for the roll chain 32 to turn gears L.
  • the engagement of the second roll chain 34 by the car R allows for the roll chain 34 to lift the car R up the rail section N by the energy device rotating the gear L of the second roll chain 34.
  • the gear L may have teeth 70.
  • the teeth 70 engage either the first roll chain 32 or the second roll chain 34.
  • the engagement of the teeth 70 with either the first or second roll chain 32 and 34 allows for rotation of either the roll chain in response to the rotation of the gear L or the rotation of the gear L in response to the rotation of the chain.
  • Figs. 5 and 6 are optional replacements of cam I.
  • Fig. 5 depicts two individual gear arms V that engage a gear Q.
  • Each arm V engages the gear Q in a single direction such that as the gear arms V move up one gear arm V rotates the gear Q and as the gear arms V move down, the other gear arm V rotates the gear Q.
  • the gear arm W may have spring type teeth 72 that may be used to engage the second roll chain 34. As the gear arm W moves down, the teeth 72 rotate toward the gear arm W and upon the gear arm W moving up, the teeth remain extended and engage the roll chain 34 and rotate the roll chain. It will be understood while these options are shown, other various components may be used to rotate the second roll chain and lift the cars R up the rail section N.
  • the gravitational force energy generating device may be applied to a rail track on an inclined hill.
  • the cars R of Figs. 1 and 3 may be replaced with rail cars, wherein the rail cars weight is adjustable.
  • the roll chains 32 and 34 may be replaced with a plurality of gears having arms that extend therefrom and directly engage the rail cars as they travel on the track.
  • the cars engage the arms of gears on a first side of the track as the cars travel down hill, and the arms of the gears on a second side of the track engage and lift the cars on the second side of the track.
  • the plurality of gears may be coupled to a plurality of gravitational force energy generating devices.
  • the plurality of energy devices allows for the generation of a greater amount of energy. In essence, the greater the weight that can be handled by the device and its components, the greater the power that can be generated using the device.
  • FIGs. 8A-8C depict an embodiment of a gravitational force energy generating device 210.
  • the device 210 comprises an outer track 212, an inner track 214, a plurality of rotational members 216 and a plurality of legs 218.
  • the plurality of rotational members 216 are operatively coupled to the outer track by use of rollers 220.
  • Each leg 218 is coupled on one end to one rotational member 216 and on the other end to the inner track 214 by use of rollers 222.
  • the legs 218 are coupled on one end to rotational member bar 217, which is coupled to the rotational member 216, and the legs 218 are coupled on the other end to hinge member 221, which has rollers 222 to engage the inner track 214.
  • the plurality of legs are such that two legs 218 are coupled to each roller 222, with one leg 218 coupled to one rotational member 216 and the other leg 218 is coupled to an adjacent rotational member 216.
  • the plurality of rotational members 216 are coupled to the outer track 212 such that the may travel around the track by use of the rollers 220.
  • the outer track 212 and the inner track 214 are configured such that the spacing between the tracks 212 and 214 varies. This varying of the spacing between the tracks 212 and 214 is such that when the rotational members 216 are on a first track portion with the tracks 212 and 214 spaced furthest apart, the rotational members are close together and the legs 218 are in a closed position. Further, when the rotational members 216 are on a second track portion with the tracks 212 and 214 spaced closest together, the rotational members 216 are spaced apart and the legs 218 are in an opened position.
  • the coupling of the legs to each rotational member link all of the rotational members such that the movement of one of the rotational members 216 around the outer track rotates all of the rotational members and the legs 218 around the outer track 212 and inner track 214 respectively.
  • the gravitational force applied to the rotational members 216 located on the first track portion is greater than the gravitational force applied to the rotational members located on the second track portion.
  • the difference in the gravitational force is due to the number of the rotational members 216 located on the first track portion being greater than the number of rotational members 216 located on the second track portion.
  • the rotational members 216 may include two outer disk portions 219 and an inner portion 217 connecting the two outer portions.
  • the outer track 212 and the inner track 214 to have two separate tracks that are substantially the same in shape and size.
  • the rotational members 216 may then engage the outer tracks 212 by use of rollers 220 copuled to each outer disk portion 219.
  • legs 218 may be rotatably coupled to each outer disk portion 219 and to each hinge member 221 associated with the outer disk portion 219.
  • Each hinge member 221 includes rollers 222 to engage the inner tracks 214.
  • the rotational members 216 may engage an output device (not shown) similar to the output mechanism 206 of FIG. 9.
  • the output mechanism may transfer the created energy to a power generator.
  • FIGs. 9 A and 9B another embodiment of a gravitational force energy generating device 200 is depicted.
  • a first car 202 travels down having a gravitational force F 1 acting on the first car 202, the force F 1 being governed by the configuration of the first car 202 with legs 203 extended.
  • a second car 204 travels up having a gravitational force acting on the second car 204, the gravitational force being governed by the configuration of the second car 204 with legs 203 retracted.
  • the modification of the configuration of the car as it moves from the second side to the first side affects the forces such that the force F 1 is greater than twice the gravitational force acting on the second car 204. This difference in force allows for the first car 202 to travel down and lift the second car 204. As the cars 202 and 204 travel around the device 200, they engage output mechanism 206 that transfers the energy created from the device 200 to external applications.
  • the legs 203 of the car 202/204 may be coupled to track engagement members 201.
  • the track engagement members 201 include a body 209 and rollers 205.
  • the legs 203 are rotatably coupled to the track engagement members 201 and the rollers 205 are coupled in a configuration with a space between the rollers 205 for receiving and engaging a track.
  • the device 200 is shown with two cars that particular embodiments of the present invention include a plurality cars traveling around device 200, wherein the plurality of cars are coupled together by use of the track engagement members 201, wherein the leg 218 of one rotational member is coupled on one end to an end of the track engagement members 201, and the leg 218 of another rotational member is coupled on the other end of the track engagement members 201. All rotational members may be coupled in a series until there is a loop rotational members coupled together as part of the device 200.
  • FIGs. 10-13 depict another embodiment of a gravitational force energy generating device 100 in accordance with particular embodiments of the present invention.
  • the device 100 includes a first rotational member 102, a second rotational member 104, a base 114 and a guide track 112.
  • the first rotational member 102 and the second rotational member 104 each include an axis of rotation that is the same axis.
  • the first and second rotational members 102 and 104 are configured to extend in opposite directions from a central hub 110, each having a telescoping portion having an inner portion 106 and an outer portion 108.
  • the first and second rotational members 102 and 104 each have two rollers coupled to them for maintaining engagement with the track 112.
  • the central hub 110 and the guide track 112 are each coupled to the base 114 such that the axis of the central hub 110 and the axis of the track 112 are not the same axis and are parallel each other. This allows the first and second rotational members 102 and 104 to move from an extended position to a retracted position as the rotational members 102 and 104 travel around the track 112. Since the first and second rotational members 102 and 104 extend in opposite directions, when the first rotational member 102 is fully extended, the second rotational member 104 is fully retracted.
  • This configuration creates a force differentiation between the first and second rotational members 102 and 104.
  • the gravitational force on the first rotational member 102 when extended is greater than the gravitational force on the second member 104 as applied around the central hub 110, such that the first and second rotational members 102 And 104 travel around the track 112 in a direction equivalent to the direction of the force applied to the first rotational member 102.
  • the first rotational member 102 and 104 rotate around track 112
  • the first rotational member 102 retracts as the second rotational member 104 extends.
  • the gravitational force will then be greater on the second rotational member 104 causing the rotational members 102 and 104 to continue in rotation.
  • a plurality of rotational member may be used, each rotational member having another rotational member extending in a direction opposite another rotational member.
  • the plurality of rotational mambers may be an even number of rotational members, such that each rotational member is coupled to an opposite side of the hub from another rotational member. As the rotational members rotate, output shaft 120 rotates and allows for the translation of energy for other uses.
  • first and second rotational members 102 and 104 may include support structures 103 to connect each portion of the rotational member 102/104 together when used on a double guide track 112.
  • the support structures may be I-beams.
  • the telescoping portion may include various levels of telescoping portions, such as portions 130, 132 and 134 of FIG. 13.
  • Figs. 14 and 15 depict a gravitational force energy generating device 140.
  • the device 140 includes an out put shaft 142, a central hub 143, a first rotational member 146, a second rotational member 148 and guide track 144.
  • the first and second rotational members 146 and 148 may be coupled to the central hub 143 by use of hinged arms 150 and 152 respectively.
  • the rotational members 146 and 148 are coupled to the track 144 by use of wheels 152.
  • the first and second rotational members 146 and 148 are configured such that they extend from the central hub 143 in opposite directions.
  • the central hub 143 and the guide track 144 are configured such that the axis of the central hub 143 and the axis of the track 144 are not the same axis and are parallel each other. This allows the first and second rotational members 146 and 148 to move from an extended position to a retracted position as the rotational members 146 and 148 travel around the track 144.
  • the hinged legs 150 and 152 will continuously move from a bent position to a straightened position depending on the location of the first and second rotational members 146 and 148 respectively. Since the first and second rotational members 146 and 148 extend in opposite directions, when the first rotational member 146 is fully extended, the second rotational member 148 is fully retracted.
  • This configuration creates a force differentiation between the first and second rotational members 146 and 148.
  • the gravitational force on the first rotational member 146 when extended is greater than the gravitational force on the second member 148 as applied around the central hub 143, such that the first and second rotational members 146 and 148 travel around the track 144 in a direction equivalent to the direction of the force applied to the first rotational member 146.
  • the first rotational member 146 and 148 rotate around track 144, the first rotational member 146 retracts as the second rotational member 148 extends.
  • the gravitational force will then be greater on the second rotational member 148 causing the rotational members 146 and 148 to continue in rotation.
  • a plurality of rotational member may be used, each rotational member having another rotational member extending in a direction opposite another rotational member. As the rotational members rotate, output shaft 142 rotates and allows for the translation of energy for other uses.
  • the gravitational force energy generating device 140 may include more than one hinged leg 150.
  • the device 140 may include hinged legs 150 and 151, each extending and retracting as the rotational memberl46 or 148 rotates around the track 144. Any number of legs may be used in conjunction with each other in accordance with the present invention.
  • FIGs. 16A and 16B depict another embodiment of a gravitational force energy generating device 230 in accordance with particular embodiments of the present invention.
  • the device 230 includes a first rotational member 232, a second rotational member 234, a rotational frame 242 and a guide track 240.
  • the first rotational member 232 and the second rotational member 234 each include an axis of rotation that is the same axis.
  • the first and second rotational members 232 and 234 are configured to couple within guide channels 244 of the rotational frame 243, the guide channels 244 extending in opposite directions from a central hub 238 of the rotational frame 242.
  • the first and second rotational members 232 and 234 each have two rollers 236 coupled to an end of the rotational members 232 and 234 for engaging the guide track 240.
  • the first and second rotational members 232 and 234 each have two rollers 239 coupled to another end of the rotational members 232 and 234 for engaging the guide channel 244.
  • the axis of the central hub 238 and the axis of the track 240 are not the same axis and are parallel each other. This allows the first and second rotational members 232 and 234 to move from an extended position to a retracted position within the guide channels 244 as the rotational members 232 and 234 travel around the track 240. Since the first and second rotational members 232 and 234 include channel members 231 that engage guide channels 238 that extend in opposite directions, when the first rotational member 232 is fully extended, the second rotational member 234 is fully retracted.
  • This configuration creates a force differentiation between the first and second rotational members 232 and 234.
  • the gravitational force on the first rotational member 232 when extended is greater than the gravitational force on the second member 234 as applied around the central hub 238, such that the first and second rotational members 232 and 234 travel around the track 240 in a direction equivalent to the direction of the force applied to the first rotational member 232.
  • the first rotational member 232 retracts as the second rotational member 234 extends within their respective channel guides 244.
  • the gravitational force will then be greater on the second rotational member 234 causing the rotational members 232 and 234 to continue in rotation.
  • a plurality of rotational member may be used, each rotational member having another rotational member within channel guides extending in a direction opposite each other. As the rotational members rotate, output shaft 250 rotates and allows for the translation of energy for other uses.
  • rotational members 232 and 234 may travel within the guide channel 244, where rollers engage the inner surface 241 of the channel guide 244.
  • Other embodiments may have rotational members 232 and 234 that engage the channel guide 244 such that rollers engage the outer surface 243 of the channel guide.
  • FIG. 7 A and 7B other particular embodiments of the present invention include another optional gravitational force energy generating device 90.
  • the device 90 has an outer ring 92 and inner member 98 and first rotational member 94 and an opposing second rotational member 96.
  • the rotational members 94 and 96 are coupled between the outer ring 92 and the inner member 98.
  • the second rotational member 96 is fully retracted. In this position, the gravitational force in addition to a longer lever arm will pull the first rotational member 94 down and begin the rotation.
  • the first member 94 retracts at the same rate that the second member 96 extends.
  • the gravitational force in combination with the extended second rotational member 96 will further allow the device 90 to continue to rotate. It will be understood that an equal amount of a plurality of first rotational members 94 and second rotational members 96 may be used to provide continual rotation of the device 90.
  • the device 90 may be coupled to a power generator, wherein the rotation of the device 90 operates the generator. It will be understood that this particular embodiment operates similar to a scale with one side of the scale shifting the weight closer to the fulcrum, thereby allowing the side with the weight further away from the fulcrum to travel downward. Additionally, it is similar to a cylindrical roll having an off-center axis of rotation, wherein the portion of the cylinder furthest from the axis of rotation falls downward.
  • rollers that are not integral with the rotating members, but rather the rollers may be a separate part of the system where in the rotational members travel on the rollers.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Connection Of Motors, Electrical Generators, Mechanical Devices, And The Like (AREA)

Abstract

La présente invention concerne un dispositif générant de l'énergie par la force gravitationnelle, qui comprend un mécanisme de translation, un mécanisme générant une force externe et une tige de sortie. Le mécanisme de translation comprend un premier élément rotationnel ayant un axe de rotation et un second élément rotationnel couplé de manière opérationnelle au premier élément rotationnel. Le second élément rotationnel a un autre axe de rotation. Le mécanisme générant la force externe applique une force externe à l'un des premiers et second éléments rotationnels. La tige de sortie transfère l'énergie hors du dispositif de génération d'énergie par la force gravitationnelle.
PCT/US2007/085642 2006-12-08 2007-11-27 Dispositif générant de l'énergie par la force gravitationnelle WO2008097402A2 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US86915306P 2006-12-08 2006-12-08
US60/869,153 2006-12-08
US85216407A 2007-09-07 2007-09-07
US11/852,164 2007-09-07

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WO2008097402A2 true WO2008097402A2 (fr) 2008-08-14
WO2008097402A8 WO2008097402A8 (fr) 2008-10-30

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2546520A1 (fr) * 2011-07-13 2013-01-16 Rolf-Dieter Rössler Procédé de développement ultérieur et de fabrication de dispositifs d'entraînement, de moteurs, de renforceurs, de balances doubles horizontales/verticales, de moteurs à gravitation etc.
WO2013182216A1 (fr) 2012-06-09 2013-12-12 Roessler Rolf-Dieter Génération d'énergie cinétique en excès à partir de systèmes rotatifs soumis en permanence à des charges asymétriques
WO2018041310A1 (fr) 2016-08-30 2018-03-08 Hans Krissler Praepondium

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2546520A1 (fr) * 2011-07-13 2013-01-16 Rolf-Dieter Rössler Procédé de développement ultérieur et de fabrication de dispositifs d'entraînement, de moteurs, de renforceurs, de balances doubles horizontales/verticales, de moteurs à gravitation etc.
WO2013182216A1 (fr) 2012-06-09 2013-12-12 Roessler Rolf-Dieter Génération d'énergie cinétique en excès à partir de systèmes rotatifs soumis en permanence à des charges asymétriques
WO2018041310A1 (fr) 2016-08-30 2018-03-08 Hans Krissler Praepondium

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