WO2009151450A1 - Electro-magnetic circular engine - Google Patents
Electro-magnetic circular engine Download PDFInfo
- Publication number
- WO2009151450A1 WO2009151450A1 PCT/US2008/066670 US2008066670W WO2009151450A1 WO 2009151450 A1 WO2009151450 A1 WO 2009151450A1 US 2008066670 W US2008066670 W US 2008066670W WO 2009151450 A1 WO2009151450 A1 WO 2009151450A1
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- WIPO (PCT)
- Prior art keywords
- electro
- magnetic
- electrical
- magnets
- hub assembly
- Prior art date
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K53/00—Alleged dynamo-electric perpetua mobilia
Definitions
- the present invention relates to engines, and more particularly, to circular engines in which the motive force is electro-magnetism .
- Electro-magnetic systems comprise the basic principle that opposite poles attract and like poles repel each other. There are no electro-magnetic circular engines to the best of applicant's knowledge that include the rotation of a hub assembly in a predetermined direction continuously after the initial activation of the hub assembly by means of applying a short period of a force.
- An electro-magnetic circular engine comprising a hub assembly and a first electro-magnetic wheel rotatably mounted on the hub assembly.
- the first electro-magnetic wheel comprises first electro-magnets.
- a second electro-magnetic wheel surrounds the first electro-magnetic wheel and comprises second electro-magnets .
- the instant invention also has electro-magnetic means consisting of a distributor having first synchronizing means to send an electrical current to the first and second electromagnets.
- the electro-magnetic means generate an electro-motive force between the first and second electro-magnets when synchronized by the distributor, wherein engaging magnetic polarity between the first and second electro-magnets, forces the first electro-magnetic wheel to rotate with the hub assembly in a predetermined direction continuously after an initial activation of the electro-magnetic means. This is done by applying a short period of an electrical force to the hub assembly.
- the instant invention also comprises electrical means that comprise an electrical connection and a source of rechargeable battery power for supplying the rechargeable battery power for the short period of an electrical force.
- the electro-magnetic circular engine may further comprise a third electro-magnetic wheel rotatably mounted on the hub assembly.
- the third electro-magnetic wheel comprises third electro-magnets.
- the electro-magnetic means further has second synchronizing means to send an electrical current to the first, second, and third electro-magnets.
- the electro-magnetic means generate the electro-motive force between the first, second, and third electro-magnets when synchronized by the distributor, wherein engaging magnetic polarity between the first, second, and third electro-magnets forces the first and third electro-magnetic wheels to rotate with the hub assembly in a predetermined direction continuously after an initial activation of the electro-magnetic means. This is done by applying the short period of the electrical force.
- the electro-magnetic circular engine may further comprise a fourth electro-magnetic wheel surrounding the third electromagnetic wheel.
- the fourth electro-magnetic wheel comprises fourth electro-magnets.
- the electromagnetic means further has third synchronizing means to send an electrical current to the first, second, third, and fourth electro-magnets.
- the electro-magnetic means generate the electro-motive force between the first, second, third, and fourth electro-magnets when synchronized by the distributor, wherein engaging magnetic polarity between the first, second, third, and fourth electro-magnets forces the first and third electro-magnetic wheels to rotate with the hub assembly in a predetermined direction continuously after an initial activation of the electromagnetic means. This is done by applying the short period of the electrical force.
- the first, second, third, and fourth electro-magnets each comprise sensors to receive the electrical current via the electromagnetic means.
- the electrical means further comprises the source of rechargeable battery power having the electrical connection to a starter switch.
- the electrical means further comprises the starter switch having the electrical connection to a starter.
- the electrical means further comprises the starter switch having the electrical connection to at least one electrical coil.
- the electrical coil is an inverter, and has means to convert 24 volts DC to 240 volts AC.
- the electrical means further comprises the at least one electrical coil having the electrical connection to a mechanical pedal that is operated by a driver for acceleration.
- the mechanical pedal has the electrical connection to an electric accelerator.
- the mechanical pedal has the electrical connection to a computer.
- the computer has the electrical connection to the distributor, and the short period of an electrical force derives from a starter.
- the electro-magnetic circular engine further comprises at least three alternators connected to the hub assembly.
- the at least three alternators work at a minimum of 35 amps to over 600 amps each and recharge the rechargeable battery power.
- the first, second, third, and fourth electro-magnets requires scheduled maintenance and replacement at predetermined time intervals to maintain predetermined the electro-motive forces.
- the electro-magnetic circular engine set forth in claim 10, further comprises a cooling system and an engine oil system for lubrication and cooling.
- Figure IA is a schematic drawing showing a section of the electrical system of an electro-magnetic circular engine.
- Figure IB represents a cross sectional view of the preferred embodiment of the electro-magnetic circular engine.
- Figure 2 represents a cross sectional view of a first alternate embodiment of the electro-magnetic circular engine.
- Figure 3 represents a cross sectional view of a second alternate embodiment of the electro-magnetic circular engine.
- Figure 4 represents a cross sectional view of a third alternate embodiment of the electro-magnetic circular engine.
- Figure 5 represents a cross sectional view of a fourth alternate embodiment of the electro-magnetic circular engine.
- an electro-magnetic circular engine is shown at 10.
- the electromagnetic circular engine consists of hub assembly 20, electromagnetic wheel 30, electro-magnetic wheel 50, and electrical system 100, as seen in figures IA and IB.
- electrical system 100 comprises rechargeable batteries 102 and electrical wires 104 that electrically connect to each of the components described below.
- Rechargeable batteries 102 have sufficient power to start instant invention 10.
- Each of rechargeable batteries 102 has an electrical wire 104 that connects to starter switch 106.
- Starter switch 106 is connected to starter 108.
- Starter switch 106 connects to each of electrical coils 110 with electrical wire 104.
- each of electrical coils 110 as inverters, have means to convert 24 volts to 240 volts.
- Electrical coils 110 connect to a mechanical pedal 112 that connects to an electric accelerator 114. The mechanical pedal 112 is operated by a driver whereby pressing the mechanical pedal 112 increases vehicle acceleration.
- electric accelerator 114 communicates electronically with computer 116, and computer 116 determines current to flow to distributor 118. Extending from distributor 118 are electrical wires i and j. It is also noted that distributor 118 has synchronizing means to send electrical currents to electro-magnets to switch magnetic polarity. [28] As seen in figures IA and IB, induced currents Il and 12 flow through their respective current limiters Rl and R2 and activate transistors Ql and Q2 respectively. When the transistors Ql and Q2 are activated, the currents Il and 12 flow from distributor 118.
- Distributor 118 synchronizes the generation of opposite forces by sending an electrical current, defined as Il and 12, to sensors 37 and 58 of electro-magnets 36 and 56 respectively, thus producing an opposite electro-motive force upon electro-magnets 36, thus causing electro-magnetic wheel 30 to rotate with shaft 22 in a predetermined direction.
- electro-magnets 36 and 56 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
- Hub assembly 20 comprises shaft 22 and spacer 24. Spacer 24 serves to secure electro-magnetic wheel 30 upon shaft 22.
- Electro-magnetic wheel 30 comprises walls 32 and 34 that have electro-magnets 36 fixed there between. Each electromagnets 36 has sensor 37 fixed thereon.
- Electro-magnetic wheel 50 comprises walls 52 and 54 that have electro-magnets 56 fixed there between. Each electro-magnet 56 has sensor 58 fixed thereon. Between electro-magnetic wheels 30 and 50 is a clearance 38.
- Electro-magnetic wheel 30 is mounted upon shaft 22 and therefore rotates with shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. It is noted that electro-magnetic wheel 50 is stationary and does not rotate upon shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
- a first alternate embodiment of the instant invention is defined as 10', further comprising electromagnetic wheel 150 in addition to hub assembly 20, electromagnetic wheel 30, electro-magnetic wheel 50, and electrical system 100.
- distributor 118 In the first embodiment 10', extending from distributor 118 are electrical wires i, j, plus an additional electrical wire, not seen. As in the preferred embodiment 10, distributor 118 has synchronizing means to send an electrical current to electromagnets to switch magnetic polarity.
- induced currents flow through their respective current limiters and activate transistors respectively.
- the currents flow from distributor 118.
- Distributor 118 synchronizes the generation of opposite forces by sending an electrical current to sensors 37; 58; and 158 of electro-magnets 36; 56; and 156 respectively, thus producing an opposite electro-motive force upon electro-magnets 36, thus causing electro-magnetic wheel 30 to rotate with shaft 22 in a predetermined direction.
- electro-magnetic wheel 150 is connected to shaft 22 via clutch 151, seen in figure 4, allowing electro-magnetic wheel 150 to rotate upon shaft 22.
- electro-magnets 36; 56; and 156 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
- Electro-magnetic wheel 150 comprises walls 152 and 154 that have electro-magnets 156 fixed there between. Each electro-magnets 156 has a sensor 158 fixed thereon. Between electro-magnetic wheels 50 and 150 is a clearance 138.
- Electro-magnetic wheels 30 and 150 rotate upon shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. It is noted that electro-magnetic wheel 50 is stationary and does not rotate upon shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
- the first embodiment 10' produces greater rotational force upon shaft 22 than the preferred embodiment defined as 10, since distributor 118 synchronizes the generation of opposite forces by sending an electrical current to each of electro-magnets 36; 56; and 156, thus producing an opposite electro-motive force so as to force electro-magnetic wheels 30 and 150 to rotate upon shaft 22.
- a second alternate embodiment of the instant invention is defined as 10", further comprising electromagnetic wheel 250 in addition to electro-magnet wheel 150, hub assembly 20, electro-magnetic wheel 30, electro-magnetic wheel 50, and electrical system 100.
- distributor 118 extending from distributor 118 are electrical wires i, j, plus two additional electrical wires, not seen.
- distributor 118 has synchronizing means to send an electrical current to electromagnets to switch magnetic polarity.
- induced currents flow through their respective current limiters and activate transistors respectively.
- the currents flow from distributor 118.
- Distributor 118 synchronizes the generation of opposite forces by sending an electrical current to sensors 37; 58; 158; and 258 of electro-magnets 36; 56; 156; and 256 respectively, thus producing an opposite electro-motive force so as to force electro-magnetic wheel 30 to rotate upon shaft 22 in a predetermined direction.
- electromagnetic wheel 150 is connected to shaft 22 via clutch 151, seen in figure 4, allowing electro-magnetic wheel 150 to rotate upon shaft 22.
- electro-magnets 36; 56; 156; and 256 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
- Electro-magnetic wheel 250 comprises walls 252 and 254 that have electro-magnets 256 fixed there between. Each electro-magnets 256 has a sensor 258 fixed thereon. Between electro-magnetic wheels 150 and 250 is a clearance 238.
- Electro-magnetic wheels 30 and 150 rotate upon shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. It is noted that electro-magnetic wheels 50 and 250 are stationary and do not rotate upon shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
- the second embodiment 10" produces greater rotational force upon shaft 22 than the first alternate embodiment defined as 10', since distributor 118 synchronizes the generation of opposite forces by sending an electrical current to each of electromagnets 36; 56; 156; and 256, thus producing an opposite electro-motive force so as to force electro-magnetic wheels 30 and 150 to rotate upon shaft 22.
- Seen in figure 4 is a third alternate embodiment of the instant invention illustrating a plurality of electro-magnetic wheels mounted upon a single shaft 22 that may comprise a single electrical system 100.
- a user may engage the plurality of electro-magnetic wheels in series to increase rotational force upon shaft 22 for power and/ or velocity.
- a fourth alternate embodiment of the instant invention is defined as 10"', comprising electro-magnet 350 in addition to hub assembly 20, electro-magnetic wheel 30, and electrical system 100.
- distributor 118 has synchronizing means to send an electrical current to electro-magnets to switch magnetic polarity.
- induced currents flow through their respective current limiters and activate transistors respectively.
- the currents flow from distributor 118.
- Distributor 118 synchronizes the generation of opposite forces by sending an electrical current to sensors 37 and 358 of electro-magnets 36 and 356 respectively, thus producing an opposite electro-motive force upon electromagnets 36, thus causing electro-magnetic wheel 30 to rotate with shaft 22 in a predetermined direction.
- electro-magnets 36 and 356 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
- Electro-magnetic wheel 30 rotates upon shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22.
- Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108.
- At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
- the electro-magnetic circular engine 10 is manufactured of demagnetized material. It is important to note that the instant invention 10 requires scheduled maintenance and replacement of electro-magnets 36; 56; 156; and 256 at predetermined time intervals to maintain predetermined electromotive forces to properly operate. It is noted that the instant invention also comprises a separate cooling system and an engine oil system for lubrication and cooling that have not been illustrated for simplification.
- This invention is suitable to be used with any application requiring an engine, such as an automobile in the preferred embodiment; however, other embodiments of the present invention may be suitable for vehicles such as, but not limited to: airplanes, trucks, jeeps, motorcycles, scooters, vans, and water vessels. In alternative embodiments, the instant invention may be implemented with DC or AC current for tools, electrical appliances, pumps, heating systems, generators, toys, and in electrical plants to produce electricity.
- Traditional components such as timing chains, gears etc. have not been depicted and only a portion of the mechanism means has been illustrated enough to describe the invention. It is understood that these components will be part of the final embodiment. It is to be understood that variation in these elements of structure to obtain the same results is within the scope of the invention.
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Abstract
An electro-magnetic circular engine (10) in which the motive force is electro-magnetism. The electro-magnetic circular engine comprises a hub assembly (20), first and second electro-magnetic wheels (30 and 50), electro-magnetic means, and electrical means (100). The electro-magnetic circular engine (10) includes the rotation of the hub assembly (20) in a predetermined direction continuously after the initial activation of the hub assembly (20) by assembly of applying a short period of the external force, such as from a starter (108). At least three alternators are connected to the rotating shaft (22) and work at a minimum of 35 amps to over 600 amps each and recharge batteries (102).
Description
[ 1] I. TITLE: ELECTRO-MAGNETIC CIRCULAR ENGINE
[2] II. FIELD OF THE INVENTION
[3] The present invention relates to engines, and more particularly, to circular engines in which the motive force is electro-magnetism .
[4] III. DESCRIPTION OF THE RELATED ART
[5] Electro-magnetic systems comprise the basic principle that opposite poles attract and like poles repel each other. There are no electro-magnetic circular engines to the best of applicant's knowledge that include the rotation of a hub assembly in a predetermined direction continuously after the initial activation of the hub assembly by means of applying a short period of a force.
[6] Applicant believes that the only prior art reference corresponds to Applicant's own patent application having serial number: 10/987,701 for Electro-magnetic engine, filed on Nov. 15, 2004, that was granted a notice of allowance on Nov. 10, 2005.
[7] IV. SUMMARY OF THE INVENTION
[8] An electro-magnetic circular engine, comprising a hub assembly and a first electro-magnetic wheel rotatably mounted on the hub assembly. The first electro-magnetic wheel comprises first electro-magnets. A second electro-magnetic wheel
surrounds the first electro-magnetic wheel and comprises second electro-magnets .
[9] The instant invention also has electro-magnetic means consisting of a distributor having first synchronizing means to send an electrical current to the first and second electromagnets. The electro-magnetic means generate an electro-motive force between the first and second electro-magnets when synchronized by the distributor, wherein engaging magnetic polarity between the first and second electro-magnets, forces the first electro-magnetic wheel to rotate with the hub assembly in a predetermined direction continuously after an initial activation of the electro-magnetic means. This is done by applying a short period of an electrical force to the hub assembly. The instant invention also comprises electrical means that comprise an electrical connection and a source of rechargeable battery power for supplying the rechargeable battery power for the short period of an electrical force.
[10] The electro-magnetic circular engine may further comprise a third electro-magnetic wheel rotatably mounted on the hub assembly. The third electro-magnetic wheel comprises third electro-magnets. In this embodiment, the electro-magnetic means further has second synchronizing means to send an electrical current to the first, second, and third electro-magnets. The electro-magnetic means generate the electro-motive force between the first, second, and third electro-magnets when synchronized by the distributor, wherein engaging magnetic polarity between the first, second, and third electro-magnets
forces the first and third electro-magnetic wheels to rotate with the hub assembly in a predetermined direction continuously after an initial activation of the electro-magnetic means. This is done by applying the short period of the electrical force.
[1 1] The electro-magnetic circular engine may further comprise a fourth electro-magnetic wheel surrounding the third electromagnetic wheel. The fourth electro-magnetic wheel comprises fourth electro-magnets. In this embodiment, the electromagnetic means further has third synchronizing means to send an electrical current to the first, second, third, and fourth electro-magnets. The electro-magnetic means generate the electro-motive force between the first, second, third, and fourth electro-magnets when synchronized by the distributor, wherein engaging magnetic polarity between the first, second, third, and fourth electro-magnets forces the first and third electro-magnetic wheels to rotate with the hub assembly in a predetermined direction continuously after an initial activation of the electromagnetic means. This is done by applying the short period of the electrical force.
[12] The first, second, third, and fourth electro-magnets each comprise sensors to receive the electrical current via the electromagnetic means. The electrical means further comprises the source of rechargeable battery power having the electrical connection to a starter switch. The electrical means further comprises the starter switch having the electrical connection to a starter. The electrical means further comprises the starter switch having the electrical connection to at least one electrical
coil. The electrical coil is an inverter, and has means to convert 24 volts DC to 240 volts AC. The electrical means further comprises the at least one electrical coil having the electrical connection to a mechanical pedal that is operated by a driver for acceleration. The mechanical pedal has the electrical connection to an electric accelerator. The mechanical pedal has the electrical connection to a computer. The computer has the electrical connection to the distributor, and the short period of an electrical force derives from a starter.
[13] The electro-magnetic circular engine further comprises at least three alternators connected to the hub assembly. The at least three alternators work at a minimum of 35 amps to over 600 amps each and recharge the rechargeable battery power. The first, second, third, and fourth electro-magnets requires scheduled maintenance and replacement at predetermined time intervals to maintain predetermined the electro-motive forces. The electro-magnetic circular engine set forth in claim 10, further comprises a cooling system and an engine oil system for lubrication and cooling.
[14] It is therefore one of the main objects of the present invention to provide an electro-magnetic circular engine in which the motive force is electro-magnetism.
[15] It is yet another object of this invention to provide such a device that is inexpensive to manufacture and maintain while retaining its effectiveness.
[16] Further objects of the invention will be brought out in the following part of the specification, wherein detailed description is for the purpose of fully disclosing the invention without placing limitations thereon.
[17] V. BRIEF DESCRIPTION OF THE DRAWINGS
[18] With the above and other related objects in view, the invention consists in the details of construction and combination of parts as will be more fully understood from the following description, when read in conjunction with the accompanying drawings in which:
[19] Figure IA is a schematic drawing showing a section of the electrical system of an electro-magnetic circular engine.
[20] Figure IB represents a cross sectional view of the preferred embodiment of the electro-magnetic circular engine.
[21] Figure 2 represents a cross sectional view of a first alternate embodiment of the electro-magnetic circular engine.
[22] Figure 3 represents a cross sectional view of a second alternate embodiment of the electro-magnetic circular engine.
[23] Figure 4 represents a cross sectional view of a third alternate embodiment of the electro-magnetic circular engine.
[24] Figure 5 represents a cross sectional view of a fourth alternate embodiment of the electro-magnetic circular engine.
[25] VI. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[26] Referring now to the drawings, an electro-magnetic circular engine is shown at 10. In the preferred embodiment, the electromagnetic circular engine consists of hub assembly 20, electromagnetic wheel 30, electro-magnetic wheel 50, and electrical system 100, as seen in figures IA and IB.
[27] As seen in figure IA, electrical system 100 comprises rechargeable batteries 102 and electrical wires 104 that electrically connect to each of the components described below. Rechargeable batteries 102 have sufficient power to start instant invention 10. Each of rechargeable batteries 102 has an electrical wire 104 that connects to starter switch 106. Starter switch 106 is connected to starter 108. Starter switch 106 connects to each of electrical coils 110 with electrical wire 104. In the preferred embodiment, each of electrical coils 110, as inverters, have means to convert 24 volts to 240 volts. Electrical coils 110 connect to a mechanical pedal 112 that connects to an electric accelerator 114. The mechanical pedal 112 is operated by a driver whereby pressing the mechanical pedal 112 increases vehicle acceleration. Recognizing pedal placement, electric accelerator 114 communicates electronically with computer 116, and computer 116 determines current to flow to distributor 118. Extending from distributor 118 are electrical wires i and j. It is also noted that distributor 118 has synchronizing means to send electrical currents to electro-magnets to switch magnetic polarity.
[28] As seen in figures IA and IB, induced currents Il and 12 flow through their respective current limiters Rl and R2 and activate transistors Ql and Q2 respectively. When the transistors Ql and Q2 are activated, the currents Il and 12 flow from distributor 118. Distributor 118 synchronizes the generation of opposite forces by sending an electrical current, defined as Il and 12, to sensors 37 and 58 of electro-magnets 36 and 56 respectively, thus producing an opposite electro-motive force upon electro-magnets 36, thus causing electro-magnetic wheel 30 to rotate with shaft 22 in a predetermined direction. As illustrated, electro-magnets 36 and 56 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
[29] Hub assembly 20 comprises shaft 22 and spacer 24. Spacer 24 serves to secure electro-magnetic wheel 30 upon shaft 22. Electro-magnetic wheel 30 comprises walls 32 and 34 that have electro-magnets 36 fixed there between. Each electromagnets 36 has sensor 37 fixed thereon. Electro-magnetic wheel 50 comprises walls 52 and 54 that have electro-magnets 56 fixed there between. Each electro-magnet 56 has sensor 58 fixed thereon. Between electro-magnetic wheels 30 and 50 is a clearance 38.
[30] Electro-magnetic wheel 30 is mounted upon shaft 22 and therefore rotates with shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. It is noted that electro-magnetic wheel 50 is stationary and does not
rotate upon shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
[31] As seen in figure 2, a first alternate embodiment of the instant invention is defined as 10', further comprising electromagnetic wheel 150 in addition to hub assembly 20, electromagnetic wheel 30, electro-magnetic wheel 50, and electrical system 100.
[32] In the first embodiment 10', extending from distributor 118 are electrical wires i, j, plus an additional electrical wire, not seen. As in the preferred embodiment 10, distributor 118 has synchronizing means to send an electrical current to electromagnets to switch magnetic polarity.
[33] Similar to the preferred embodiment, induced currents flow through their respective current limiters and activate transistors respectively. When the transistors are activated, the currents flow from distributor 118. Distributor 118 synchronizes the generation of opposite forces by sending an electrical current to sensors 37; 58; and 158 of electro-magnets 36; 56; and 156 respectively, thus producing an opposite electro-motive force upon electro-magnets 36, thus causing electro-magnetic wheel 30 to rotate with shaft 22 in a predetermined direction. In addition, electro-magnetic wheel 150 is connected to shaft 22 via
clutch 151, seen in figure 4, allowing electro-magnetic wheel 150 to rotate upon shaft 22. As illustrated, electro-magnets 36; 56; and 156 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
[34] Electro-magnetic wheel 150 comprises walls 152 and 154 that have electro-magnets 156 fixed there between. Each electro-magnets 156 has a sensor 158 fixed thereon. Between electro-magnetic wheels 50 and 150 is a clearance 138.
[35] Electro-magnetic wheels 30 and 150 rotate upon shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. It is noted that electro-magnetic wheel 50 is stationary and does not rotate upon shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
[36] It is noted that the first embodiment 10' produces greater rotational force upon shaft 22 than the preferred embodiment defined as 10, since distributor 118 synchronizes the generation of opposite forces by sending an electrical current to each of electro-magnets 36; 56; and 156, thus producing an opposite
electro-motive force so as to force electro-magnetic wheels 30 and 150 to rotate upon shaft 22.
[37] As seen in figure 3, a second alternate embodiment of the instant invention is defined as 10", further comprising electromagnetic wheel 250 in addition to electro-magnet wheel 150, hub assembly 20, electro-magnetic wheel 30, electro-magnetic wheel 50, and electrical system 100.
[38] In this second embodiment 10", extending from distributor 118 are electrical wires i, j, plus two additional electrical wires, not seen. As in the preferred embodiment 10, distributor 118 has synchronizing means to send an electrical current to electromagnets to switch magnetic polarity.
[39] Similar to the preferred embodiment, induced currents flow through their respective current limiters and activate transistors respectively. When the transistors are activated, the currents flow from distributor 118. Distributor 118 synchronizes the generation of opposite forces by sending an electrical current to sensors 37; 58; 158; and 258 of electro-magnets 36; 56; 156; and 256 respectively, thus producing an opposite electro-motive force so as to force electro-magnetic wheel 30 to rotate upon shaft 22 in a predetermined direction. In addition, electromagnetic wheel 150 is connected to shaft 22 via clutch 151, seen in figure 4, allowing electro-magnetic wheel 150 to rotate upon shaft 22. As illustrated, electro-magnets 36; 56; 156; and 256 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic
principle that opposite poles attract and like poles repel each other.
[40] Electro-magnetic wheel 250 comprises walls 252 and 254 that have electro-magnets 256 fixed there between. Each electro-magnets 256 has a sensor 258 fixed thereon. Between electro-magnetic wheels 150 and 250 is a clearance 238.
[41] Electro-magnetic wheels 30 and 150 rotate upon shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. It is noted that electro-magnetic wheels 50 and 250 are stationary and do not rotate upon shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102. It is noted that the second embodiment 10" produces greater rotational force upon shaft 22 than the first alternate embodiment defined as 10', since distributor 118 synchronizes the generation of opposite forces by sending an electrical current to each of electromagnets 36; 56; 156; and 256, thus producing an opposite electro-motive force so as to force electro-magnetic wheels 30 and 150 to rotate upon shaft 22.
[42] Seen in figure 4 is a third alternate embodiment of the instant invention illustrating a plurality of electro-magnetic wheels mounted upon a single shaft 22 that may comprise a
single electrical system 100. When desired, a user may engage the plurality of electro-magnetic wheels in series to increase rotational force upon shaft 22 for power and/ or velocity.
[43] As seen in figure 5, a fourth alternate embodiment of the instant invention is defined as 10"', comprising electro-magnet 350 in addition to hub assembly 20, electro-magnetic wheel 30, and electrical system 100.
[44] In this fourth embodiment 10"', extending from distributor 118 is an electrical wire k. As in the preferred embodiment 10, distributor 118 has synchronizing means to send an electrical current to electro-magnets to switch magnetic polarity.
[45] Similar to the preferred embodiment, induced currents flow through their respective current limiters and activate transistors respectively. When the transistors are activated, the currents flow from distributor 118. Distributor 118 synchronizes the generation of opposite forces by sending an electrical current to sensors 37 and 358 of electro-magnets 36 and 356 respectively, thus producing an opposite electro-motive force upon electromagnets 36, thus causing electro-magnetic wheel 30 to rotate with shaft 22 in a predetermined direction. As illustrated, electro-magnets 36 and 356 have defined polarities, wherein north polarity is defined by N and the south polarity is defined by S to follow the basic principle that opposite poles attract and like poles repel each other.
[46] Electro-magnetic wheel 30 rotates upon shaft 22 in a predetermined direction continuously after the initial activation of the shaft 22. Initial activation of the shaft 22 can be accomplished by means of applying a short period of the force, such as from starter 108. At least three alternators, not shown, are connected to the rotating shaft 22. In the preferred embodiment, the alternators work at a minimum of 35 amps to over 600 amps each and recharge rechargeable batteries 102.
[47] It is noted that the electro-magnetic circular engine 10 is manufactured of demagnetized material. It is important to note that the instant invention 10 requires scheduled maintenance and replacement of electro-magnets 36; 56; 156; and 256 at predetermined time intervals to maintain predetermined electromotive forces to properly operate. It is noted that the instant invention also comprises a separate cooling system and an engine oil system for lubrication and cooling that have not been illustrated for simplification.
[48] This invention is suitable to be used with any application requiring an engine, such as an automobile in the preferred embodiment; however, other embodiments of the present invention may be suitable for vehicles such as, but not limited to: airplanes, trucks, jeeps, motorcycles, scooters, vans, and water vessels. In alternative embodiments, the instant invention may be implemented with DC or AC current for tools, electrical appliances, pumps, heating systems, generators, toys, and in electrical plants to produce electricity.
[49] Traditional components such as timing chains, gears etc. have not been depicted and only a portion of the mechanism means has been illustrated enough to describe the invention. It is understood that these components will be part of the final embodiment. It is to be understood that variation in these elements of structure to obtain the same results is within the scope of the invention.
[50] As can be readily understood from the foregoing description of the invention, the present structure can be configured in different modes to provide the ability to construct an electromagnetic circular engine. Accordingly, the foregoing description conveys the best understanding of the objectives and advantages of the present invention. Different embodiments may be made of the inventive concept of this invention. It is to be understood that all matter disclosed herein is to be interpreted merely as illustrative, and not in a limiting sense.
[51] VII. INDUSTRIAL APPLICABILITY
[52] It is evident that an invention such as the electro-magnetic circular engine claimed in the present application is quite desirable because the motive force is electro-magnetism. Also, the present invention is quite desirable because it is inexpensive to manufacture and maintain while retaining its effectiveness.
Claims
[53] VIII. CLAIMS
[54] What is claimed is:
[55] 1. An electro-magnetic circular engine, comprising;
[56] A) a hub assembly;
[57] B) a first electro-magnetic wheel rotatably mounted on said hub assembly, said first electro-magnetic wheel comprising first electro-magnets;
[58] C) a second electro-magnetic wheel surrounding said first electro-magnetic wheel, said second electro-magnetic wheel comprising second electro-magnets;
[59] D) electro-magnetic means, said electro-magnetic means consisting of a distributor having first synchronizing means to send an electrical current to said first and second electromagnets, said electro-magnetic means generate an electro-motive force between said first and second electro-magnets when synchronized by said distributor, wherein engaging magnetic polarity between said first and second electro-magnets forces said first electro-magnetic wheel to rotate with said hub assembly in a predetermined direction continuously after an initial activation of said electro-magnetic means by applying a short period of an electrical force to said hub assembly; and
[60] E) electrical means comprising an electrical connection and a source of rechargeable battery power for supplying said
rechargeable battery power for said short period of an electrical force.
[61] 2. The electro-magnetic circular engine set forth in claim
1, further comprising:
[62] F) a third electro-magnetic wheel rotatably mounted on said hub assembly, said third electro-magnetic wheel comprising third electro-magnets; and
[63] G) said electro-magnetic means further having second synchronizing means to send an electrical current to said first, second, and third electro-magnets, said electro-magnetic means generate said electro-motive force between said first, second, and third electro-magnets when synchronized by said distributor, wherein engaging magnetic polarity between said first, second, and third electro-magnets forces said first and third electromagnetic wheels to rotate with said hub assembly in a predetermined direction continuously after an initial activation of said electro-magnetic means by applying said short period of said electrical force.
[64] 3. The electro-magnetic circular engine set forth in claim
2, further comprising:
[65] H) a fourth electro-magnetic wheel surrounding said third electro-magnetic wheel, said fourth electro-magnetic wheel comprising fourth electro-magnets; and
[66] I) said electro-magnetic means further having third synchronizing means to send an electrical current to said first, second, third, and fourth electro-magnets, said electro-magnetic means generate said electro-motive force between said first, second, third, and fourth electro-magnets when synchronized by said distributor, wherein engaging magnetic polarity between said first, second, third, and fourth electro-magnets forces said first and third electro-magnetic wheels to rotate with said hub assembly in a predetermined direction continuously after an initial activation of said electro-magnetic means by applying said short period of said electrical force.
[67] 4. The electro-magnetic circular engine set forth in claim
3, further characterized in that said first, second, third, and fourth electro-magnets each comprise sensors to receive said electrical current via said electro-magnetic means.
[68] 5. The electro-magnetic circular engine set forth in claim
4, further characterized in that said electrical means further comprises said source of rechargeable battery power having said electrical connection to a starter switch.
[69] 6. The electro-magnetic circular engine set forth in claim
5, further characterized in that said electrical means further comprises said starter switch having said electrical connection to a starter.
[70] 7. The electro-magnetic circular engine set forth in claim 6, further characterized in that said electrical means further comprises said starter switch having said electrical connection to at least one electrical coil, said electrical coil is an inverter, and has means to convert 24 volts DC to 240 volts AC.
[71] 8. The electro-magnetic circular engine set forth in claim
7, further characterized in that said electrical means further comprises said at least one electrical coil having said electrical connection to a mechanical pedal that is operated by a driver for acceleration, said mechanical pedal has said electrical connection to an electric accelerator, said mechanical pedal has said electrical connection to a computer, said computer has said electrical connection to said distributor, and said short period of an electrical force derives from a starter.
[72] 9. The electro-magnetic circular engine set forth in claim
8, further comprising at least three alternators connected to said hub assembly, said at least three alternators work at a minimum of 35 amps to over 600 amps each and recharge said rechargeable battery power.
[73] 10. The electro-magnetic circular engine set forth in claim
9, further characterized in that said first, second, third, and fourth electro-magnets requires scheduled maintenance and replacement at predetermined time intervals to maintain predetermined said electro-motive forces.
[74] 11. The electro-magnetic circular engine set forth in claim 10, further comprising a cooling system and an engine oil system for lubrication and cooling.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/US2008/066670 WO2009151450A1 (en) | 2008-06-12 | 2008-06-12 | Electro-magnetic circular engine |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/US2008/066670 WO2009151450A1 (en) | 2008-06-12 | 2008-06-12 | Electro-magnetic circular engine |
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Publication Number | Publication Date |
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WO2009151450A1 true WO2009151450A1 (en) | 2009-12-17 |
Family
ID=41416974
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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PCT/US2008/066670 WO2009151450A1 (en) | 2008-06-12 | 2008-06-12 | Electro-magnetic circular engine |
Country Status (1)
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WO (1) | WO2009151450A1 (en) |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20050248231A1 (en) * | 2004-03-24 | 2005-11-10 | Pioneer Corporation | Motor and information recording and reproducing apparatus |
US7105958B1 (en) * | 2004-11-15 | 2006-09-12 | Shimon Elmaleh | Electro-magnetic engine |
-
2008
- 2008-06-12 WO PCT/US2008/066670 patent/WO2009151450A1/en active Application Filing
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20050248231A1 (en) * | 2004-03-24 | 2005-11-10 | Pioneer Corporation | Motor and information recording and reproducing apparatus |
US7105958B1 (en) * | 2004-11-15 | 2006-09-12 | Shimon Elmaleh | Electro-magnetic engine |
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